cpsA regulates mycotoxin production, morphogenesis and...
Transcript of cpsA regulates mycotoxin production, morphogenesis and...
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cpsA regulates mycotoxin production, morphogenesis and cell wall biosynthesis in the 1
fungus Aspergillus nidulans 2
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Xuehuan Feng1, Vellaisamy Ramamoorthy1†, Sandesh S. Pandit, Alicia Prieto2, Eduardo A. Espeso2 and 4
Ana M. Calvo1* 5
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1Department of Biological Sciences, Northern Illinois University, Dekalb, IL 60115, USA. 7
2Centro de Investigaciones Biológicas, CSIC, Madrid, Spain 8
†Dept. of Plant Pathology Agricultural College and Research Institute Killikulam, Vallanadu - 628 252 9
Thoothukudi District Tamil Nadu, India 10
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*Author to whom correspondence should be addressed [telephone: (815) 753-0451]; fax (815) 753-0461; 13
e-mail [email protected]] 14
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Summary 16
The model fungus Aspergillus nidulans synthesizes numerous secondary metabolites, including 17
sterigmatocystin (ST). The production of this toxin is positively controlled by the global regulator veA. In 18
the absence of veA (ΔveA), ST biosynthesis is blocked. Previously we performed random mutagenesis in 19
a ΔveA strain and identified revertant mutants able to synthesize ST, among them RM1. Complementation 20
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of RM1 with a genomic library revealed that the mutation occurred in a gene designated as cpsA. While in 21
the ΔveA genetic background cpsA deletion restores ST production, in a veA wild-type background 22
absence of cpsA reduces and delays ST biosynthesis decreasing the expression of ST genes. Furthermore, 23
cpsA is also necessary for the production of other secondary metabolites, including penicillin, affecting 24
the expression of PN genes. In addition, cpsA is necessary for normal asexual and sexual development. 25
Chemical and microscopy analyses revealed that cpsA is found in cytoplasmic vesicles and it is required 26
for normal cell wall composition and integrity, affecting adhesion capacity and oxidative stress 27
sensitivity. The conservation of cpsA in Ascomycetes suggests that cpsA homologs might have similar 28
roles in other fungal species. 29
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Key words: mutagenesis, veA, velvet, polysaccharide, cpsA, mycotoxin, cell wall, development, penicillin, 31
secondary metabolism 32
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Introduction 34
Aspergillus species synthesize numerous secondary metabolites (Adrio et al., 2003; Brakhage et al., 35
2011). These compounds include antibiotics and other medical drugs as well as mycotoxins (Bennett et 36
al., 2003; Reverberi et al., 2010). The model fungus Aspergillus nidulans produces the mycotoxin 37
sterigmatocystin (ST). This mycotoxin is similar to the well-known potent carcinogenic aflatoxins (AFs) 38
(Payne and Yu, 2010; Sweeny and Dobson, 1999; Payne and Brown, 1998), produced by other 39
Aspergillus species, including the agriculturally important fungi A. flavus and A. parasiticus. Both toxins 40
are produced through a conserved biosynthetic pathway (Cole and Cox, 1981). As in the case of AF 41
genes, the genes involved in the synthesis of ST are clustered and regulated by aflR, an endogenous 42
transcription factor gene (Yu et al., 1996; Keller and Hohn, 1997; Fernandes et al., 1998). Transcription 43
of aflR, and concomitant production of ST, is positively controlled by veA, a global regulatory gene that 44
also governs sexual and asexual development in A. nidulans (Kato et al., 2003; Calvo, 2008, Calvo et al., 45
2016). A similar role was found in A. flavus and A. parasiticus, where veA controls AF production (Duran 46
et al., 2007; 2009; Calvo et al., 2004). 47
In A. nidulans, the biosynthesis of other natural products, such as penicillin (PN), is also veA-regulated 48
(Kato et al., 2003). Similar regulatory output is also observed in other fungal species, for instance, veA 49
homologs also regulate PN synthesis in Penicillium chrysogenum (Hoff et al., 2010; Veiga et al., 2012; 50
Kopke et al., 2013) and cephalosporin C production in Acremonium chrysogenum (Dreyer et al., 2007). 51
Additionally, besides affecting ST and AF production, veA also controls the biosynthesis of other 52
mycotoxins, for instance, cyclopiazonic acid and aflatrem in Aspergillus flavus (Duran et al., 2007), 53
fumonisins and fusarins in Fusarium spp, including F. verticillioides and F. fujikuroi (Myung et al., 2009; 54
Wiemann et al., 2010), trichothecenes in F. graminerum (Merhej et al., 2012), as well as dothistromin in 55
Dothistroma septosporum (Chettri et al., 2012) among others. 56
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The use of A. nidulans as a model system has greatly enhanced our knowledge on the veA regulatory 57
mechanism of action (Calvo et al., 2016). The VeA protein, together with another velvet protein 58
denominated VelB (Bayram et al., 2008), is transported to the nucleus by the KapA α-importin, 59
particularly in the dark, a condition that promotes ST production and sexual development in this fungus 60
(Stinnett et al., 2007; Araújo-Bazán et al., 2009). This migration of KapA-VeA-VelB is negatively 61
affected under light by other proteins, such as FphA, LlmF, and Vip-VapB dimer (Palmer et al., 2013; 62
Sarikaya-Bayram et al., 2014; Purschwitz et al., 2008) promoting conidiation. In the nucleus, VeA also 63
interacts with other proteins, forming a complex with light-responsive proteins, FphA, LreA and LreB, 64
which also affects asexual and sexual morphogenesis and secondary metabolism (Purschwitz et al., 2008; 65
Röhrig et al., 2013). Furthermore, VeA also interacts with the putative methyl transferase LaeA (Bayram 66
et al., 2008; Bayram and Braus, 2012) forming the VelB-VeA-LaeA velvet complex. LaeA, also required 67
for normal mycotoxin biosynthesis (Bok and Keller, 2004), has been shown to be involved in chromatin 68
remodeling (Reyes-Dominguez et al., 2010; Bayram et al., 2010). Interestingly, not only does VeA play a 69
role as a scaffold for these complexes, but velvet proteins have been shown to bind DNA (Beyhan et al., 70
2013; Ahmed et al., 2013). 71
Our previous phylogenetic study revealed that VeA is conserved in many Ascomycetes (Myung et al., 72
2012), where in addition to governing morphogenesis and secondary metabolism, this regulator influences 73
plant pathogenicity of different mycotoxigenic fungi, for example in Aspergillus flavus (Duran et al., 74
2007; 2009), Fusarium verticillioides (Myung et al., 2012; Li et al., 2006), F. fujikuroi (Bayram et al., 75
2008), and F. graminearum (Merhej et al., 2012; Jiang et al., 2001), as well as fungal infections in 76
animals (Laskowski-Peak et al., 2012). Absence of veA homologs in these fungi resulted in a decrease in 77
virulence, coinciding with a reduction in mycotoxin production. In addition, cellular processes such as 78
oxidative stress response (Calvo et al., 2016; Baidya et al., 2014), cell wall structure synthesis (Li et al., 79
2006; Park et al., 2015), and generation of hydrolytic activity (Dhingra et al., 2012; Duran et al., 2014) 80
have all been found to be modulated by veA. 81
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In order to discover novel genetic elements connected to the veA global regulatory mechanism we 82
previously performed random mutagenesis in a deletion veA strain, and identified several veA-dependent 83
genes involved in the regulation of ST biosynthesis (Ramamoorthy et al., 2012). For instance, rtfA, a gene 84
encoding a putative RNA polymerase transcription elongation factor-like that also regulates sexual and 85
asexual development. In the same manner, we found mtfA, encoding a novel putative C2H2 zinc finger 86
domain type transcription factor that regulates the biosynthesis of several secondary metabolites including 87
ST, and it is also important for morphogenesis in A. nidulans (Ramamoorthy et al., 2013). In the present 88
study we have investigated another selected revertant mutant, RM1. This strain presented a point mutation 89
in a gene that we designate as cpsA. This gene was initially annotated as encoding a putative 90
polysaccharide synthase. In this study we show that cpsA differentially influences ST biosynthesis in a 91
veA-dependent manner. cpsA also regulates the biosynthesis of other natural products, including PN. 92
Furthermore, cpsA is necessary for normal conidiation and sexual development in A. nidulans. 93
Importantly, our chemical analysis and microscopy observations indicated that cpsA is required for 94
normal composition and integrity of the fungal cell wall, affecting fungal adhesion and the capacity to 95
survive under exposure to environmental stresses. Our study demonstrated a profound effect of the cpsA 96
gene on cell wall biosynthesis and in the expression of numerous genes, including those involved in 97
secondary metabolism and developmental processes. 98
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Results 100
AN9069 a putative polysaccharide synthase gene 101
Previously we reported seven revertant mutants (RMs) with restored wild-type levels of norsolorinic acid 102
(NOR), an orange intermediate used as marker of ST biosynthesis, in a strain with a ∆veA background 103
(Ramamoorthy et al., 2012). In the present study we identified the mutated gene in RM1 (Figure 1). First, 104
to examine whether one or more mutations occurred in RM1, the strain was crossed with RJH030 (yA2, 105
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wA3, pabaA1, ΔstcE, trpC801, veA1). Analysis of the obtained progeny and dominant analysis revealed 106
that RM1 presents a single recessive mutation. Transformation of RM1-R2 with a genomic library yielded 107
colonies with wild-type phenotype. Sequencing of the inserts in rescued plasmids from these fungal 108
colonies, and comparison of these sequences with the A. nidulans genomic database 109
(http://www.aspgd.org) by BLAST analysis showed that the mutated gene in RM1 and RM1-R2 strains 110
was AN9069, annotated as a putative polysaccharide synthase gene, and was denominated cpsA. The 111
mutation was a G-A transition at nucleotide +568 of the cpsA coding region, changing the codon from 112
GAT to AAT, resulting in a substitution of glutamic acid (D) for Asparagine (N) (Figure S1). 113
Complementation of RM1 with the library plasmid containing cpsA resulted in a strain with ∆veA 114
phenotype with reduced ST intermediate production (Figure 1). 115
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cpsA putative homologs are present in other fungal species 117
The deduced amino acid sequence of A. nidulans CpsA revealed high identity with proteins from other 118
Aspergillus species, including A. clavatus (75.4% identity), A. terreus (78.7%), A. flavus (76.5%), or A. 119
fumigatus (65.3%) (Figure S1). TMHMM predicted hydrophobic regions possibly acting as signal 120
peptide (1- 36, probability below 0.4) and transmembrane domains TM1 (309-332, probability below 121
0.4), TM2 (343-367, probability below 0.6) and TM3 (371-397, probability below 0.9) (Figure S1). 122
Analysis of other fungal genome databases revealed that CpsA is also conserved in many other 123
Ascomycetes (Table S1). An extensive alignment and phylogenetic tree is shown in Figures S2 and S3. 124
Additionally, A. nidulans CpsA was compared with putative bacterial homologs (Figure S4). CpsA 125
presents a DXD motif, conserved in glycosyltransferases (Breton et al., 2006), that is relevant for their 126
activity (Bothe et al. 2015); Busch et al., 1998; Li et al; 2001). This DXD motif was shown in crystal 127
structures to interact primarily with the phosphate groups of nucleotide donor through the coordination of 128
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a divalent cation, typically Mn2+ (Breton et al., 2006) or Mg+2 (Weigle, 2015). In addition, CpsA contains 129
the related XDD motif (Weigel, 2015; Gulberti, et al., 2003). 130
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cpsA affects mycotoxin biosynthesis in a veA-dependent manner 132
To further evaluate the effects of cpsA on A. nidulans mycotoxin biosynthesis, we deleted the cpsA coding 133
region in the RDAE206 strain (ΔveA, ΔstcE), creating TDAEΔcpsA (ΔcpsA, ΔveA, ΔstcE) (Figure S5) 134
(Table S2). In addition, we also deleted cpsA in a strain with a veA+ wild-type allele, RJMP1.49, 135
resulting in TRVΔcpsA (ΔcpsA, veA+) (Table S2) (Figure S5). These deletions were confirmed by 136
Southern blot analysis (Figure S5). The deletion of cpsA in a ∆veA ∆stcE background shows similar NOR 137
production levels to those in cpsA- ∆veA ∆stcE and the control veA1 ΔstcE, and higher than in ∆veA 138
∆stcE (Figure 1). However, deletion of cpsA in a strain with a veA+ genetic background, showed a delay 139
and a reduction in ST production compared with its isogenic controls strain, and the complementation 140
strain (Figure 2). As shown, the reintroduction of the wild-type allele partially rescues the phenotype 141
close to wild-type levels. It is possible that the complementation occurred at a different location, resulting 142
in the observed slight phenotypical changes. 143
ST production is affected by glucose concentration (i.e. Atoui et al., 2010). For this reason we 144
also evaluated the effect of cpsA on mycotoxin production on medium with different glucose 145
concentrations. ∆cpsA veA+ strain also showed a delay and a reduction in ST production when medium 146
with higher concentrations of glucose was used. Overexpression of cpsA also showed a reduction in ST 147
biosynthesis with respect to the controls. This difference in mycotoxin production was more notable as 148
the concentration of glucose in the medium was increased (Figure S6). In addition, our analysis revealed 149
that the synthesis of other unknown compounds was also cpsA-dependent (Figure S6). 150
The genes responsible for ST production are located in a cluster (Brown et al., 1996), among them, aflR 151
encodes a C6 zinc transcription factor that activates other genes in this cluster (Yu et al., 1996; Fernandes 152
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et al., 1998; Brown et al., 1996). Additionally, another gene within the ST cluster, stcU, that encodes a 153
ketoreductase, is commonly used as indicator of ST cluster activation (Yu et al., 1996; kato et al., 2003; 154
Keller et al., 1995; Hicks et al., 1997). Northern analysis showed that expression of both aflR and stcU 155
was reduced in the cpsA deletion (TRVp∆cpsA) (Table S2) in comparison to the isogenic wild type and 156
complementation strain (Figure 2A). The same trend was also observed when cpsA was overexpressed. A 157
concomitant reduction in ST accumulation was detected in the deletion and overexpression cpsA cultures 158
(Figure 2B). 159
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PN production is influenced by cpsA 161
Our chemical analysis results indicated that cpsA also affects the synthesis of other compounds in 162
addition to ST (Figure S6). It is known that production of several secondary metabolites, including ST 163
and PN, can be coregulated by certain proteins, such as VeA (Kato et al., 2003), and that, based on our 164
current study, the cpsA genetic element is VeA dependent. For these reasons, we also evaluated whether 165
cpsA influences PN production in A. nidulans. We analyzed production of this antibiotic in the ∆cpsA 166
strain (TRVpΔcpsA) and compared it with PN levels in the control strains, as well as in the cpsA 167
overexpression strain. For this assay we used a well-established bioassay using B. calidolactis as the 168
testing organism. Absence or overexpression of cpsA significantly decreased PN production with respect 169
to the control strains (Figure 3), indicating that normal cpsA expression is necessary for wild-type levels 170
of PN production. Furthermore, expression of the genes involved in PN biosynthesis, acvA, ipnA and attA 171
(MacCabe et al., 1990), was significantly down-regulated when cpsA is deleted or overexpressed, causing 172
reduction in PN biosynthesis. 173
cpsA positively affects development in A. nidulans 174
Deletion of cpsA resulted in a reduction in colony growth (Figure 4) and a drastic alteration of A. nidulans 175
morphology (Figure 5), affecting both asexual and sexual development. Absence of cpsA resulted in 176
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severe reduction of conidial production, as well as in loss of Hülle cells (nursing cells contributing to the 177
formation of fruiting bodies), and lack of cleistothecial formation under conditions that allow the 178
production of these structures in the isogenic controls (Figure 5A-B). Interestingly, overexpression of 179
cpsA also decreased conidiation, while causing an increase in the number of Hülle cells and a slight 180
increase in cleistothecia with respect to the controls (Figure 5A-B). The reduction in conidiation in ΔcpsA 181
and OEcpsA was accompanied by a decrease in the expression of brlA, a transcription factor gene that 182
regulates early stages in conidiophore formation (Figure 5C) (Boylan et al., 1987; Adams et al., 1988). 183
This reduction in brlA expression was particularly notable in ΔcpsA. In addition, the lack of sexual 184
development in the absence of cpsA also coincided with a decrease in the expression levels of nsdD and 185
steA, both encoding transcription factors involved in sexual development (Han et al., 2001; Vallim et al., 186
2000). Furthermore, deletion of cpsA negatively affected the expression of veA (Figure 6), global 187
regulator previous described to be essential for sexual development and other biological functions (Kato 188
et al., 2003; Calvo et al., 2016; Yager, 1992; Kim et al., 2002; Calvo and Cary, 2014), as well as laeA, 189
encoding a VeA-interacting partner, LaeA, that also influences sexual development and controls 190
secondary metabolism (Bok and Keller, 2004; Bayram et al., 2010). 191
CpsA localizes in cytoplasmic vesicles 192
In the current study we also investigated the subcellular localization of CpsA in A. nidulans. With this 193
purpose, we generated two identical strains with cpsA fused to gfp. A single copy of the fusion cassette 194
was detected at the cpsA locus (data not shown). The selected transformants containing the cpsA::gfp 195
cassette presented wild-type phenotype. Microscopic observations were identical for both transformants 196
(results for TXF1.1 are shown in Figure 7). Fluorescence microscopy results indicated A. nidulans CpsA-197
GFP localizes abundantly at cytoplasmic vesicles or organelles. CMAC staining indicates that some of 198
these organelles are vacuoles. Non motile and other highly motile vesicles are likely endosomes (movie 199
1). No other structures are labeled by GFP fluorescence. For example there is no evidence of 200
accumulation at the plasma membrane. Over-expression of CpsA does not modify this distribution, only 201
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the intensity of fluorescence detected (Figure S7 and movie 2). Thus CpsA might be exerting its role in 202
any of those vesicles, or the amount of protein at the plasma membrane is relatively low for detection. 203
Full length CpsA-GFP fusion protein was detected by Western Blot. This protein must be linked to 204
structures that cannot be solubilized in a standard buffer lacking detergents or denaturing agents (A50 205
buffer, see extensive work with this buffer in Orejas et al., 1995) corroborating the microscopy result of 206
localization in internal membranous structures. Nevertheless, the GFP moiety is detected suggesting a 207
degradation process for CpsA-GFP probably at recycling compartments as the lysosome or multivesicular 208
bodies. 209
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cpsA is involved in regulating cell wall composition and integrity 211
Our sequence analysis suggested that cpsA could be involved in cell wall organization or synthesis. To 212
test whether cpsA has a role in cell wall integrity, we examined the effect of cell wall disrupting 213
compounds, sodium dodecyl sulphate (SDS) and calcofluor white (CFW) (Ram and Klis, 2006) in the 214
culture medium inoculated with the wild type, ΔcpsA, ΔcpsA-com, and OEcpsA (Figure 8). In both cases 215
the presence of the cell wall disrupting agent caused growth inhibition when cpsA was deleted or over-216
expressed. The observed effect was particularly drastic in the absence of cpsA. These results suggest that 217
cpsA might affect cell wall components. We examined the cell wall composition in the wild type, cpsA 218
deletion, complementation and overexpression strains as detailed in Materials and Methods. The results 219
showed that absence of cpsA led to a significant reduction of glucan, chitin and mannoprotein compared 220
to the levels of those components in the wild-type and complementation strain cell wall (Table 1). 221
Overexpression of cpsA resulted in a similar reduction of these components compared to the controls. 222
Importantly, transmission electron microscopy analysis revealed that absence of cpsA results in partial 223
detachment of the cell wall from the plasma membrane (Figure 9). This observed separation was 224
consistent only in the case of the cpsA mutant, while it was not observed in the control strains. 225
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cpsA is involved in adhesion to surfaces 227
Biofilms are complex structures that offer protection from environmental stresses. Biofilm formation has 228
been shown to involve a sequential adherent process to a new surface (Finkel and Mitchell, 2011; 229
Beauvais and Muller, 2009). We examined the possible role of cpsA in A. nidulans mycelial adhesion. 230
Interesting, our results indicated that deletion of cpsA caused a notable delay and reduction in adhesion 231
capacity (Figure 10). Overexpression of cpsA also slightly decreased adhesion capacity at 24 h after 232
inoculation. In addition, we analyzed the expression of three genes that could influence biofilm formation, 233
dvrA, stuA and laeA (Figure 10B). In all cases these three genes were downregulated in the cpsA deletion 234
strain compared to the controls. 235
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Wild-type cpsA expression levels facilitate A. nidulans growth under oxidative stress conditions 237
In order to examine the possible role of cpsA in resistance to oxidative stress, menadione was added to the 238
culture medium at different concentrations (Figure 11A). Absence of cpsA clearly resulted in growth 239
inhibition at 0.08 mM, while the growth of the isogenic control strains was inhibited at 0.2 mM under the 240
experimental conditions assayed. Overexpression of cpsA only mildly decrease fungal growth under 241
oxidative stress conditions. Furthermore, alterations in the cpsA locus reduced the expression of the 242
thioredoxin gene thiO and catalase gene catB with respect to the controls when the cultures were exposed 243
to menadione (Figure 11B-D). 244
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Deletion of cpsA affects osmotic stress tolerance and increases sensitivity to temperature in A. 246
nidulans 247
In this study, we also examined whether cpsA was involved in survival under osmotic stress. For this 248
purpose the medium was supplemented with NaCl (0.7 M), or sorbitol (1.2 M). The addition of sorbitol 249
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did not further decrease fungal growth in the deletion mutant (Figure S8). However, addition of NaCl did 250
reduce ∆ cpsA colony growth in comparison to the colonies of this strain grown on non-supplemented 251
GMM. Absence of cpsA also resulted in an increase in sensibility to higher temperatures (45 oC), while a 252
lower temperature (30 oC) increased fungal growth in this mutant. Unexpectedly, NaCl and sorbitol 253
supplemented ∆cpsA cultures grown at 45 oC showed an increase of vegetative growth. 254
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Defects in cell wall is not sufficient to recover ST production in a ∆veA background 256
In order to test whether the deffects in cell wall composition and integrity observed in the cpsA mutant 257
were sufficient to lead to the recovery of ST biosynthesis in a strain with a ∆veA background, we 258
analyzed production of this mycotoxin in a double mutant ∆veA∆rlmA. The rlmA gene encodes a MADS-259
box transcription factor involved in cell wall integrity in A. nidulans (Kovácsa et al., 2013). Our results 260
indicated that alterations if the rlmA locus are insufficient to restablish toxin production in the absence of 261
veA (Figure S9). 262
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Analysis of hyaluronic acid by SAX-HPLC and glycosyl composition of cell wall by GC-MS 264
In order to determine whether hyaluronic acid is present or absent in A. nidulans cell wall and whether its 265
synthesis is cpsA-dependent, we examined hyaluronan content in these samples at the Complex 266
Carbohydrate Research Center (Athens, GA). After digestion with hyaluronase, samples were analyzed 267
by SAX-HPLC as described in Materials and Methods section, and compared to a purified hyaluronan 268
sample undergoing the same procedure. Our results showed that hyaluronan was not present in these 269
fractions. In addition, monosaccharide composition of the wild-type and ΔcpsA cell wall fractions was 270
also analyzed by GC-MS. Hyaluronan is a polymer of D-glucuronic acid and D-N-acetylglucosamine, 271
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however no glucuronic acid was found in these fractions (Table S3), further indicating that hyaluronan is 272
either absent of at very low concentration in the cell wall of this fungus. 273
Analysis of exopolysaccharide (EPS) glycosyl composition by GC-MS 274
In order to examine whether hyaluronan is present in A. nidulans EPS, we analyzed its glycosyl 275
composition by GC-MS as described in Materials and Methods section (Table S4). As in the case of the 276
cell wall analysis, no glucuronic acid was found in the EPS of either wild type or mutant. In addition, EPS 277
was analyzed by infrared spectroscopy (Figure S10). IR spectra from both samples were identical and 278
presented characteristics of polysaccharides with N-acetylated aminosugars. The bands at 820 and 850 279
cm-1 and the lack of signal at 890 cm-1 confirmed the alpha configuration of these polysaccharides. 280
Furthermore, the signals at 1558 and 1646 cm-1 are typical of the amide linkage from N-acetyl 281
aminosugars, which suggest N-acetylation of galactosamine units. The absence of signals in the region of 282
1700-1780 cm-1 from the carboxyl group confirms that these samples lack uronic acids, which agrees with 283
the results from monosaccharide analysis. The type of linkages was also analyzed after methylation 284
(Figure S11). The results from the methylation analysis as well as those from IR spectroscopy indicate the 285
presence of α-(1-4)-galactosaminogalactans in the EPS samples. 286
Monosaccharides detected in A. nidulans membrane 287
As mentioned above, hyaluronan is a polymer of D-glucuronic acid and D-N-acetylglucosamine. We 288
analyze the monosaccharide composition of A. nidulans wild-type in membrane in search of the presence 289
of any of these monomers, particularly glucuronic acid, which could serve as possible anchor between 290
membrane and the cell wall by binding D-N-acetylglucosamine in that structure. Furthermore, glucuronic 291
acid containing glycolipid have been reported in membranes of the phylogenetically related fungus A. 292
fumigatus (Fontaine et al., 2009). Our GC/MS analysis results are listed in Table S5. Mannitol, mannose, 293
glucose, galactose and glucosamine were detected, however glucuronic acid was not found in this sample. 294
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Discussion 296
Secondary metabolites are crucial in the ecology and adaptation of fungi to their environment. The 297
biosynthesis of these compounds, also denominated natural products, is often genetically linked with 298
morphological development by shared regulatory mechanisms (Calvo, 2008; Calvo et al., 2016; Bayram 299
and Braus, 2012; Calvo and Cary, 2014; Calvo et al., 2002; Yu and Keller, 2005). Among them, one 300
member of the velvet protein family, VeA, plays a key role in connecting these two processes (Calvo, 301
2008; Calvo et al., 2016; Bayram and Braus, 2012; Calvo and Cary, 2014; Calvo et al., 2002). In A. 302
nidulans, the absence of the veA gene results in strains unable to form sexual fruiting bodies (Kim et al., 303
2002), displaying hyperconidiation by affecting the expression of brlA, a gene encoding an indispensable 304
transcription factor for the formation of conidiophores in this model fungus (Kato et al., 2003). In other 305
Aspergillus species, such as the AF-producers A. flavus and A. parasiticus, deletion of veA prevents the 306
formation of sclerotia (Calvo et al., 2004; Duran et al., 2007; Calvo and Cary, 2014), resistant structures 307
important for survival under adverse environmental conditions (Coley-Smith and Cooke, 1971; Wicklow, 308
1987). It has been established that veA has a plurality of roles. Recent transcriptome analyses revealed a 309
wide range of veA-dependent genes with a variety of functions, including numerous secondary metabolite 310
gene clusters in A. nidulans, as well as in other Aspergillus species, such as the opportunistic human 311
pathogen A. fumigatus (Dhingra et al., 2013; Lind et al., 2015) and the AF-producer A. flavus (Cary et al., 312
2015), and in other fungal genera, for example in Fusarium (Wiemann et al., 2010; Kim et al., 2013) or in 313
Penicillum spp. (Hoff et al., 2010). While the compounds associated with some of these veA-dependent 314
genes clusters are still unknown, in some cases these associations have been characterized in great depth, 315
such as the case of the mycotoxin ST in A. nidulans. 316
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In spite its importance, the VeA mechanism of action is not fully understood. Our search for new veA-317
dependent genetic elements involved in the regulation of ST production in A. nidulans resulted in the 318
identification of cpsA, encoding a protein initially annotated as a putative polysaccharide synthase. CpsA, 319
shares limited similarity with proteins of the bi-functional glycosyltransferases family 2, hyaluronan 320
synthases, which catalyze polymerization of hyaluronan. The deduced amino acid sequence shows a 321
putative signal peptide domain and three putative transmembrane domains. Although the probability in 322
this prediction is low, these domains have also been described in other characterized hyaluronan 323
synthases, including those in humans (Watanabe and Yamaguchi, 1996). Its putative characterized 324
bacterial homolog, Cps1, is a type 3 polysaccharide synthase in Streptococcus pneumonia, involved in the 325
polymerization of Glc and GlcUA onto the growing polysaccharide chain (Chang et al., 2006). In the 326
pathogenic yeast Cryptococcus neoformans, the Cps1 homolog is a hyaluronic acid synthase needed for 327
the formation of the outer cell wall, playing an essential role in adhesion and virulence of this 328
Basidiomycete (Chang et al., 2006; Jong et al., 2007). A Cps1 putative homolog was also found in 329
Neurospora crassa by Fu et al (2014). As in the case of N. crassa, our study show that A. nidulans lacks 330
hyaluronic acid in its cell wall. Furthermore, our extensive chemical analysis indicates that this compound 331
is also absent in the exopolysaccharide, mainly composed of α-(1-4)-galactosaminogalactans. In addition, 332
no evidence of glucuronic acid in membrane was found. Nevertheless, our comparative analysis with 333
putative bacterial homologs indicated the presence of DXD and XDD motifs, conserved in 78 families of 334
glycosyltransferases (Breton et al., 2006; Bothe et al. 2016; Busch et al., 1998; Li et al; 2001). Irrefutably, 335
our results revealed a profound effect of CpsA in all aspects of A. nidulans biology. For this reason we 336
also performed a detailed microscopy study to provide additional clues of its mode of action. Our results 337
indicated that CpsA-GFP accumulates in cytoplasmic vesicles or organelles and that, based on the CMAC 338
staining, some of these organelles are vacuoles. Non motile vesicles would correspond to late-endosomes, 339
and those moving in retrograde and anterograde directions are, most probably, early endosomes (see 340
Lopez-Berges et al., 2016 and references therein). Additionally, our protein analysis also indicates that 341
16
CpsA is located and bound to internal membranous structures. Functional full-length CpsA-GFP protein 342
must locate in early and late endosomes, or other membranous compartment, such as vesicles originated 343
at the Golgi which could fuse to early endosomes. The recycling of this putative transmembrane protein 344
probably occurs in vacuoles or multivesicular bodies fused with lysosomes, as also suggested by the 345
presence of the resistant GFP fragment in the Western Blot. Further research will be carried out in our lab 346
to investigate the nature of these membranous compartment and their aggregates. 347
348 Our current study also revealed that CpsA influences ST biosynthesis in a veA-dependent manner in A. 349
nidulans. Deletion of cpsA in a strain with a veA+ allele resulted in the opposite effect on mycotoxin 350
production with respect to that observed in a strain where veA is absent, presenting a decrease in 351
accumulation of ST in comparison with the wild type. Similarly to the case of strains with a deletion veA 352
background, strains with a veA1 partially functional mutant allele (Stinnett et al., 2007; Kim et al., 2002; 353
Käfer, 1965) (commonly used in A. nidulans research laboratories), with a loss-of-function cpsA allele 354
also accumulated an abundant amount of ST. These results indicated that cpsA function is affected by the 355
veA allele. This effect on ST production was also observed in previously characterized veA-dependent 356
genes, such as rtfA (Ramamoorthy et al., 2012), and mtfA (Ramamoorthy et al., 2013). Furthermore, our 357
study also showed that cpsA affects the expression of aflR, encoding a C6 zinc transcription activator 358
necessary for the activation of other genes in the ST gene cluster (Yu et al., 1996; Fernandes et al., 1998). 359
The biosynthesis of other secondary metabolites was also impacted by the presence or absence of cpsA, 360
for instance, production of PN was reduced in the cpsA deletion mutant as well as in a strain with forced 361
overexpression of this gene. This suggests a broad effect of cpsA on A. nidulans secondary metabolism, in 362
which proper wild-type levels of cpsA expression are necessary for normal biosynthesis of these natural 363
products. 364
Besides the observed effect of cpsA in secondary metabolism, the present study indicated that cpsA also 365
affected A. nidulans development. Expression of brlA, key in the conidiation central regulatory pathway 366
17
(Boylan et al., 1987; Adams et al., 1988; Park and Yu 2012; Adams and Yu, 1998) was downregulated in 367
the absence of cpsA compared to the wild type, resulting in a reduction of conidial production. 368
Furthermore, in the cpsA deletion mutant, expression was also decreased for the nsdD, steA, and stuA 369
genes, which encode transcription factors required for sexual development (Han et al., 2001; Vallim et 370
al., 2000; Wu and Miller, 1997; Miller et al., 1992). Furthermore, the cpsA deletion strain is unable to 371
produce Hülle cells or cleistothecia under conditions that allow the production of these structures in the 372
wild type. As in the case of A. nidulans, loss of the CpsA homolog, Csp-1, negatively affected conidiation 373
and production of sexual structures in N. crassa (Fu et al., 2014). Overexpression of cpsA in A. nidulans 374
resulted in greater production of Hülle cells and cleistothecia than the wild type. These results indicate 375
that cpsA positively influences both asexual and sexual development in A. nidulans. 376
Interestingly, this study showed that not only is cpsA functionally veA-dependent, but that cpsA also 377
positively affects the expression of the global regulators veA and laeA; the later encodes a putative methyl 378
transferase involved in chromatin conformation remodeling (Bok and Keller, 2004; Reyes-Dominguez et 379
al., 2010; Bayram et al., 2010; Patananan et al., 2013). Since both veA and laeA regulate hundreds of 380
genes in A. nidulans (Lind et al., 2015; Kim et al., 2013a) as well as in other fungi (i.e. Hoff et al., 2010; 381
Wiemann et al., 2010; Dhingra et al., 2012; Lind et al., 2015; Cary et al., 2015; Kim et al., 2013a; 382
Karimi-Aghcheh et al., 2013; Fekete et al., 2014) it is possible that some of the phenotypes observed in 383
the absence of cpsA, such as changes in morphological and chemical development, could be, at least in 384
part, the result of alterations in the expression of these global regulators. Moreover, veA transcriptome 385
analysis in A. nidulans indicated that cpsA expression is also dependent on veA (Lind et al., 2015), 386
suggesting a regulatory loop essential for A. nidulans fitness. 387
The absence of cpsA was also associated with defects in cell wall composition, including a decrease in 388
glucan, chitin and mannoprotein content. Moreover, transmission electron microscopy analysis revealed 389
alterations in cell wall integrity with structural changes in the cpsA deletion mutant, presenting partial 390
18
detachment of the cell wall with respect to the plasma membrane. It is possible that this partial 391
detachment could be a consequence of a disorganized assembly of the cell wall. Additionally, it is likely 392
that some of the cell wall components could be more easily lost in the cpsA mutant strain, as in the case of 393
cell wall proteins in the N. crassa Cps1 mutant (Fu et al., 2014). It has been shown that deletion of a gene 394
involved in cell wall biosynthesis may induce a compensatory effect further modifying the structure 395
(Beauvais et al., 2014; Latgé, 2010). However, our results suggest that the lack of cpsA does not lead to a 396
compensatory effect in this case. The reduction of other cell wall components and structural alterations in 397
the cpsA mutant cell wall could contribute to the observed increase in sensitivity to external stresses. For 398
example, the fungal cell wall is the first line of defense for protection against exogenous oxidative stress 399
(Fuchs and Mylonakis, 2009). Our results indicated that alterations in the expression of cpsA increases 400
sensitivity to reactive oxygen species (ROS). In addition, wild-type expression levels of cpsA are also 401
necessary for proper expression of thiO, catB (Hong et al., 2013; Kawasaki and Aguirre, 2001) and veA, 402
also known to be involved in oxidative stress response (Baidya et al., 2014), that further contributes to 403
this increased sensitivity to ROS in strains without a wild-type cpsA locus. Oxidative stress influences 404
activation of fungal development and secondary metabolism (i.e Baidya et al., 2014; Etxebeste et al., 405
2010; Amare and Keller, 2014; Roze et al., 2013). However above certain thresholds, excessive exposure 406
to ROS and other stresses in the cpsA mutant could lead to deleterious effects, negatively affecting the 407
expression of numerous genes, including those involved in sexual and asexual development, as well as 408
those involved in secondary metabolism in A. nidulans. Interestingly, in the case of ST, deletion of the 409
rlmA gene, involved in cell wall integrity (Kovácsa et al., 2013) in a ∆veA strain did not recover toxin 410
production, suggesting that although cpsA notably affects A. nidulans cell wall, this effect does not 411
appears to be solely responsible for all the biological changes observed in the absence of cpsA. 412
It is known though that the fungal cell wall not only plays an essential role in maintaining cell shape and 413
protecting the cell against mechanical damage and other environmental stresses, but it is also involved in 414
adhesion to environmental surfaces and in biofilm formation (de Groot et al., 2009; Yin et al., 2008; 415
19
Brown et al., 2014). In pathogenic fungi, biofilms cause clinical problems, including resistance to 416
antifungal drugs (Ramage et al., 2009). Importantly, our results revealed that cpsA is necessary for normal 417
adhesion to surfaces. Biofilm formation, for which adhesion is necessary, is associated with complex 418
regulation of cell surface protein synthesis, hyphal formation and secondary metabolism (Finkel and 419
Mitchell, 2011; Beauvais et al., 2014). Interestingly, physical contact of fungal mycelium with bacteria 420
has been shown to be required to elicit a response that triggers the expression of specific secondary 421
metabolite gene clusters (Schroeckh et al., 2009). This evidence supports that adhesion, which allows 422
proper physical contact with surfaces, is intimately related with secondary metabolism regulation in 423
response to this environment perception. In addition, in A. fumigatus, the secondary metabolite regulator 424
laeA, was found highly upregulated during biofilm formation (Gibbons et al., 2011). In our studies, lack 425
of proper adhesion in the cpsA mutant formation coincided with a reduction of laeA transcription, which 426
could also negatively affect secondary metabolism. The reduction in adhesion in the absence of cpsA was 427
also associated with a decrease in the expression of the developmental gene stuA, homolog of Candida 428
albicans efg1, which is necessary for biofilm formation in this pathogenic fungus (Finkel and Mitchell, 429
2011; Gibbons et al., 2014). stuA plays multiples roles in fungi; in A. nidulans, besides its described role 430
in the regulation of sexual development and possibly in adhesion, as suggested in our study, it is also 431
involved in the regulation of asexual development (Wu and Miller, 1997; Miller et al., 1992), this holds 432
true in A. fumigatus (Sheppard et al., 2005), as well as its role governing some secondary metabolite gene 433
clusters (Sheppard et al., 2005; Twumasi-Boateng et al., 2009). Interestingly, the multiple functions 434
described for stuA include the regulation of catalase-peroxidase gene cpeA in A. nidulans (Scherer et al., 435
2002), as well as cat1 in A. fumigatus (Sheppard et al., 2005). It is possible that besides the effects 436
observed in development and possibly in biofilm formation, the reduction of stuA in the cpsA mutant 437
could further contribute to accentuate the increased sensitivity to ROS. Lastly, in our study, loss of 438
adhesion capacity in ∆cpsA was also associated with a reduction in the expression of the A. nidulans 439
homolog of the A. fumigatus C2H2 zinc finger transcription factor gene dvrA (Ejzykowicz et al., 2010), 440
20
and C. albicans and C. parasilosis bcr1 (Fanning and Mitchell, 2012; Nobile and Mitchell, 2005; Ding 441
and Butler, 2007), known to play a critical role in biofilm formation. 442
In conclusion, our studies revealed that the veA-dependent genetic element cpsA in A. nidulans has a 443
profound effect on secondary metabolism and morphological development. cpsA also, proved to be 444
critical for proper cell wall composition and integrity, as well as for normal adhesion capacity. The 445
critical role of cpsA in fungal cell wall formation could in part determine resistance to environmental 446
stressors, such as presence of ROS, osmostress or temperature variation. These multiple direct or indirect 447
effects suggest a cross-talk and complex balance between different cpsA-dependent cell processes in A. 448
nidulans that could be in part mediated by the effect of cpsA on the global regulators veA and laeA. The 449
fact that the absence of cpsA results in a range of dramatic defects in this filamentous model fungus, 450
together with the conservation of cpsA in many other fungal species, makes cpsA a potential desirable 451
target in a control strategy to reduce the detrimental effects of fungi, including mycotoxin contamination. 452
Additionally, since cpsA homologs are present in multiple fungal pathogens, this gene and its gene 453
product could also be used as target for antifungal drugs. The study of A. nidulans cpsA exemplifies the 454
strong interdependence of different cellular processes necessary for fitness and survival of fungal species. 455
456
Experimental Procedures 457
Fungal strains and growth conditions 458
The A. nidulans strains used in this study are listed in Table S2. Strains were grown on glucose minimum 459
medium (GMM) (Käfer, 1977) and oat meal medium (OMM) (Butchko et al., 1999) containing the 460
appropriate supplements for the corresponding auxotrophic markers (Käfer, 1977). Ten grams per liter 461
was added in the case of solid medium. Strains were stored as 30% glycerol stocks at −80 °C. 462
463
21
Genetic techniques 464
Meiotic recombination was established between A. nidulans RM1 mutant obtained by chemical 465
mutagenesis (Ramamoorthy et al., 2012) and the RJH030 strain (pabaA1; yA2; wA3; argB2; 466
ΔstcE::argB; trpC801; veA1) as previously described (Pontecorvo et al., 1953). The progeny was 467
analyzed for the presence or absence of the veA1 allele, first by phenotypic observation and finally 468
confirmed by PCR. Colony morphology, as well as norsolorinic acid (NOR) production, were also 469
examined. The progeny of this cross showed four phenotypic groups: 1. ∆veA, ∆stcE, X- (RM1 parental 470
type); 2. ∆stcE (RJH030 parental type); 3. recombinant type ∆veA, ∆stcE (deletion veA phenotype); 4. 471
recombinant type ∆stcE, X- (RM1-R2). Dominance test was carried out by generating diploids using 472
RM1-R2 and RAV1 strains. Diploids were analyzed for NOR accumulation as well as morphological 473
development. 474
Identification of the revertant mutation in RM1 475
To identify the mutated gene originally present in RM1, the RM1-R2 (∆stcE, X-) strain was transformed 476
with the A. nidulans genomic library pRG3-AMA1-NOT1. Plasmid DNA was extracted from fungal 477
transformants showing wild-type phenotype. The end regions of the DNA inserts in the obtained plasmids 478
were sequenced. The complete DNA insert sequence was found in the A. nidulans genome database 479
(http://www.aspgd.org). To elucidate the location of the mutation in RM1, a PCR product was amplified 480
from the same locus in RM1 and sequenced. 481
482
Sequence analysis 483
The deduced amino acid sequence of cpsA (AN9069) was compared against databases from other 484
Aspergillus species and from different fungal genera, using the BLAST (blastp) tool provided by National 485
Center for Biotechnology Information (NCBI), (http://www.ncbi.nlm.nih.gov/). TMHMM website 486
(http://www.cbs.dtu.dk/services/TMHMM/) was also used for prediction of hydrophobic regions possibly 487
22
acting as signal peptide or transmembrane domains in the comparison between several CpsA homologs 488
from different Aspergillus species. The gene entry with the highest percentage of identity and the lowest 489
e-value for each of the species was selected. Pairwise sequence alignment of the proteins was performed 490
using the EMBOSS Needle tool (http://www.ebi.ac.uk/Tools/psa/emboss_needle/) from EMBL-EBI 491
(European Molecular Biology Laboratory's European Bioinformatics Institute). Percentage of similarities 492
and percentage of identities were tabulated for each of the alignments. Multiple sequence alignment was 493
performed with CpsA (A. nidulans) and homologs found across various fungal species using MAFFT 494
version 6.0 (http://mafft.cbrc.jp/alignment/server/index.html), followed by shading with the Jalview 495
2.9.0b2 software (http://www.jaview.org/) (Waterhouse et al., 2009). Generation of the phylogenetic tree 496
was performed by the MEGAv6 software (Tamura et al., 2013). Sequences were aligned using MUSCLE 497
software. A maximum-likelihood tree was generated with a bootstrap value of 1000. Accession numbers 498
for all sequences used are shown in Table S1. 499
500
Generation of the cpsA deletion and complementation strains 501
The DNA cassette used to delete cpsA was obtained by fusion PCR as previously described (Szewczyk et 502
al., 2006). The 1.4 kb 5’ UTR and 1.5 kb 3’ UTR flanking regions of cpsA were PCR amplified with 503
RM1-F1 and cps-P2, and cps-P3 and RM1-R2A primers sets, respectively (Table S6). The A. fumigatus 504
pyrG selectable marker was amplified with cps-P5 and cps-P6 primers from plasmid p1439. The 5’ and 3’ 505
UTR fragments were then PCR fused to pyrGAfum to generate the cpsA replacement construct using 506
primers RM1-F2 and RM1-R4. RDAE206 and RJMP1.49 were used as host strains. The resulting 507
transformation strains were designated as TDAE∆cpsA and TRV∆cpsA, respectively. Genomic DNA 508
from the selected transformants was analyzed by Southern blot. 509
510
23
A complementation strain was also obtained by transforming TRV∆cpsA with the cpsA wild-type allele. 511
The complementation vector was generated as follows: a DNA fragment containing the entire cpsA wild-512
type locus, including 2.0 kb of upstream and 1.0 kb downstream regions, was amplified with the primers 513
cps-com1 and cps-com2, digested with EcoRI and HindIII and ligated into pSM3 (containing pyroA), 514
previously digested with the same enzymes, resulting in pSM3-cpsA-com. The complementation vector 515
was then transformed into TRV∆cpsA using pyroA as selectable marker. Complementation was confirmed 516
by PCR. The complemented strain was designated as TRV∆cpsA-com. 517
518
Generation of cpsA overexpression strain 519
To generate the cpsA overexpression strain, the entire cpsA coding region was first PCR amplified using 520
the cps-OE1 and cps-OE2 primers, with engineered AscI and NotI sites (Table S6). The PCR product was 521
then digested with AscI and NotI, and ligated into pTDS1 vector previously digested with the same 522
enzymes. pTDS1 contains the A. nidulans gpdA promoter, trpC terminator and the pyrG marker. The 523
resulting plasmid was denominated pTDS-cpsOE. The pTDS-cpsOE vector was transformed into 524
RJMP1.49, and transformants were selected on appropriate selection medium without uridine and uracil, 525
and confirmed by diagnostic PCR using gpdApromoF and cps-OE2 primers (Table S6). 526
Toxin analysis 527
Culture plates containing 25 ml of solid GMM were top-agar inoculated with 106 spores/plate, and 528
incubated at 37 °C in the dark for 6 days. Three cores (16 mm diameter) were collected from each 529
replicate plate and extracted with 5 ml of chloroform. Alternatively, strains were incubated in GMM 530
liquid shaken cultures (106 spores/ml) at 37 °C and 250 rpm. Culture supernatants were collected and 531
extracted with chloroform. Extracts were dried overnight and then re-suspended in 500 μl of chloroform. 532
Samples were fractionated by thin-layer chromatography (TLC) using benzene and glacial acetic acid 533
[95:5 (v/v)] as solvent system for ST analysis, and chloroform: acetone: n-hexane (85:15:20) for NOR 534
24
analysis. Aluminum chloride (15% in ethanol) were then sprayed on the plates, and baked at 80 °C for 10 535
min. Metabolites present on TLC plates were visualized under 375 nm UV light. Commercial ST (Sigma) 536
was used as standard. 537
538
PN analysis 539
The PN bioassay was performed as previously described (Brakhage et al., 1992) with some modifications, 540
using Bacillus calidolactis C953 as the test organism. Briefly, twenty-five milliliters of seed culture 541
medium were inoculated using 106 spores/ml of wild type, deletion cpsA, complementation and 542
overexpression strains, and incubated at 26 °C for 48 h at 250 rpm. Mycelia were washed and transferred 543
to 20 ml of fermentation medium. Mycelial samples were harvested at 24 h and 48 h for gene expression 544
analysis. After 96 h, the culture supernatants were collected for PN analysis. Four-hundred milliliters of 545
Tryptone-Soy Agar was supplemented with 30 ml of B. calidolactis C953 culture and plated on five 150-546
mm-diameter Petri dishes. Twenty microlitres of each culture supernatant was added to 7-mm-diameter 547
wells. The plates were incubated at 55°C for 24 h, when inhibition halos were visualized and measured. 548
To verify that the observed antibacterial activity was due to the presence of PN, and not to the presence of 549
different fungal compounds in the supernatant, controls containing commercial penicillinase from 550
Bacillus cereus (Sigma, MO, USA) were also included. A standard curve using various concentrations of 551
PN G (Sigma, MO, USA) was utilized to determine PN concentration in the supernatants. 552
Morphological studies 553
Plates containing 25 ml of solid GMM medium were inoculated with 5 ml of top agar containing 106 554
spores of wild type, ∆cpsA, complementation and overexpression strains. The cultures were incubated in 555
dark or light at 37°C. Cores (7 mm diameter top agar layer) were removed from each culture after 48 h 556
and 72 h and homogenized in water. Conidia and Hülle cells were counted using a hemacytometer. 557
Identical cores were also taken to visualize cleistothecia under a dissecting microscope. To improve 558
25
visualization of fruiting bodies, the cores were sprayed with 70% ethanol to remove conidiophores. To 559
examine colony growth, each strain was point-inoculated on GMM plates and incubated under light or 560
dark conditions at 37°C for 6 days. Colony diameter was measured. Experiments were performed with 561
three replicates. 562
Gene expression analysis 563
Total RNA was extracted from lyophilized mycelia as previously described (Weber et al., 1998). 564
Gene expression levels were evaluated by Northern blot or quantitative reverse transcription-565
PCR (qRT-PCR) analysis. For Northern analysis, about 25 μg of total RNA of each sample was 566
separated by agarose gel electrophoresis and blotted as described by Sambrook and Russell 567
(2001). For qRT-PCR, total RNA was extracted from lyophilized mycelia using TRIsure (Bioline) 568
reagent and RNeasy Mini Kit (Qiagen) according to the manufacturer instructions. Five µg of total RNA 569
were treated with RQ1 RNase-Free DNase (Promega). cDNA was synthesized with Moloney murine 570
leukaemia virus (MMLV) reverse transcriptase (Promega). qRT-PCR was performed with the Applied 571
Biosystems 7000 Real-Time PCR System using SYBR green dye for fluorescence detection. A. nidulans 572
actin gene expression was used as reference, and the relative expression levels were calculated using the 573
2-ΔΔCT method (Livak and Schmittgen, 2001). Primer pairs used are shown in Table S6. 574
575
Study of cpsA subcellular localization 576
Aspergillus nidulans RJMP1.49 strain was transformed with a cpsA::gfp::pyrGA.fum DNA cassette 577
generated by fusion PCR as previously described (Szewczyk et al., 2006). Specifically, the cpsA coding 578
region and the 3’ UTR were PCR amplified with RM1-F4 and cpsgfp-P2, and cpsgfp-P3 and RM1-R2A 579
primers sets, respectively. The gfp::pyrGA.fum fragment was amplified with cpsgfp-P5 and cpsgfp-P6 580
primers from plasmid p1439 (Stinnett et al., 2007). The fragments were then PCR fused to generate the 581
cpsA::gfp::pyrGA.fum cassette using primers RM1-F5 and RM1-R3. Two transformants (TXF1.1 and 582
26
TXF1.2) were selected for further study. An overexpression strain, gpdA(p)::cpsA::gfp::pyrGA.fum was also 583
constructed as follows: cpsA::gfp was PCR amplified from TXF1.1 genomic DNA using RM1-Cps-OE1 584
and GFPR + notI primers (Table S6), digested with AscI and NotI and ligated to pTDS1 vector previously 585
digested with the same enzymes. The resulting plasmid was designated as pSSP4.1. The vector was then 586
transformed into TSSP7.1 resulting in strain TSS19.1. Conidia from the selected transformants, TXF1.1 587
TXF1.2 and TSS19.1 were inoculated as previously described (Stinnett et al., 2007). Conidia were 588
allowed to germinate on coverslip submerged in Watch minimal medium (WMM) (Peñalva, 2005) and 589
incubated for 16 h. Time lapse microscopy was done using Stream acquisition with 200 ms exposure per 590
frame using Metamorph software and a DMI6000b inverted microscope equipped with GFP and CMAC 591
(UV) detection filters. Images were acquired with a Hamamatsu ORCA-ERII high-sensitivity 592
monochrome digital CCD camera. Staining with CMAC (Molecular Probes) was carried out adding 593
CMAC 10 µM to the culture and incubating during 5 min at 25 oC followed by three washes with WMM. 594
CMAC (7-amino-4-chloromethylcoumarin) is commonly used for vacuole staining (acidic pH in vacuoles 595
activates this dye). Stack of images was converted to mov (Quicktime) using ImageJ software and 596
QTmoviemaker plugging. Movie 3 (showing only motile particles) is a stack of images from Movie 2 597
subjected to "Walking average" subroutine of ImageJ (4 images for media calculation) and then to "stack 598
difference" (image interval set to 1). Both ImageJ pluggins were obtained from EMBL, 599
https://www.embl.de/eamnet/html/body_kymograph.html. 600
601
Protein extraction and Western blot 602
Conidia of wild type and CpsA-GFP strain were inoculated in GMM and cultivated at 37 oC for 18 h in an 603
orbital shaker at 250 rpm. Mycelia were collected and lyophylized. A fraction of each mycelium mat was 604
subjected to protein extraction with an alkaline lysis protocol and another part to standardized protein 605
extraction using A50 buffer as indicated in (Hernandez-Ortiz and Espeso, 2013). Only the soluble fraction 606
27
of A50 buffer extraction is normally collected and used for further analyses. In this manuscript we kept 607
the insoluble fraction, which was treated with the alkaline lysis protocol to analyze insoluble proteins or 608
those linked to endomembranes or plasma membrane. SDS-PAGE and Western blotting was performed 609
using standard procedures. Proteins were transferred to nitrocellulose using the Transblot System from 610
BioRad. Mouse antibodies clones 7.1 and 13.1 against GFP were obtained from Sigma (1/5000 dilution). 611
Secondary anti-mouse antibody was obtained from Jackson (1/4000 dilution). Western blot was 612
developed using the ECL chemiluminescent kit. Images were taken using a BioRad Chemidoc Imaging 613
system and processed using Image Lab software (BioRad). 614
615
Cell wall stress assay 616
To test for possible alterations in the cell wall caused by either deletion or overexpression of cpsA, we 617
exposed the wild type, ∆cpsA, complementation and overexpression strains to SDS or calcofluor white 618
(CFW) as previously described by Riche et al (2009). GMM was amended with various concentrations of 619
SDS (0, 0.001%, 0.002%, 0.003%, 0.004%, 0.005%), or calcofluor white (CFW) (0, 2, 4, 6, 8, 10 μg/ml). 620
The strains were then point-inoculated on these media, and incubated at 37 °C for 3 days. 621
622
Cell wall chemical analysis 623
Conidia (106 spores/ml) from wild type, ∆cpsA, complementation and overexpression strains were 624
inoculated in 50 ml of liquid GMM and incubated for 48 h at 37 °C and 250 rpm. Mycelium was 625
harvested by filtration using miracloth, and washed twice with sterile distilled water. Five milligrams of 626
dry mycelium was finely ground. Each sample was boiled in 1 ml of buffer A (2% SDS, 50 mM Tris-HCl, 627
100 mM Na-EDTA, 40 mM β-mercaptoethanol, 1 mM PMSF) for 15 min (Riche et al.,2009). 628
Mannoprotein was extracted with 1M NaOH at 75 °C for 1 h and quantified as previous described (de 629
Groot et al., 2008; Kapteyn et al., 2001). Glucan and chitin were digested in 96% formic acid at 100 oC 630
for 4 h (Li et al., 2006). Formic acid was evaporated and residues were dissolved in 1 ml of distilled water. 631
28
The contents of glucan and chitin were evaluated by the quantification of released glucose and N-632
acetylglucosamine after digestion. Glucose concentration was measured by the phenol-sulphuric acid 633
method at 490 nm (Dubois et al., 1956). N-acetylglucosamine concentration was measured at 520 nm by 634
the method described by Lee et al (2005). The experiment included five replicates. 635
636
Transmission Electron Microscopy 637
Samples were fixed in 2.5% glutaraldehyde in Millonig’s phosphate buffer for 3 h at 4 oC, rinsed (3 x 10 638
min) in Millonig’s phosphate buffer followed by a treatment with 1% osmium tetroxide (OsO4) for 2 h at 639
room temperature. Then the samples were rinsed again (3 x 10 min) in Millonig’s phosphate buffer, 640
dehydrated in graduated ethanol series and cleared in acetone. The specimens were embedded using an 641
EMBed-812 kit (Electron Microscopy Sciences) and sectioned with a Reichert Om-U2 ultramicrotome 642
using a Diatome diamond knife. Samples were stained with 2% uranyl acetate (Watson) followed by lead 643
citrate (Sato). The fixation/dehydration/embedding was repeated twice (two separate experiments) with 644
similar results. For each samples, twenty images were visualized. Samples were visualized with a Hitachi 645
H-600 transmission electron microscope. Micrographs were taken with a SIA L12C digital camera 646
operated using MaxIm DL version 5.08 software. 647
648
Adhesion assay 649
The possible effect of cpsA on A. nidulans adhesion capacity was tested using 96 well plates as previously 650
described (Mowat et al., 2007; Pierce et al., 2008; Coffey and Anderson, 2014). Briefly, one hundred and 651
thirty microliters of inoculated GMM (105 spores/ml) were placed in each of the 96 wells on polystyrene 652
culture plates, and incubated at 37 °C for 24 h, 48 h and 72 h respectively. Then, the supernatant was 653
removed and the mycelium attached to the surface was washed 3 times with distilled water before adding 654
130 µl of Crystal violet 0.01% in water. After 20 min at room temperature, the wells were washed 3 times 655
29
with distilled water and were dried at room temperature. One hundred and thirty microliters of acetic acid 656
30% were used for distaining. OD was measured at 560 nm. 657
Oxidative and osmotic stress assays 658
In order to test whether cpsA affects A. nidulans response to oxidative stress, a method described by 659
Tribus et al (2005) was used with some modifications. Solid GMM containing various concentrations of 660
menadione (0, 0.04, 0.08, 0.12, 0.16, 0.20 mM) in 24 well plates were point-inoculated with the wild 661
type, ∆cpsA, complementation and overexpression strains and incubated at 37 °C for 3 days. GMM 662
without menadione was used as control. 663
664
Expression analysis of thiO and catB genes was examined by qRT-PCR and Northern blot, respectively, 665
using the primers listed in Table S6.The strains (106 spores/ml) were inoculated in liquid GMM and 666
incubated at 37°C in the dark for 48 h a 250 rpm. After that, approximately the same amount of mycelium 667
from each strain were transferred to GMM with or without menadione (0.08 mM). 668
669
To test sensitivity to osmotic stress, the wild type, ∆cpsA, complementation and overexpression strains 670
were point-inoculated on GMM and GMM supplemented with 0.7 M NaCl, or 1.2 M sorbitol. The 671
cultures were also grown at different temperatures, 30 °C, 37 °C and 45°C, to examine whether cpsA 672
function is affected by this parameter. 673
674
Generation of ∆rlmA and ∆veA∆rlmA double mutant 675
The DNA cassette used to delete rlmA by gene replacement was obtained by the fusion PCR method as 676
previously described (Szewczyk et al., 2006). The 1.3 kb 5’ UTR and 1.5 kb 3’ UTR of rlmA were 677
amplified from genomic DNA with primers ANrmlA_P1, ANrmlA_P2 and ANrmlA_P3, ANrmlA_P4, 678
respectively. The A. fumigatus pyrG selectable marker was amplified with ANrmlA_P5_pyrGafum and 679
30
ANrmlA_P6_pyrGafum primers from plasmid p1439. The 5’ UTR and 3’ UTR fragments were fused to 680
pyrGA.fum using ANrlm_p7 and ANrlm_p8 primers. TSSP7.1 strain was used as host for the 681
transformation, generating TSSP15.1. The DNA cassette also used to delete rlmA in TXF3.1 (∆veA), 682
generating TSSP16.1. Deletion of rlmA and veA was confirmed by PCR. 683
684
Analysis of hyaluronic acid and glycosyl composition of cell wall fractions 685
Plates containing 25 ml of liquid GMM were inoculated with 106 spores/ml of wild type, ∆cpsA, 686
complementation and overexpression strains. The cultures were then incubated in dark at 37 °C for 48 h, 687
when mycelium was collected by filtration using Miracloth. The cell wall samples were obtained as 688
follows: mycelium was first washed with 1xPBS and lyophilized. Then samples were ground, washed 689
with 1xPBS four times, and boiled in water for 10 min, followed by four additional washes with 1xPBS 690
and water. The cell wall samples were sent to the Complex Carbohydrate Research Center (Athens, GA) 691
for analysis. Approximately 0.5 g of each cell wall fraction was suspended in 5 mL of HA buffer (50 mM 692
sodium acetate, pH 6) and hyaluronase (from Streptomyces hyalurolyticus), final concentration 0.05 693
U/mL. The digestion was carried out at 55 oC for 24 h. A second aliquot of enzyme was added at that 694
time and the reaction was allowed to continue for another 24 h. The reaction was then stopped by boiling 695
for 10 min and filtered through a C18 SPE cartridge to separate out any remaining solids and to remove 696
any remaining protein from solution. The filtrate was then lyophilized and reconstituted in 500 µl of water 697
and analyzed by HPLC. Compounds were separated using an Agilent system with a 4.6x250 mm Waters 698
Spherisorb analytical column with 5μm particle size at 25°C, and a solvent gradient (solvent A: 2.5 mM 699
sodium phosphate, pH 3.5 and solvent and solvent B:) 2.5 mM sodium phosphate, 1.2 M NaCl, pH 3.5), 700
and a flow rate of 1 mL/min. Detection was performed by post-column derivatization. Briefly, the eluent 701
from the column was combined with a 1:1 mixture of 0.25 M NaOH and 1% 2-cyanoacetamide pumped 702
at a flow rate of 0.5 mL/min from a post column reactor. The eluent was heated to 130 °C in a 10-m 703
31
reaction coil, then cooled in a 50-cm cooling coil and measured with a fluorescence detection (λex = 346 704
nm, λem = 410). Identification and quantification was determined by comparison with a digestion of 705
Hyaluronan as positive control. 706
707
Cell wall monosaccharide components were analyzed by GC-MS. Approximately 2 mg of wild type and 708
ΔcpsA cell wall samples were placed in screw-cap tubes, 1 µl of 1 mg/mL inositol was added as internal 709
standard, and the samples were lyophilized. Methyl glycosides then were prepared from the dried samples 710
by methanolysis with 3 M HCl in methanol at 100 °C for 2 h, and re-N-acetylation with pyridine and 711
acetic anhydride in methanol. The samples then were per-O-trimethylsilylated (TMS) with a Tri-Sil 712
reagent (Thermo Scientific) at 80 °C for 30 min. Analysis of the TMS methyl glycosides was performed 713
on a Agilent 7890A gas chromatograph equipped with a Supelco EC-1 fused silica capillary column (30 714
m x 0.25 mm ID) and interfaced to a Agilent 5975C inert MSD. 715
716
Analysis of EPS 717
To assess whether hyaluronan is present in EPS of A. nidulans, its glycosyl composition of the EPS was 718
analyzed by GC-MS in our laboratory. EPS was first precipitated from culture supernatants of wild type 719
and cpsA mutant strain with 1 volume of ethanol 96% and dialyzed with water using a membrane with a 3 720
kDa cutoff. Samples were first hydrolyzed with 3 M trifluoroacetic acid (TFA) at 121 °C for 1 h, and 721
derivatized and analyzed as previously reported (Bernabé et al., 2011). 722
In addition, EPS was also analyzed by infrared spectroscopy. Infrared spectra were obtained by the KBr 723
technique. In brief, approximately 2 mg of dry sample were thoroughly mixed in a mortar with 300 mg of 724
KBr and maintained in a desiccator. The pellet was prepared by using a hydraulic press, applying a 725
pressure of 2 tons for 2 minutes and then 10 tons for 6 min. The spectra were recorded in a FTIR 4200 726
32
type A instrument (Jasco Corporation, Tokyo, Japan). Light source of transmittance was in the middle 727
range infrared 700–4000 cm-1. The detector used was triglycine-sulfate (TGS) with resolution 4 cm-1. 728
The type of linkages in the EPS was also analyzed after methylation of dry samples (1-3 mg). Then 729
samples were dissolved in dimethyl sulfoxide and processed according to the method of Ciucanu and 730
Kerek (1984). The per-O-methylated polysaccharides were hydrolyzed with 3 M TFA, reduced with 731
NaBD4, derivatized to their corresponding partially methylated alditol acetates, and analyzed GC-MS as 732
previously described (Shaaban et al., 2010). 733
Analysis of monosaccharides in membrane 734
Protoplasts from the wild-type strain TRV50.2 were prepared from mycelium grown on GMM for 16 h. 735
Four grams of mycelium was treated with Glucanex (Novozymes) for 1.5 h in 1.2 M MgSO4, 10 mM 736
phosphate buffer at pH 6.5. Protoplasts were purified as described in the transformation protocol from 737
Tiburn et al 1993 (Tilburn et al 1983). Protoplasts were lyophilized. The sample was hydrolyzed with 738
TFA under the same conditions described for EPS analysis, and the compounds released were derivatized 739
both as alditol acetates and as TMS-oxymes before GC/MS analysis. 740
741
Acknowledgements 742
This work was supported by NIH Grant 2R15AI081232-02 awarded to Ana Calvo. This research was also 743
supported in part by the National Institutes of Health (NIH)-funded Research Resource for Integrated 744
Glycotechnology” (NIH grant no. 5P41GM10339024) to Parastoo Azadi at the Complex Carbohydrate 745
Research Center. AMC also thanks Jessica Lohmar, Tim Satterlee, Parastoo Azadi, Yanbin Yi, Scott 746
Grayburn, Lori Bross, James Horn, and Barbara Ball for their technical support. 747
748
33
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Table S1. Sequence analysis of CpsA homologs in different fungi using NCBI BLAST and NEEDLE 1093
Pairwise sequence alignment. 1094
NCBI (National Center for Biotechnology Information)
EMBOSS Needle-Pairwise Sequenc Alignment (global alignment) (EBLOSUM 62)
Accession Number E-value (Blastp)
Length % Identity % similarity
Aspergillus nidulans AN9069(AspGD) 455
Aspergillus terreus NIH2624 XP_001209243.1 0.0 437 78.7 85.7
Neosartorya fischeri NRRL 181 XP_001262883.1 0.0 437 77.6 85.3
Aspergillus oryzae RIB40 XP_001825520.2 0.0 437 76.9 84.6
Aspergillus niger CBS 513.88 XP_001395099.2 0.0 437 76.0 84.4
Aspergillus flavus NRRL3357 XP_002380722.1 0.0 432 76.5 84.2
Penicillium oxalicum 114-2 EPS30883.1 0.0 437 75.2 84.8
Aspergillus clavatus NRRL 1 XP_001272298.1 0.0 437 75.4 84.2
Penicillium roqueforti CDM29186.1 0.0 437 72.5 84.2
Byssochlamys spectabilis No. 5 GAD99635.1 0.0 438 72.0 82.8
Talaromyces stipitatus ATCC 10500 XP_002488246.1 0.0 453 69.0 78.8
Talaromyces marneffei ATCC 18224
XP_002153204.1 0.0 453 70.7 82.1
Ajellomyces dermatitidis ATCC 18188
EGE77411.1 0.0 443 63.4 76.9
Arthroderma otae CBS 113480 XP_002846165.1 0.0 450 61.4 73.2
Arthroderma gypseum CBS 118893
XP_003171383.1 0.0 455 62.6 75.1
Aspergillus fumigatus Af293 XP_746682.1 0.0 366 65.3 71.6
Coccidioides immitis RS EAS29292.2 0.0 442 62.7 73.6
50
Trichophyton soudanense CBS 452.61
EZF76299.1 0.0 463 62.1 74.9
Trichophyton tonsurans CBS 112818
EGE00026.1 0.0 461 61.6 73.8
Trichophyton rubrum CBS 118892 XP_003233075.1 0.0 462 62.2 75.1
Uncinocarpus reesii 1704 XP_002582796.1 0.0 478 58.6 70.8
Cladophialophora psammophila CBS 110553
EXJ66589.1 0.0 460 61.8 72.3
Trichophyton interdigitale H6 EZF28355.1 0.0 452 57.8 70.0
Cladophialophora yegresii CBS 114405
EXJ61611.1 0.0 459 62.3 73.6
Coccidioides posadasii C735 delta SOWgp
XP_003067944.1 0.0 455 57.7 67.8
Cladophialophora carrionii CBS 160.54
ETI27167.1 0.0 459 61.1 73.2
Aspergillus ruber CBS 135680 EYE94145.1 0.0 302 54.7 60.2
Aspergillus kawachii IFO 4308 GAA91101.1 0.0 302 54.7 59.8
Exophiala dermatitidis NIH/UT8656
EHY56476.1 0.0 469 59.2 71.2
Capronia coronata CBS 617.96 EXJ83412.1 0.0 461 59.7 69.0
Capronia epimyces CBS 606.96 EXJ87365.1 0.0 461 57.1 71.5
Endocarpon pusillum Z07020 ERF70808.1 0.0 655 42.3 52.0
Paracoccidioides sp. 'lutzii' Pb01 XP_002789730.1 0.0 509 49.7 60.4
Penicillium digitatum Pd1 EKV11345.1 8e-180 303 52.5 58.7
Cyphellophora europaea CBS 101466
ETN46808.1 7e-178 462 58.0 72.5
Blastomyces dermatitidis ATCC 26199
EQL38488.1 6e-169 352 52.1 61.9
Trichophyton rubrum CBS 100081 EZF44401.1 6e-156 367 50.2 59.7
51
Dothistroma septosporum NZE10 EME46318.1 6e-156 465 52.6 67.6
Histoplasma capsulatus H143 EER44516.1 1e-149 304 43.9 53.3
Cercospora fijiensis CIRAD86 EME83393.1 4e-147 473 49.8 63.7
Paracoccidioides brasiliensis Pb18 EEH48190.1 2e-142 473 55.9 69.3
Baudoinia panamericana UAMH 10762
EMC98785.1 3e-142 457 49.7 63.3
Arthrobotrys oligospora ATCC 24927
EGX50474.1 6e-142 436 49.0 66.3
Sphaerulina musiva SO2202 EMF13967.1 1e-140 493 45.5 59.2
Zymoseptoria tritici IPO323 XP_003857553.1 4e-138 471 48.3 62.9
Macrophomina phaseolina MS6 EKG18474.1 4e-131 453 49.4 62.4
Marssonina brunnea f. sp. 'multigermtubi' MB_m1
XP_007296604.1 1e-125 522 40.0 54.9
Sclerotinia sclerotiorum 1980 UF-70
XP_001587297.1 5e-124 513 39.8 56.2
Blumeria graminis f. sp. tritici 96224
EPQ64353.1 8e-124 481 41.8 59.2
Blumeria graminis f. sp. hordei DH14
CCU81486.1 2e-123 481 42.6 60.4
Metarhizium acridum CQMa 102 EFY86657.1 2e-122 489 41.1 58.8
Botrytis cinerea B05.10 XP_001548088.1 2e-122 514 38.5 55.3
Metarhizium anisopliae ARSEF 23 EFZ03703.1 3e-122 495 41.2 58.4
Botrytis cinerea T4 CCD48940.1 1e-121 514 38.4 55.2
Trichoderma atroviride IMI 206040
EHK40282.1 1e-121 526 38.7 53.9
Pestalotiopsis fici W106-1 ETS75078.1 1e-121 507 40.8 50.0
Pyrenophora tritici-repentis Pt-1C-BFP
XP_001934872.1 2e-121 464 44.2 59.3
Fusarium verticillioides 7600 EWG36475.1 2e-121 529 38.4 53.2
52
Fusarium fujikuroi IMI 58289 CCT62864.1 9e-121 529 38.2 53.5
Fusarium oxysporum Fo5176 EGU78390.1 1e-120 529 38.2 53.2
1095
Table S2. Fungal strains used in this study. 1096
Strain name Pertinent genotype Source
FGSC4 Wild type (veA+) FGSC
RDAE206 yA2, pabaA1, pyrG89; argB2, ∆stcE::argB, ∆veA::argB Ramamoorthy et al. (2012)
RDAEp206 yA2; ΔstcE::argB, ΔveA::argB Ramamoorthy et al. (2012)
RAV1 yA2, pabaA1, pyrG89; wA3; argB2, ∆stcE::argB; veA1 Ramamoorthy et al. (2012)
RAV1p yA2; wA3; ΔstcE::argB; veA1 Ramamoorthy et al. (2012)
RAV2 yA2; wA3; argB2, ∆stcE::argB; pyroA4; veA1 Ramamoorthy et al. (2012)
RJH030 yA2; wA3; pabaA1; argB2; ΔstcE::argB; trpC801; veA1 Ramamoorthy et al. (2012)
RM1 yA2, pabaA1, pyrG89; argB2, ∆stcE::argB, ∆veA ::argB,
cpsA- This study
RM1p yA2, ΔstcE::argB, ΔveA ::argB, cpsA-, This study
RM1-R2 yA2, pyrG89; pabaA1; wA3; argB2, ∆stcE::argB, cpsA-,
veA1 This study
RM1p-R2 yA2; wA3; ΔstcE::argB, cpsA-, veA1 This study
RM1-R2-com yA2, pyrG89; pabaA1, wA3; argB2, ∆stcE::argB, cpsA-,
pRG3-AMA-NOT1- cpsA::pyr4; veA1 This study
RM1p-R2-com yA2, pyrG89; wA3; argB2, ∆stcE::argB, cpsA-, pRG3-
AMA-NOT1- cpsA::pyr4; veA1 This study
RJMP1.49 pyrG89; argB2, ∆nkuA::argB; pyroA4; veA+ Shaaban et al. (2010)
53
TRV50 argB2, ∆nkuA::argB; pyroA4; veA+ Ramamoorthy et al. (2012)
TRV50.2 argB2, ∆nkuA::argB; veA+ Ramamoorthy et al. (2012)
TRV∆cpsA pyrG89; argB2, ∆nkuA::argB; ∆cpsA::pyrG A.fum; pyroA4;
veA+ This study
TRVp∆cpsA ∆nkuA::argB; ∆cpsA::pyrGA.fum; veA+ This study
TRV∆cps-com
pyrG89; argB2, ∆nkuA::argB, ∆cpsA::pyrG A.fum;
pyroA::cpsA; pyroA4; veA+ This study
OEcpsA pyrG89; pyroA4, argB2, ∆nkuA::argB,
alcA(p)::cpsA::trpC(t)::pyr4; veA+ This study
OEpcpsA pyrG89; argB2, ∆nkuA::argB,
alcA(p)::cpsA::trpC(t)::pyr4; veA+ This study
TDAE∆cpsA pabaA1, pyrG89; ∆cpsA::pyrG A.fum, ∆stcE::argB,
∆veA::argB This study
TDAEp∆cpsA
TDAEp∆cpsA-
com
TXF1
∆cpsA::pyrGA.fum, ∆stcE::argB, ∆veA::argB
pyrG89; ∆ cpsA::pyrGA.fum, ∆stcE::argB, ∆veA::argB,
cpsA;:pyrG
pyrG89; pyroA4, ∆nkuA::argB; cpsA::gfp::pyrG, veA+
This study
This study
This study
_____________________________________________________________________________ 1097
FGSC, Fungal Genetics Stock Center. p, prototrophs obtained by transformation with the wild-type allele of the 1098
indicated auxotrophic marker genes. 1099
1100
54
1101
Table S3. Glycosyl composition analysis of cell wall fractions by GC-MS
Sample Glycosyl residue Mass (µg) Mol % WT Ribose (Rib) n.d. - Arabinose (Ara) n.d. - Rhamnose (Rha) n.d. - Fucose (Fuc) n.d. - Xylose (Xyl) n.d. - Glucuronic Acid (GlcA) n.d. - Galacturonic acid (GalA) n.d - Mannose (Man) 75.0 9.0 Galactose (Gal) 154.3 18.5 Glucose (Glc) 513.6 61.8 N-Acetyl Galactosamine (GalNAc) n.d. - N-Acetyl Glucosamine (GlcNAc) 108.4 10.6 Σ= 851.3 Sample Glycosyl residue Mass (µg) Mol % Deletion Ribose (Rib) n.d. - Arabinose (Ara) n.d. - Rhamnose (Rha) n.d. - Fucose (Fuc) n.d. - Xylose (Xyl) n.d. - Glucuronic Acid (GlcA) n.d. - Galacturonic acid (GalA) n.d. - Mannose (Man) 102.5 9.4 Galactose (Gal) 309.2 28.3 Glucose (Glc) 606.7 55.5 N-Acetyl Galactosamine (GalNAc) n.d. - N-Acetyl Glucosamine (GlcNAc) 93.0 6.9 Σ= 1111.4
1102
55
1103
Table S4. Monosaccharides (%) released from the
exopolysaccharide (EPS) after acid hydrolysis with
3 M TFA for 1 h at 120 ºC, detected as alditol acetates.
WT ∆cpsA
Mannose 0.7 0.7
Glucose 0.6 0.6
Galactose 29.1 22.9
Galactosamine 9.8 7.5
1104
Table S5. Monosaccharides (%) identify in membrane of A. nidulans wild
type using GC/MS after acid hydrolysis with 3 M TFA for 1 h at 120 ºC.
% Mannitol 2.5
Mannose 1.5
Glucose 22.7
Galactose 1.2
Glucosamine 1.6
1105
1106
56
1107
Table S6. Primers used in this study. 1108
Name Sequence (5’→ 3’)
RM1-F1
RM1-F2
ATCTGCTACTTGTGGTTCGGGAG
TACGCCTTAATCCAGACGGTCTCC
RM1-R2A
RM1-R4
cpsA-P2
cpsA-P3
cpsA-P5
cpsA-P6
AAAGAGAGGCAAAGTCACCGAACG
GAGTTTACGGACATTTGCTTGTGC
GCGGTGCCCAATGTGCCAAACGATCCC
CAGTACAGGGTGCCATGTCGGCGTGC
GGGATCGTTTGGCACATTGGGCACCGCACCGGTCGCCTCAAACAATGCTCT
GCACGCCGACATGGCACCCTGTACTGGTCTGAGAGGAGGCACTGATGCG
cps-com1 NNNNNGAATTCTGACAGGAACGGCAGTTAGCACGC
cps-com2 NNNNNNNAAGCTTCTAGGGCAAAGAGCTCTTGG
cps-OE1 NNNNNGGCGCGCCATGCACATAACGTATATGCGAGCGTTCATC
cps-OE2
gpdApromoF
NNNNNNNNNNNGCGGCCGCTCAGGAGATATCGGCCGAGGTTACAC
AAGTACTTTGCTACATCCATACTCC
RM1-F4 ATGTGACGGTCATAATCCCTACGC
RM1-F5 TCACTCGATGGATGGTCTCACA
RM1-R3 ACGTAACTAGGGCAAAGAGC
cpsgfp_P2 GGAGATATCGGCCGAGGTTAC
cpsgfp_P3 GCGTGGGCGGGTTCTCGTCGC
57
cpsgfp_P5
cpsgfp_P6
aflR-F
aflR-R
stcU-F
stcU-R
stuA-F
stuA-R
dvrA-F
dvrA-R
laeA-F
laeA-R
aatA-Q1
aatA-Q2
ipnA-Q1
ipnA-Q2
acvA-Q1
acvA-Q2
18SQ1
18SQ2
actinQ1
actinQ2
stuAQ1
stuAQ2
veAQ1
GTAACCTCGGCCGATATCTCCGGAGCTGGTGCAGGCGCTGGAGCC
GCGACGAGAACCCGCCCACGCGTCTGAGAGGAGGCACTGATGCG
GAGCCCCCAGCGATCAGC
CGGGGTTGCTCTCGTGCC
TTATCTAAAGGCCCCCCCATCAA
ATGTCCTCCTCCCCGATAATTACCGTC
ATGGCCAGCATGAATCAACCTCAACCG
GGTGGCGTAGGAAACGTATGTGCG
ACATCTCTTCGCCACCGGACCGC
GCCGCAACTCGGCTTCTGTCGGT
ATGACCTCTCCAGCGCACAACCACTACAGC
TCTTAATGGTTTCCTAGCCTGGTATATGTGCAG
CCATTGACTTCGCAACTGGCCTCATTCATGGCAAA
ATGACAATCTCCGATACTTCGCGTTCCGCACCCTTT
TCCCTACCCCGAGGCTGCTATCAAGACG
CATTTCACCCGATGGATGGGCGCTTT
CGTGACTAAACTGCTGCGGGTGGATAACGA
TGAACGGACTGGTATGGTGCGATTGTGG
GAGACCTCGGCCCTTAAATAGCCCGGTC
CCCAGAACATCTAAGGGCATCACAGACCTGTTATTGC
ATGGAAGAGGAAGTTGCTGCTCTCGTTATCGACAATGGTTC
CAATGGAGGGGAAGACGGCACGGG
TGTCACCAACCACCCTGTTCCCAC
CTTCTCTTCGAGCAACGCAGACACCC
TGTCGAACAGAGTCATATACTCTAGTCGATTCTTCTAGAGCATTTTGTG
58
ANThiOF_int ATGGGTGCCTCTGAACAC
ANThiOR_int CTAAGCAAGCAGAGCCTTGAT
catB-For GCCAATGCCGTCTGTCCGT
catB-Rev GTGGAACTTGACGAGCTTGGTGG
1109
1110
59
Figure Legends 1111
Figure 1. TLC analysis of NOR production in GMM cultures. (A) The strains ∆ veA ∆stcE 1112
(RDAEp206), veA1 ∆stcE (RAV1p), cpsA- ∆veA ∆stcE (RM1p), cpsA- cpsA+ ∆veA ∆stcE (RM1p-com), 1113
cpsA- veA1 ∆stcE (RM1p-R2), ∆ cpsA ∆veA ∆stcE (TDAE∆cpsA), ∆cpsA cpsA+ ∆ veA ∆stcE 1114
(TDAE∆cpsA-com) (Table S2), were top-agar inoculated and incubated at 37 °C in the dark for 5 days. 1115
NOR production was analyzed by TLC. (B) Intensity of NOR bands. Densitometry was carried out with 1116
GelQuant.NET software. NOR band intensity was normalized using the intensity corresponding to 1117
RDAEp206 as 1. The letters above the bars represent significantly different values (P ≤0.05, Tukey test). 1118
1119
Figure 2. cpsA is necessary for normal expression of ST genes and mycotoxin production in A. 1120
nidulans strains with a veA+ wild-type background. (A) Wild type (TRV50.2) (WT) veA+ control, 1121
∆cpsA (TRVp∆cpsA), complementation (TRVp∆cpsA-com)(com), and overexpression (OEpcpsA)(OE) 1122
strains were inoculated in liquid GMM. Mycelia were collected after 48 and 72 h of culture in a shaker 1123
incubator at 250 rpm at 37 °C. Expression of aflR and stcU was analyzed by Northern blot. rRNA serves 1124
as loading control. Asterisk indicates not detected. Densitometry of the Northern blot results is shown. 1125
(B) TLC analysis of ST production in 72 h cultures described in (A), densitometry of ST band intensity is 1126
shown. 1127
Figure 3. cpsA affects penicillin production. A) Extracts from wild-type (WT) veA+ control, ΔcpsA, 1128
complementation (com) and overexpression (OE) strains were analyzed for penicillin content as described 1129
in Materials and Methods section. (B) Quantification of penicillin content in the analyzed extracts. Values 1130
are means of three replicates. (C) qRT-PCR gene expression analysis by of acvA, ipnA and aatA from 1131
mycelial samples collected after 24 h and 48 h of incubation in PN inducing medium. The relative 1132
expression was calculated using the 2−ΔΔCT method, as described by Livak and Schmittgen (2001). Values 1133
60
were normalized to the expression levels in the wild type, considered 1. Error bars represent standard 1134
errors. The letters above the bars represent significantly different values (P ≤0.05). 1135
Figure 4. cpsA positively affects A. nidulans colony growth. (A) Photographs of wild-type (WT) veA+ 1136
control, ΔcpsA, complementation (com) and overexpression (OE) strains point-inoculated on GMM plates 1137
and incubated at 37 °C in either light or dark for 6 days. (B) Colony growth measured as colony diameter. 1138
Standard error is shown. Means are average of three replicates. 1139
Figure 5. cpsA is necessary for proper asexual and sexual development. (A) Micrographs of wild-type 1140
(WT) veA+ control, ΔcpsA, complementation (com) and overexpression (OE) strains point-inoculated 1141
GMM cultures incubated at 37 °C in either light or dark for 6 days. Samples were observed two 1142
centimeters from the inoculation point. Images were captured with an upright Leica MZ75 1143
stereomicroscope. Scale bar corresponds to 200 µm. (B) Quantitative analysis of production of conidia, 1144
Hülle cells and cleistothecia from top-agar inoculated GMM cultures incubated at 37 °C in either light or 1145
dark for 48 h and 72 h, in the case of conidia and Hülle cells, and 6 days in the case of cleistothecia. 1146
Asterisk indicates not detected. The experiment included three replicates. (C) qRT-PCR gene expression 1147
analysis of brlA, nsdD, steA and stuA from mycelial samples from 48 h and 72 h GMM liquid stationary 1148
cultures. The relative expression was calculated using the 2−ΔΔCT method, as described by Livak and 1149
Schmittgen (2001). Values were normalized to the expression levels in the wild type, considered 1. Error 1150
bars represent standard errors. 1151
Figure 6. Expression of veA and laeA is positively affected by cpsA. qRT-PCR gene expression 1152
analysis of veA and laeA from liquid stationary GMM cultures 48 h and 72 h after incubation in the dark 1153
at 37 oC. The relative expression was calculated using the 2−ΔΔCT method, as described by Livak and 1154
Schmittgen (2001). Levels in the wild type, considered 1. Error bars represent standard errors. The letters 1155
above the bars represent significantly different values (P ≤0.05). 1156
1157
61
Figure 7. Localization of CpsA protein. (A) Cellular localization of CpsA-GFP fusion protein expressed 1158
by its endogenous promoter. Cells were grown for 16 h at 25 C. CpsA accumulates at small vesicles 1159
resembling vacuoles and endosomes. The kymograph obtained from a stack of 90 images for 12 seconds 1160
(200 ms exposure each) along the line shown in GFP inset. Dashed line square indicates the limits of 1161
movie 1. Kymograph shows the presence of static and motile vesicles migrating in an anterograde (to the 1162
tip) and retrograde (from tip to base of cells) modes. (B) CMAC staining confirm the presence of CpsA-1163
GFP in small vacuoles. Details of the aggregates are shown at the bottom of the images. Asterisks 1164
indicate cell tips. Scale bar represents 5 micrometers. (C) Detection of CpsA-GFP fusion using GFP 1165
antibodies. TE indicates a total extract using an alkaline lysis protocol. Soluble protein from A50 1166
extraction protocol is shown in line SN. Insoluble protein in A50 treatment was analyzed in line P. An 1167
overexposure of the filter on the CpsA-GFP fusion region is shown. In both protocols a band 1168
corresponding to GFP is visualized as indication of protein degradation in vacuoles or MVs 1169
(multivesicular bodies)/lysosomes. 1170
1171
Figure 8. Absence of or overexpression of cpsA increases sensitivity to SDS and CFW. (A) Wild-type 1172
(WT) veA+ control, ΔcpsA, complementation (com) and overexpression (OE) strains were point 1173
inoculated on GMM containing SDS (A) and CFW (B) at different concentrations. Cultures were 1174
incubated at 37 °C in dark for 3 days. 1175
1176
Figure 9. cpsA is required for proper attachment of the cell wall to the plasma membrane. 1177
Transmission electron microscopy images of wild-type (WT) veA+ control, ΔcpsA, complementation 1178
(com) and overexpression (OE) strains. The strains were grown in liquid stationary GMM cultures at 1179
37°C for 48 h. Mycelia were fixed and stained with 2% uranyl acetate and 0.2% lead citrate. The arrows 1180
show the cell structure alteration with detachment of plasma membrane and cell wall. Micrographs were 1181
acquired with different magnifications represented by panels in (A) and (B). 1182
62
1183
Figure 10. cpsA is involved in adhesion to surfaces. (A) Conidia of wild-type (WT) veA+ control, 1184
ΔcpsA, complementation (com) and overexpression (OE) strains were inoculated in liquid GMM (105 1185
spores/ml), and incubated at 37 °C for 24 h and 48 h as stationary cultures. Mycelium was stained with 1186
Crystal violet as described in Materials and Methods section. The 48 h samples in panel A were dilluted 1187
2-fold for measurement at 560 nm. (B) Expression analysis of laeA, dvrA, and stuA by Northern blot. The 1188
strains were inoculated (105 spores/ml) in Petri dishes containing 20 ml of liquid GMM, and incubated at 1189
37 °C for 48 h and 72 h as stationary cultures. rRNA serves as loading control. Densitometry of the 1190
Northern blot results is shown. 1191
Figure 11. cpsA is necessary in resistance to oxidative stress in A. nidulans. (A) Wild-type (WT) veA+ 1192
control, ΔcpsA, complementation (com) and overexpression (OE) strains were point-inoculated on GMM 1193
containing different concentrations of menadione and incubated at 37 °C in dark for 3 days. Expression 1194
analysis of thiO by qRT-PCR (B) and catB by Northern blot (C and D). The strains were incubated in 1195
liquid GMM at 250 rpm at 37°C in the dark for 48 h. After that, mycelia were transferred to GMM with 1196
or without menadione (0.08 mM). rRNA serves as loading control. Densitometry of the Northern blot 1197
results is shown. 1198
1199
Figure 12. Model of the role of cpsA in A. nidulans. cpsA is necessary for proper attachment of the cell 1200
wall to the plasma membrane, and the normal cell wall composition and integrity that protect fungal cells 1201
from environmental stresses. All the genes in this model are downregulated in the absence of cpsA. The 1202
cpsA gene positively influences the expression of the master regulators veA, laeA and stuA, and is 1203
required for normal sexual and asexual development, secondary metabolism and biofilm formation. 1204
Supplemental Figures 1205
63
Figure S1. RM1 presents a single mutation in cpsA gene. (A) Complementation insert from the 1206
genomic library plasmid in the RM1 mutant and corresponding genomic fragment in the RM1 mutant. 1207
The red arrow shows the point mutation at nucleotide +568 of the cpsA coding region, from GAT to 1208
AAT, resulting in a change from glutamic acid (D) to Asparagine (N). (B) Alignment of the deduced 1209
amino acid sequences of A. nidulans cpsA and putative homologs in other Aspergillus species. The 1210
species compared are: Aspergillus terreus (NIH2624), Aspergillus clavatus (NRRL 1), Aspergillus 1211
fumigatus (Af293), Aspergillus niger (CBS 513.88, asterisk after residue A304 indicates the exclusive 1212
presence of 76 non-conserved amino acids, coordinates 305-380, in A.niger CpsA putative homolog), 1213
Aspergillus oryzae (RIB40), and Aspergillus flavus (NRRL 3357). Accession numbers of protein 1214
sequence are located in Table S1. The alignment was performed with MAFFT 1215
(http://www.ebi.ac.uk/Tools/msa/mafft/ ) multiple sequence alignment software program. Conserved 1216
residues are highlighted in blue with Jalview 2.9.0b2 (http://www.jaview.org/)) software program. The 1217
conserved domain, GT2_HA, is indicated with an orange bar (amino acid residues, 45-290), predicted 1218
Signal peptide and TM domains are indicated with cian and brown boxes, respectively. 1219
1220
Figure S2. Conservation of CpsA in different fungal genera. Multiple sequence alignment of CpsA 1221
putative homologs. Alignment was generated using MAFFT. The alignment was visualized by Jalview 1222
with conserved residues in dark blue. Species represented in alignment are: Aspergillus nidulans (Anid), 1223
Histoplasma capsulatum (Hcap), Trichoderma reesei (Tree), Botrytis cinerea (Bcin), Fusarium 1224
oxysporum (Foxy), Neurospora crassa (Ncra), Coccidioides immitis (Cimm), Stachybotrys chartarum 1225
(Scha), Acremonium chrysogeum (Achr), Crytococcus neoformans (Cneo), Coprinopsis cinera (Ccin), 1226
and Sphaerobolus stellastus (Sste). Accession numbers of each protein sequence are located in Table S1. 1227
1228
Figure S3. CpsA Phylogenetic Tree. Phylogenetic tree of CpsA putative homologs from different fungal 1229
species. Phylogenetic trees constructed using MEGA v6.0. Trees were constructed with Maximum-1230
64
Likelihood model with a bootstrap value of 1000. Green branches indicate Aspergillus spp., blue branches 1231
indicate other Ascomycota outside of Aspergillus, and red represents species from Basidomycota. 1232
Figure S4. Alignment of the deduced amino acid sequences of A. nidulans cpsA and putative 1233
bacterial homologs. The species compared are: Streptomyces pneumoniae, Streptacidiphilus albus, 1234
Actinomadura macra, Piscicoccus intestinalis, Frankia elaeagni, and Pseudonocardia acacia. The 1235
alignment was performed with MAFFT (http://www.ebi.ac.uk/Tools/msa/mafft/) multiple sequence 1236
alignment software program. Conserved residues are highlighted in black with BOXshade 1237
(http://www.ch.embnet.org/) software program. The conserved domain, GT2_HA, is underlined (amino 1238
acid residues, 45-290). DDD and XDD motifs are indicated with red boxes. 1239
1240
Figure S5. Generation of A. nidulans cpsA deletion, complementation and overexpression strains. 1241
(A) Schematic diagram showing the replacement of cpsA with the A. fumigatus pyrG gene (pyrGA. fum) by 1242
a double-crossover event. XhoI restriction sites and probe template used in the Southern blot analysis to 1243
confirm the proper integration of the cassette are shown. (B) Southern blot analysis results of 1244
TDAE∆cpsA and TRV∆cpsA transformants. The expected band sizes were 5.6 kb for wild type (WT) and 1245
3.1 kb for ∆cpsA. (C) Linear diagram of cpsA complementation plasmid pSM3-cpsA-com. The 1246
complementation strain was confirmed by diagnostic PCR, using primers RM1-F5 (F) and cps-OE2 (R) 1247
the expected 0.9 kb PCR product is shown. (C) Linear diagram of cpsA overexpression plasmid pTDS-1248
cpsOE. The overexpression transformants were confirmed by PCR with primers gpdApromoF (F) and 1249
cps-OE2 primers (R) yielded the predicted 1.8 kb product. (D) Expression analysis of cpsA by Northern 1250
blot. Wild type veA+ control (WT), ∆cpsA, complementation (com) and overexpression (OE) strains were 1251
inoculated in liquid GMM and incubated at 37 °C for 72 h. Densitometry of the Northen blot results is 1252
shown. Asterisk indicates not detected. 1253
65
Figure S6. Effect of cpsA deletion in ST production in GMM cultures containing different glucose 1254
concentrations. Wild type veA+ control (WT), ∆cpsA, complementation (com) and overexpression (OE) 1255
strains were top-agar inoculated and incubated at 37 °C in the dark for 2, 3 and 6 days. ST production was 1256
analyzed as described in the Materials and Methods section. White arrows indicate additional unknown 1257
compounds whose synthesis is cpsA-dependent. 1258
Figure S7. Localization of overexpressed CpsA-GFP. Fusion CpsA-GFP was overexpressed using the 1259
gpdA promoter. A micrograph of strain TSSP19.1 (Table S1) Localization of OE-CpsA-GFP is nearly 1260
identical to that observed using the cpsA endogenous propmoter. A kymograph shows the presence of 1261
static (grey triangles) and motile fluorescence accumulations, probably early endosomes. These 1262
organelles move in anterograde (c) or retrograde (b) direction and some reached the tip of the cell but 1263
rapidly migrate in opposite direction (a). Accumulation of CpsA-GFP at the plasma membrane was not 1264
detected. 1265
1266
Figure S8. Effect of cpsA on the resistance to osmotic stress and temperature changes. Wild type 1267
veA+ control (WT), ∆cpsA, complementation (com) and overexpression (OE) strains were point 1268
inoculated on GMM or GMM containing 0.7 M NaCl or 1.2 M of sorbitol, and incubated at 30 oC, 37°C 1269
or 45 oC in dark for 3 days. 1270
1271
Figure S10. Deletion of rlmA in the absence of veA does not rescue ST production. (A) Diagrams and 1272
verification of rlmA deletion in TSSP15.1 (∆rlmA) and TSSP16.1 (∆veA ∆rlmA) and (B) veA deletion in 1273
TXF2.1p (∆veA) and also in TSSP16.1 (∆veA ∆rlmA). The strains were confirmed by diagnostic PCR, 1274
obtaining the expected 2.7 kb (using primers ANrmlA_P1 (F) and pyrG_Afum_R (R)), and 2.8 kb 1275
products (using primers veAF5'UTR (F) and pyroAR)), respectively. (C) TLC analysis of ST from wild 1276
type (WT), ∆veA, ∆ rlmA and ∆veA∆rlmA double mutant from top-agar inoculated GMM cultures 1277
66
incubated for 72 h at 37 oC. ST standard (ST) was included on both sides of the TLC plate. (D) 1278
Densitometry of ST performed using GelQuantNET software. ST band intensity was normalized with 1279
respect to that of the wild type considered as 1. 1280
1281
Figure S10. Infrared spectroscopy analysis. Infrared spectra were obtained from wild type and cpsA 1282
mutant by the KBr method described in Materials and Methods. IR spectra from both samples were 1283
identical. 1284
1285
Figure S11. Linkage types in EPS. The type and abundance (%) of the linkages were deduced by 1286
methylation analysis of the EPS from A. nidulans wild type (wt) and cpsA mutant (mut). After 1287
derivatization to their corresponding partially methylated alditol acetates, samples were analyzed by GC-1288
MS as described in Materials and Methods. 1289
1290