1 La Trobe Institute for Molecular Science, Melbourne 3086 Victoria ...
Transcript of 1 La Trobe Institute for Molecular Science, Melbourne 3086 Victoria ...
1
The plasma membrane transregulator of polyamine uptake Agp2p regulates the antifungal activity 1
of the plant defensin NaD1 and other cationic peptides. 2
Mark R Bleackley1#, Jennifer L Wiltshire1, Francine Perrine-Walker1, Shaily Vasa1, Rhiannon L Burns1, 3
Nicole L van der Weerden1, Marilyn A Anderson1# 4
1 La Trobe Institute for Molecular Science, Melbourne 3086 5
Victoria, Australia 6
# Address correspondence to: Mark R Bleackley ([email protected], +61 3 7
94792353) or Marilyn A Anderson ([email protected], +61 3 9479 1255) 8
Running Title: Agp2 and NaD1 activity 9
AAC Accepts, published online ahead of print on 24 February 2014Antimicrob. Agents Chemother. doi:10.1128/AAC.02087-13Copyright © 2014, American Society for Microbiology. All Rights Reserved.
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Abstract 10
Cationic antifungal peptides (AFPs) act through a variety of mechanisms but share the common 11
feature of interaction with the fungal cell surface. NaD1, a defensin from Nicotiana alata, has 12
potent antifungal activity against a variety of fungi of both hyphal and yeast morphologies. The 13
mechanism of action of NaD1 occurs via three steps; binding to the fungal cell surface, 14
permeabilization of the plasma membrane, internalization and interaction with intracellular targets 15
to induce fungal cell death. The targets at each of these three stages have yet to be defined. In this 16
study, screening of a Saccharomyces cerevisiae deletion collection led to identification of Agp2p as a 17
regulator of the potency of NaD1. Agp2p is a plasma membrane protein that regulates transport of 18
polyamines and other molecules, many of which carry a positive charge. Cells lacking the agp2 gene 19
were more resistant to NaD1 and this resistance was accompanied by decreased uptake of defensin. 20
Competitive inhibition of the antifungal activity of NaD1 by the polyamine spermidine, one of the 21
molecules that Agp2p senses and regulates the uptake of, was observed in both S. cerevisiae and the 22
plant pathogen Fusarium oxysporum. Resistance of agp2Δ to other cationic antifungal peptides and 23
decreased binding to the cationic protein cytochrome c to agp2Δ compared to wildtype have led to a 24
proposed mechanism of resistance whereby deletion of agp2 leads to an increase of positively 25
charged molecules at the cell surface that repels cationic antifungal peptides. 26
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Introduction 28
Fungal pathogens infect plant and animal species and are being increasingly recognised as a threat 29
to human health, biodiversity and agriculture [1]. Present day infections of major crops including 30
wheat, soy bean, corn and banana lead to significant yield losses [1, 2]. Thus development of novel 31
systems for prevention of fungal infection in plants has been identified as a key point in protecting 32
global food security [3]. One way to combat the damaging effects of fungal pathogens is to identify 33
the most potent antifungal molecules that have evolved in nature. Elucidation of the mechanisms 34
by which they inhibit infection can in turn be used to facilitate their development as tools to combat 35
fungal pathogens. Of particular interest are gene encoded innate immunity peptides that are 36
produced by a wide range of organisms including animals, plants, insects, fungi and bacteria [4]. 37
Plants lack an adaptive immune system and have therefore evolved a variety of innate immune 38
responses to protect against infection [5]. A major component of the plant innate immune system is 39
the production of antimicrobial peptides [6], many of which are active against a variety of fungi [4]. 40
Gene encoded peptides are of particular interest as once the sequence is known the encoding DNA 41
can be used to produce the peptides recombinantly for characterization and as well as for 42
construction of transgenic plants with increased antifungal resistance. Gaining an understanding of 43
the mechanisms by which these proteins act against fungal pathogens is crucial for the design of 44
improved antifungal molecules and treatment regimens. 45
One of the largest families of plant antimicrobial peptides is the defensins [7-9]. Plant defensins are 46
small (45-54 amino acid) basic proteins with four to five disulphide bonds [7]. Although there is 47
structural conservation among plant defensins, there is substantial variability in the amino acid 48
sequences which leads to a variety of biological functions and mechanisms of action [4, 9]. The 49
mechanisms of antifungal activity also vary between defensins and although not well defined include 50
features such as sphingolipid binding, generation of reactive oxygen species (ROS), cell wall stress, 51
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septin mislocalization, programmed cell death, blocking of calcium channels and cell cycle arrest [10-52
16]. 53
NaD1 is a defensin from the ornamental tobacco Nicotiana alata [17] that kills filamentous fungi 54
such as Fusarium graminearum and F. oxysporum [18], the human fungal pathogens Candida 55
albicans and Cryptococcus neoformans and the model yeast Saccharomyces cerevisiae [19]. 56
Transgenic cotton plants expressing NaD1 are resistant to F. oxysporum and Verticillium dahlia in the 57
field [20]. Killing of the fungal cell is proposed to occur via a three step process dependent on the 58
presence of the fungal cell wall. Exposure of fungi to NaD1 results in ROS and nitric oxide (NO) 59
production as well as permeabilization of the fungal membrane [18, 19, 21] and has been proposed 60
to involve dimerization of the defensin [22]. Studies on the activity of NaD1 in C. albicans have 61
revealed that the Hog1 pathway plays a role in protecting the cell from the damaging effects of 62
NaD1 and S. cerevisiae studies have provided evidence for the involvement of active mitochondria in 63
ROS production [19]. However, the cell surface receptor and intracellular targets of NaD1 have yet to 64
be elucidated. With the aim of identifying these components, we screened the non-essential S. 65
cerevisiae deletion collection for strains that are resistant to NaD1. This led to the identification of a 66
set of genes involved in polyamine transport as having a role in the antifungal activity of NaD1. Of 67
particular interest was the cell membrane regulator of polyamine and carnitine transport Agp2p. 68
Deletion of the agp2 gene imparted resistance to NaD1 via a mechanism that includes diminished 69
uptake of the defensin. Further analysis of antifungal peptide sensitivity in agp2Δ revealed a link 70
between polyamine uptake and the activity of cationic antifungal peptides as a whole. 71
Materials and Methods 72
Yeast strains and media 73
The S. cerevisiae non-essential deletion collection was purchased from Thermo Scientific and is in a 74
BY4741 (MATa his3∆0 leu2∆0 met15∆0 ura3∆0) background. Mutant strains were retrieved from the 75
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deletion collection and compared to BY4741. Double mutants were made by amplifying the URA3 76
gene from the pRS426 plasmid using primers containing 40bp regions corresponding to the 5’ and 3’ 77
ends of the coding region upstream of the pRS426 binding sequence (italics). The sequences of these 78
primer pairs were Dur3F 79
ATGGGAGAATTTAAACCTCCGCTACCTCAAGGCGCTGGGTCTGTGCGGTATTTCACACCG and Dur3R 80
TTAAATTATTTCATCAACTTGTCCGAAATGTGATGATTGTCGATTGTACTGAGAGTGCAC, Sam3F 81
ATGGATATACTCAAGAGGGGAAATGAATCGGACAAGTTTACTGTGCGGTATTTCACACCG and Sam3R 82
TAACACCAAAATCTGTAGATTTTGTAATAGAATGGCTTAGGATTGTACTGAGAGTGCAC. PCR products were 83
purified using a Wizard PCR clean-up kit (Promega) and transformed into yeast cells via 84
electroporation. Mutants were colonies selected on SD-URA (0.67% yeast nitrogen base without 85
amino acids (Sigma), 0.077% -URA DO supplement (Clontech) agar plates. Overnight cultures for all 86
S. cerevisiae experiments were grown in YPD (1% yeast extract, 2% peptone, 2% dextrose). All 87
mutants were confirmed by genotyping. 88
Fusarium oxysporum f. sp. vasinfectum (Australian isolate VCG01111 isolated from cotton; Farming 89
Systems Institute, DPI, Queensland, Australia, a gift from Wayne O’Neill) overnight cultures were 90
grown in ½ strength Potato Dextrose Broth (1/2 PDB) (BD Difco). All experiments were conducted in 91
1/2 PDB except where otherwise noted. All chemicals were purchased from Sigma unless otherwise 92
noted. NaD1 was purified from Nicotiana alata flowers as outlined in [18]. HBD2 was expressed in 93
Pichia pink (Life Technologies) using the protocol outlined in [19]. Other antifungal peptides were 94
purchased from GenScript (Hong Kong) or GL Biochem (Shanghai). 95
Yeast deletion screen 96
The non-essential S. cerevisiae deletion collection (ThermoScientific) [23, 24] was grown overnight at 97
30⁰C in 96 well plates in YPD supplemented with G418 (200µg/mL) (Amresco). Each strain was 98
diluted 1:100 with ½ PDB and diluted culture (5 µL) was added to 95µL of ½ PDB containing 4µM 99
NaD1. This concentration of NaD1 was chosen as it was the lowest concentration where >90% 100
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inhibition was regularly observed in preliminary experiments on wild type yeast conducted under 101
the same conditions as the screen (data not shown). Half-strength PDB with no added protein was 102
used as a control. Liquid handling was performed with a Bravo Automated liquid handling platform 103
(Agilent technologies). Growth was measured as the increase in absorbance at 595 nm after 104
incubation for 20 h at 30⁰C. Absorbance at 595 nm was measured using a SpectraMax M5e plate 105
reader (Molecular Devices). Percent growth inhibition [(growth in control media - growth in NaD1 106
media)/growth in control media x 100] was calculated for each strain and resistant strains were 107
defined as those with a percentage growth inhibition that was more than two standard deviations 108
below the mean. Strains that did not grow in ½ PDB were eliminated from the analysis and the 109
remaining resistant strains were rescreened in triplicate in 4µM NaD1 to ensure reproducibility. 110
Strains exhibiting less than 60% growth inhibition in the triplicate screen were then considered the 111
NaD1 resistant subset. P-values were calculated using the embedded function in Microsoft Excel. 112
Antifungal assays 113
Antifungal protein stock solutions were prepared at 10x the desired final concentration in sterile 114
milliQ water. Ten microliters of these solutions were added to the wells of a 96 well microtitre plate 115
along with 90 µL of overnight culture that had been diluted to OD 600=0.01 in ½ PDB. Growth was 116
measured as the increase in absorbance at 595 nm after incubation for 20 h at 30⁰C. Absorbance at 117
595 nm was measured using a SpectraMax M5e plate reader (Molecular Devices). Percent growth 118
inhibition was calculated as above. All experiments were replicated at least three times. 119
Survival assays 120
Antifungal protein stocks were prepared as above and added to 90µL aliquots of overnight cultures 121
that had been diluted to OD600=0.2. For experiments on the effect of spermidine, spermidine was 122
prepared at 100x the final concentration and 1µL was added to diluted cells together with 10µL of 123
the antifungal protein. Cells were incubated for 1h at 30⁰C. After incubation the cells were serially 124
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diluted 3x and each dilution was plated (4µL) on a YPD plate and incubated at 30⁰C for 48h. All 125
experiments were repeated a minimum of three times and results were consistent across replicates. 126
Membrane permeabilization assays 127
Membrane permeabilization assays were performed using a protocol modified from [21]. Briefly, 128
antifungal protein solutions were prepared as 10x concentrates in milliQ water as described for the 129
antifungal assays except for experiments also involving polyamines. In these experiments NaD1 was 130
made up at 20x the final concentration and the polyamine (putrescine or spermidine) was made up 131
at 10x the final concentration. The NaD1 solution (5µL) and the polyamine solution (10µL) were 132
transferred to the wells of a black 96 well plate (Nunc). S. cerevisiae overnight cultures (85µL) that 133
had been diluted to OD 600=0.1 in ½ PDB with 1µM SYTOX green (Molecular Probes) were then 134
added to the wells prior to analysis. SYTOX green uptake was measured using a SpectraMax M5e 135
plate reader (Molecular Devices) with excitation and emission wavelengths of 488nm and 538nm 136
respectively. All data presented was consistent across at least three independent replicates. 137
Microscopy 138
Yeast cells were grown overnight in YPD liquid medium and diluted to an OD600nm of 0.5-0.6 139
(Biophotometer, Eppendorf) in 1/2 PBD. The yeast cell suspension (300µL) was then placed in µ-slide 140
8 wells (Ibidi) for live cell imaging. All live cell imaging experiments were maintained at 30⁰C within a 141
Zeiss Clear Perspex Incubator equipped with a heater and temperature controller (Temp Control 37-142
2 digital). NaD1 was labelled with the fluorophore BODIPY-FL-EDA (Molecular probes) as outlined in 143
[21]. Samples were treated with 0 or 25µL of 2.5mg/mL BODIPY labelled-NaD1 peptide stock 144
solution. The yeast cells were then visualized by confocal microscopy using a Zeiss LSM 510 laser 145
scanning Axiovert 200M inverted confocal microscope with a Plan Apochromat 100X/1.4 Oil DIC 146
objective. For live cell imaging, the cells were excited at the 488nm with an Argon laser using band 147
pass filters BP505-530 or BP505-550 for detection of BODIPY fluorescence (green). Time series 148
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images at 30 and 60 second intervals over 36 minutes were acquired using the Zen 2009 image 149
acquisition software (Carl Zeiss MicroImaing GmbH 1997-2011). Control experiments were 150
performed using the same parameters. Experiments were conducted in triplicate. Images were 151
further analyzed using Fiji software (Image J 1.47h version) (Rasband,W.S., ImageJ , U.S. National 152
Institutes of Health, Bethesda, Maryland, USA, 1997-2012) and Zeiss LSM Image Browser Version 153
4.2.0.121 (Carl Zeiss MicroImaging GmbH 1997-2006) and were processed in Illustrator CS6 (Adobe). 154
Flow cytometry 155
S. cerevisiae strains were grown overnight in YPD then diluted to OD 600=0.1 in ½ PDB before 100µL 156
aliquots were treated with a given concentration (0, 5, 10, 20µM) of BODIPY labelled NaD1 for 30 157
min or 3 h in the absence of light. Cells were then washed two times with 100µL of phosphate 158
buffered saline (PBS, 137mM NaCl, 2.7mM KCl, 10mM Na2HPO4, 2mM KH2PO4, pH 7.4) before they 159
were resuspended in 100µL PBS. Samples were then transferred to a U-bottom 96 well plate 160
(Greiner) and analysed using the FITC channel on a FACS Canto II fitted with an HTS sampler (BD 161
Biosciences). FACS analysis was performed using Weasel (Walter and Elisa Hall Institute for Medical 162
Research). 163
NaD1 pull down and Western blot. 164
BY4741, sam3/dur3 and agp2Δ cells were grown overnight at 30⁰C in liquid YPD. One mL of cell 165
culture was pelleted and cells washed 2X with 1mL of MilliQ H2O in 1.5 mL microfuge tubes. Cells 166
were then resuspended in ½ PDB at an OD600nm=0.5. BY4741 cells were resuspended with and 167
without the addition of 100µM spermidine. NaD1 was added to a final concentration of 20µM in a 168
final volume of 100µL. Each treatment was then rotated at room temperature on a Ratek RSM6 169
wheel for 30 min. Cells were then pelleted at max speed in a microfuge, washed with 100µL of MilliQ 170
water, resuspended in 20µL of 0.01% SDS. NuPAGE LDS sample buffer (Life Technologies) and Bond-171
Breaker TCEP solution (Thermo) (5µL total of a 9:1 solution of NuPAGE LDS buffer:Bondbreaker) was 172
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added to each sample and incubated at 90⁰C for 20min. Total cell suspensions were run on SDS-173
PAGE. Proteins were transferred to nitrocellulose using a Trans-Blot Turbo (Biorad). NaD1 levels 174
were determined by Western blot using an anti-NaD1 primary antibody [18] and donkey anti-rabbit 175
(GE healthcare) secondary antibody. Immunoreactive NaD1 was visualized using the GE Healthcare 176
ECL Western Blotting Detection Reagents kit and densitometry of resulting bands was performed 177
using the Image Lab software package (Biorad). 178
Cytochrome c binding assay. 179
The cyctochrome c binding assay was modified from the protocol outlined in [25]. Yeast cells were 180
grown overnight at 30⁰C in liquid YPD and cells were pelleted and resuspended at an OD600=13. 181
Cells in a 1 mL aliquot of each strain were washed 2x with PBS and resuspended in 1mL of PBS. Cells 182
(100µL) were then added to 300 µL of a cytochrome c solution (0.5mg/mL of equine cytochrome c 183
(Sigma) in PBS) and incubated at room temperature on a a Ratek RSM6 wheel for 20 min. Cells were 184
then pelleted and the supernatant (3x100µL) was transferred to the wells of a 96 well microtitre 185
plate. Cytochrome c remaining in the supernatant was quantified spectrophotometrically at 530nm, 186
the absorption maximum of the protein resulting from the heme prosthetic group. 187
Results 188
Yeast deletion screen 189
Screening of the S. cerevisiae haploid non-essential deletion collection for strains resistant to 4µM 190
NaD1 revealed the expected normal distribution of phenotypes across the collection (Figure 1A). 191
Strains were selected as resistant if the percent growth inhibition was more than two standard 192
deviations below the mean (<89%). Eighty one strains were resistant to NaD1 and these strains were 193
re-arrayed in a microtitre plate and rescreened against 4µM NaD1 in triplicate. Strains that exhibited 194
an average percent growth inhibition of less than 60 percent were then considered the set of 195
resistant deletion strains (Table 1 and Figure 1B). No growth was observed for BY4741 in the 196
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triplicate re-screen. Functional cluster analysis of the resistant strains was performed using FunSpec 197
[26]. Minimal clustering was observed for any GO or MIPS classifications. However, there was some 198
indication of enrichment for genes with functions in the mitochondria and in polyamine transport. 199
Manual examination of the annotated locations and functions of the genes deleted in the NaD1 200
resistant set using the Saccharomyces genome database (www.yeastgenome.org) further supported 201
a role for mitochondria (cbp1, ccs1, tuf1, mrp7) and polyamine transport (agp2, brp1, ptk2, sky1) 202
[27] in the antifungal activity of NaD1. A link between functional mitochondria and NaD1 activity has 203
been reported previously [19] so we chose to pursue the role of polyamine transport in NaD1 204
activity as the focus for subsequent experiments. 205
Resistant strains with deletions in genes with known functions in polyamine transport (agp2, brp1, 206
ptk2, sky1) [27], all of which had a p-value for resistance less than 1x10-4 from the triplicate rescreen, 207
were retrieved from the deletion collection and reassessed across a range of NaD1 concentrations to 208
determine the IC50 of NaD1 against these strains. All four strains showed significant resistance to 209
NaD1 with IC50s of between 2.75 and 4 µM (relative to 2 µM for wild type) (Figure 2A). The most 210
resistant strain was agp2Δ which encodes a regulator of high affinity polyamine transport [28]. It is 211
important to note that the antifungal assays were performed at a lower cell density (OD600=0.01) 212
than the experiments outlined in the following sections (OD600=0.1-0.5). Higher concentrations of 213
NaD1 are required to achieve the same level of growth inhibition when higher cell densities are 214
used. 215
A link between polyamine transport and NaD1 induced membrane permeabilization 216
To further investigate NaD1 resistance in yeast strains with deletions of genes that function in 217
polyamine uptake, the kinetics of membrane permeabilization were monitored using a SYTOX green 218
mediated assay. Membrane permeabilization is likely downstream effect of the activity of NaD1 and 219
as such membrane permeabilization is delayed compared to other antifungal peptides for which 220
membrane disruption is the primary mode of action[21]. Consistent with the growth assays, the set 221
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of NaD1 resistant strains were permeabilized more slowly by NaD1 than the wild type (Figure 2B) 222
with agp2Δ exhibiting a lower (around 20% wild type) level of SYTOX green uptake than the other 223
mutants (60-90% wild type). Agp2p is a plasma membrane protein that senses the polycation 224
spermidine and regulates the expression of proteins that transport spermidine into the cell [28]. 225
Since NaD1 is a positively charged protein, we considered whether it binds to the cell by exploiting 226
polyamine binding molecules on the surface of the cell. This was investigated by measuring NaD1 227
mediated membrane permeabilization in the presence of increasing concentrations of spermidine or 228
putrescine. Spermidine protected S. cerevisiae from membrane permeabilization by NaD1 in a 229
concentration dependent manner (Figure 3A). In contrast, putrescine had little effect on NaD1-230
induced membrane permeabilization (Figure 3B). The effect of spermidine on NaD1-induced cell 231
death was also measured (Figure 4). The addition of spermidine enhanced survival of BY4741 cells. 232
Cells treated with 100µM spermdine showed a similar level of survival as agp2Δ cells without added 233
spermidine. As with the membrane permeabilization assay, spermidine protected cells against the 234
activity of NaD1 in a concentration dependent manner. Addition of exogenous putrescine had no 235
observable effect on cell survival (data not shown). To confirm that the link between polyamines and 236
NaD1 is conserved from the model yeast to plant pathogens, membrane permeabilization assays in 237
the presence of polyamines were repeated using Fusarium oxysporum f.sp. vasinfectum. Consistent 238
with the results in S. cerevisiae, spermidine inhibited NaD1-induced membrane permeabilization in a 239
concentration dependent manner and putrescine was less effective than spermidine (Figure 3C). 240
Cells lacking Agp2p have reduced uptake of NaD1 241
In previous studies with F. oxysporum and C. albicans we demonstrated that NaD1 is transported 242
into the fungal cytoplasm as part of the mechanism for fungal cell killing [18, 19]. Confocal 243
microscopy using NaD1 labelled with the fluorophore BODIPY-FL-EDA revealed that uptake of the 244
defensin was lower in agp2Δ compared to the wildtype over a time course of 30min (Figure 5A). 245
Uptake of BODIPY-NaD1 was also measured by flow cytometry. As observed in the fluorescence 246
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microscopy, uptake of BODIPY-NaD1 over 30min was lower in agp2Δ compared to the wildtype 247
BY4741 cells at all NaD1 concentrations tested (Figure 5B,C). Uptake of BODIPY-NaD1 was 248
concentration dependent in both strains and was not fully dependent on the presence of Agp2p. As 249
spermidine decreased the membrane permeabilizing activity of NaD1 the effect of spermidine on 250
NaD1 binding and uptake was assayed using a whole cell pull down followed by Western blotting to 251
detect levels of NaD1 associated with the yeast cells. Cells treated with 100 µM spermidine pulled 252
down 47.3% of the amount of NaD1 that was pulled down by untreated wild type cells. Similarly the 253
agp2Δ cells pulled down only 29.7% of the NaD1 that was associated with the untreated wild type 254
cells (Figure 5D,E,F). 255
Analysis of other polyamine transport mutants 256
To determine whether the resistance observed in agp2Δ was specific to the lack of Agp2 protein in 257
the membrane or a defect in cellular polyamine transport, the phenotype of yeast strains lacking 258
two other polyamine transport proteins, dur3Δ and sam3Δ [29], as well as the double mutants 259
dur3Δ/agp2Δ and sam3Δ/agp2Δ was investigated. The single mutants exhibited the same sensitivity 260
to NaD1 as the wild type and the double mutants had the same resistance as agp2Δ (Figure 6). That 261
is, deletion of other polyamine transporters did not enhance resistance to NaD1 in a wild type or 262
agp2Δ background. To further this line of investigation the phenotype of a sam3Δ/dur3Δ double 263
mutant was also examined. No resistance to NaD1 was observed in the sam3Δ/dur3Δ double 264
mutant compared to wild-type (Figure 8b). Interestingly, the double mutant bound less NaD1 in the 265
whole cell pull down assay despite the lack of phenotype (Figure 5 E,F). 266
Resistance of agp2Δ to other antifungal peptides 267
We hypothesized that the mechanism for the involvement of Agp2p in the activity of NaD1 was in 268
providing a binding partner through a cation binding site normally utilized for the polyamine 269
spermidine. To determine whether the interaction was specific for NaD1 we assayed agp2Δ for 270
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resistance to other positively charged antifungal proteins: CP29, a cecropin–bee melittin hybrid 271
peptide variant that permeabilizes microbial membranes [30], BMAP28 a cathelcidin variant with 272
membrane permeabilizing activity [31], Bac2a a bactenicin variant that enters the cytoplasm of 273
microbial cells [32] and HBD2 a human beta defensin [33], in addition to hydrogen peroxide as a 274
control. The agp2Δ mutant was more resistant than BY4741 for every antifungal peptide tested 275
(Figure 7) but not hydrogen peroxide implicating Agp2p in the general sensitivity of S. cerevisiae to 276
cationic antifungal peptides. The lack of resistance to hydrogen peroxide indicates that this 277
resistance is specific to cationic antifungal proteins and is not merely due to an increase in general 278
fitness in the agp2Δ mutant. As we had already constructed the sam3Δ/dur3Δ double mutants we 279
also tested other AFPs against the double mutant. No resistance was observed in the double mutant 280
compared to wildtype for the panel of AFPs we tested (Figure 8). In fact the double mutant was 281
slightly more sensitive to cationic AFPs than the wildtype. 282
Cytochrome c binding in agp2Δ. 283
As agp2Δ was resistant to a range of cationic AFPs we hypothesized that the mechanism of 284
resistance was an increase in positive charge on the cell surface of the mutant cells which decreased 285
binding of cationic proteins to the cell surface. To test this hypothesis of an increase in positive 286
charge we measured binding of cytochrome c. Cytochrome c is a cationic protein (pI 10-10.5) with a 287
heme prosthetic group that absorbs at 530nm. Thus levels of cytochrome c remaining in the 288
supernatant were measured after cells were incubated with cytochrome c by measuring the 289
absorbance at 530nm. Wildtype (BY4741) cells bound to a most of the added cytochrome c whereas 290
a negligible amount of cytochrome c bound to the agp2Δ cells over the 20 min time course (Figure 291
9). 292
Discussion 293
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In this paper we describe a genetic approach to identify the target molecules of the antifungal 294
defensin NaD1. The S. cerevisiae non-essential deletion collection was screened to identify strains 295
that were resistant to NaD1. An enrichment of mitochondrial genes, many of which yield a petite 296
phenotype when deleted, was found in the set of NaD1 resistant deletions. This is in agreement with 297
a previous study whereby a role for respiratory competent mitochondria and reactive oxygen 298
species in the antifungal activity of NaD1 was described [19]. In this study, a role for the plasma 299
membrane regulator of spermidine transport Agp2p was also identified and confirmed via growth 300
assays, membrane permeabilization assays, microscopy and flow cytometry. Cells lacking Agp2 were 301
resistant to NaD1 and showed decreased uptake of the labelled defensin. This decreased uptake led 302
to the conclusion that the moiety that NaD1 binds to on the cell surface is absent, down regulated or 303
modified in the absence of Agp2p or that the lack of Agp2p caused an increase in the concentration 304
of molecules that interfere with NaD1 binding to the cell surface. Resistance of agp2Δ to NaD1 was 305
more robust at earlier time points which indicates that the defensin was able to partially overcome 306
the resistance mechanism upon prolonged exposure to the fungus. Application of exogenous 307
spermidine, one of the key molecules Agp2p senses, provided protection against the antifungal 308
activity of NaD1 and decreased uptake of the defensin into yeast cells, further linking Agp2p to the 309
activity of NaD1. Spermidine also protected F. oxysporum against NaD1 which indicates that this 310
mechanism may be conserved in pathogenic fungi. Resistance of agp2Δ to other cationic antifungal 311
peptides was also observed. These observations have led us to the conclusion that polyamine 312
uptake and metabolism is linked to susceptibility of fungi to cationic antifungal proteins. 313
Spermidine is a polycationic molecule belonging to a family called polyamines that have a number of 314
biological functions including roles as plant growth factors and stress response molecules in a range 315
of organisms [34] as well as the induction of mycotoxin production in Fusarium graminearum [35]. 316
The positive charge allows polyamines to associate with polyanions such as nucleic acids and lipids 317
as well as proteins. Furthermore interactions with cellular components allow polyamines to mediate 318
a variety of intracellular processes by modulating gene expression [36]. An example of polyamine 319
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mediated gene expression has been well described in Pseudomonas aeruginosa PAO1. In this system 320
exogenous spermidine induces the oprH-phoPQ operon, which encodes a membrane porin and a 321
two component regulatory system. It also induces the PA3552-PA3559 operon which functions in 322
lipopolysaccharide (LPS) modification. The end result of this altered gene expression is resistance to 323
cationic peptide antibiotics such as polymyxin B as well as aminoglycosides and quinolone antibiotics 324
[37]. As this mechanism centres on LPS, which is not present in fungi, it was eliminated as a possible 325
mechanism of resistance to NaD1 as reported here. Interestingly, polyamines are reported to have 326
the opposite effect on other antibiotics including beta-lactams where the application of exogenous 327
polyamine increases sensitivity of the bacteria [38]. 328
Three hypotheses for the role of Agp2 and polyamines in the activity of NaD1 were initially 329
considered. First, as Agp2p is a plasma membrane protein, we considered that it may be the cell 330
surface receptor for NaD1. The implication of plasma membrane polyamine binding proteins in the 331
mechanism of antifungal proteins is not unique. Histatin 5, an antifungal peptide from human saliva, 332
kills Candida albicans cells via a mechanism that involves binding to Dur3p and Dur31p which are 333
both polyamine transporters [39]. In addition, histatin 5 resistant C. glabrata strains can be made 334
sensitive to Histatin 5 by expressing the C. albicans DUR3 and DUR31 proteins [40]. Thus the first 335
hypothesis was based on similar rational as proposed for Histatin 5, that is, polyamines are positively 336
charged molecules and the proteins that bind them would possess a cation binding region. NaD1 337
also carries a positive charge and thus could bind to Agp2p on the cell surface by exploiting the 338
cation binding sites in the protein. This model fits the decreased activity of NaD1 in the presence of 339
increased spermidine as spermidine would compete with NaD1 for binding to Agp2p in the plasma 340
membrane. However, when we also considered the broad spectrum resistance of agp2Δ to cationic 341
antifungal peptides this model did not seem applicable. The sequences and structures of the other 342
AFPs tested vary significantly from each other and NaD1. NaD1 acts through a complex mechanism 343
that involves binding to the cell wall and translocation into the fungal cytoplasm. CP29 and BMAP28 344
are short, membrane permeabilizing peptides with little secondary structure. Bac2a is a short linear 345
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peptide that enters the cytoplasm and kills fungal cells through a yet to be described mechanism. 346
HBD2 adopts the characteristic defensin fold and also acts through a complex mechanism. It is 347
unlikely that a group of proteins as diverse as the ones tested here would have a common binding 348
partner on the cell surface. 349
Agp2p was recently shown to regulate the expression of a large number of genes, many of which 350
encode plasma membrane transporters including those for polyamine uptake [28]. This formed the 351
basis of our second model for the role of Agp2p in the activity of cationic antimicrobial peptides. 352
Here we hypothesized that different cationic AFPs bind to different plasma membrane proteins, all 353
of which are regulated by Agp2p. This fits with the agp2Δ phenotype as in the absence of Agp2p 354
these genes are not expressed as highly. That is a decreased level of receptor protein on the cell 355
surface would underlie the resistance to cationic AFPs observed in agp2Δ. Along the same lines, 356
application of exogenous spermidine to wildtype BY4741 would cause Agp2p to signal that there was 357
adequate polyamine availability and decrease expression of the membrane binding partners. Sam3p 358
and Dur3p are the plasma membrane proteins responsible for polyamine uptake in S. cerevisiae [29] 359
and are known to be regulated by Agp2p [28] and polyamine concentration [29]. As a link between 360
polyamines and the activity of cationic AFPs had been established we examined whether the 361
resistant phenotype was observed in sam3Δ and dur3Δ mutants as these proteins are potential 362
membrane binding partners. Single sam3Δ and dur3Δ exhibited the same sensitivity to NaD1 as wild 363
type and double mutants sam3Δ/agp2Δ and dur3Δ/agp2Δ had the same level of resistance as the 364
agp2Δ single mutant. As Sam3p and Dur3p have a redundant function in polyamine transport we 365
also looked at the sam3Δ/dur3Δ double mutant and found the same NaD1 sensitivity as observed for 366
the wild type BY4741. This extended to the other cationic AFPs we tested. Sam3p and Dur3p were 367
eliminated as potential membrane binding targets of NaD1 and other cationic AFPs. However, it is 368
possible that one or more of the other membrane proteins with levels regulated by Agp2p on the 369
fungal cell surface could have functions in binding to cationic AFPs. 370
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An agp2Δ strain has been previously reported to have decreased levels of spermidine uptake [27] 371
resulting from decreased expression of polyamine transporters [28]. Thus we propose a third, 372
alternate model whereby spermidine competes with cationic AFPs for negatively charged binding 373
sites on the cell surface. In the case of the agp2Δ mutant, lack of spermidine transport could lead to 374
an accumulation of spermidine on the cell surface, effectively increasing the localized concentration 375
and occupying the binding sites as would occur with the application of exogenous spermidine. 376
Polyamines have long been known to associate with negatively charged moieties in membranes and 377
shield surface charges and in some cases provide stability to the membrane [41]. This shielding of 378
binding sites by spermidine fits with the observation that agp2Δ is resistant to cationic AFPs which 379
bind to negatively charged sites on the cell surface but not hydrogen peroxide which does not need 380
to bind to charged surfaces to exert its cell killing activity. The observation that most of the other 381
AFPs tested are still active at higher concentrations suggests that there is competitive binding for the 382
cell surface sites and higher AFP concentrations out compete spermidine for these binding sites. 383
This model is also supported by the decreased binding of cytochrome c to agp2Δ. The observation 384
that decreased binding extends beyond AFPs to other cationic peptides indicates that the 385
mechanism of resistance does not relate to a characteristic specific to AFPs but is due to an increase 386
in positive charge on the cell surface that repels cationic proteins. Further investigation into the 387
mechanism by which Agp2p and polyamines influence the activities of cationic AFPs is required to 388
fully understand the biological phenomena involved. Perhaps fungal cells have evolved to maintain 389
a prophylactic shield made up of polyamines and other positively charged molecules to protect 390
against the effects of cationic antifungal peptides and lack of expression of genes controlled by 391
Agp2p leads to increased thickness and/or stability of this layer. 392
Current methods for control of fungal pathogens have encountered hurdles associated with 393
emerging resistance in fungi as well as undesirable off target toxicity. Identification of novel agents 394
for the control of pathogenic fungi is necessary to minimize the potentially catastrophic effect these 395
microorganisms could have on the world. One particularly attractive class of molecules for the 396
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control of fungal pathogens is the plant defensins. The results from this study are encouraging for 397
the development of antifungal proteins such as NaD1 as molecules for combatting fungal pathogens 398
in agriculture and the clinic. Although we did identify a set of resistant strains, the level of resistance 399
was not insurmountable as full inhibition of all strains analysed was achieved by increasing the 400
concentration of protein less than 3 fold. In addition, polyamine uptake and metabolism is essential 401
for the viability of yeast and other fungi. Strains in nature that may develop mutations that mimic 402
those investigated here would be considerably less fit, as evidenced by the decreased competitive 403
fitness observed in an agp2Δ strain [42]. The likelihood of mutations causing resistance via the 404
mechanisms discussed here arising in a natural population is low. 405
Using the model yeast S. cerevisiae a link between polyamine uptake and the antifungal mechanism 406
of the plant defensin NaD1 and other cationic antifungal peptides has been established. We 407
anticipate that this also operates in other fungal pathogens and further investigation is required to 408
confirm this prediction. Elucidation of the interplay between polyamines and antifungal peptides 409
will provide information that will be crucial for the design of novel antifungal molecules. 410
411
Acknowledgements 412
This work was supported by a Discovery Project from the Australian Research Council (ARC, 413
DP120102694) to MAA and NLV and a La Trobe University Early Career Research Grant to MRB. 414
415
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547
548
Percent growth inhibition Genes deleted <20 PAC10, SLS1, LPX1, ORM2, EMC6, PET494, TVP18, PTK2, YDL034W,
TRP2, YNL109W, VMA11, SPO7, MSN5, YSA1, SKY1, TUF1, KEX1, YJL120W, UPF3, MTH1, YOR200W, FUN19, AAT2 , YGP1, UBP14, TCO89, YOR379C, SUR2, YBL028C, OPI9, YGL214W, IRC21
20-40 CCS1, SEM1, FAR7, AGP2, PTC3, RPL26B, YGR269W, LDB19, RAS1, NCL1, RXT2, URE2, BRP1, RIB4, YFR012W, CBP1, RSM27, SAP185, YDL062W, FMP48, YPL182C, CTI6, YGR069W, YVC1, ARP8, YHR039C-B, DOA1, HSV2, YGL149W, MAP1, EMI2, RTK1, MRPL6, YDR290W, NAP1, CPR7, GZF3, CUE3, NAM7
40-60 YJL027C, TDH3, HIS7, YOR199W, MTC7, RGD2, UBC4, YDL063C, MRPS35
Table 1. Genes deleted in strains that were found to be resistant when screened in triplicate against 549 4µM NaD1. Only strains where all three replicates had less than 60% growth inhibition were 550 included in the resistant set. 551
552
Figure legends 553
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Figure 1. Screening of the non-essential S. cerevisiae deletion collection for resistance to 4µM 554 NaD1. A. Distribution of percent growth inhibition phenotypes across the collection. Extreme 555 outliers were removed from this graph. B. Growth phenotypes of the 81 strains initially identified as 556 sensitive when re-screened in triplicate against 4µM NaD1. No growth was observed for wild type 557 (BY4741) at this concentration. Strains with growth inhibition less than 60% were considered 558 resistant. Error bars are standard deviation for each set of triplicates. 559
Figure 2. . NaD1 resistance in strains lacking components of the high affinity spermidine pathway. 560 A. Growth of deletion strains across a range of NaD1 concentrations. Less growth inhibition occurred 561 in strains lacking a component of the polyamine uptake system, sky1Δ (dotted black), brp1Δ (dotted 562 grey), ptk2Δ (dashed black) and agp2Δ (solid grey), than wild type (solid black). B. NaD1 (20µM) 563 induced membrane permeabilization of agp2Δ(solid grey) was dramatically decreased compared to 564 wildtype (solid black), membrane permeabilization kinetics of sky1Δ (dotted black), brp1Δ (dotted 565 grey) and ptk2Δ (dashed black) are intermediate compared to agp2Δ and wildtype. Error bars are 566 standard deviation of three biological replicates. The trend was consistent over a minimum of three 567 independent experiments. 568
Figure 3. Exogenous spermidine protects against membrane permeabilization by NaD1 in S. 569 cerevisiae. A. Treatment with increasing concentrations of spermidine, the preferential substrate for 570 Agp2p, decreases membrane permeabilization by 20µM NaD1 in a concentration dependent 571 manner; spermidine concentrations 100µM (solid grey), 25µM (dotted grey), 12.5µM (dotted black), 572 0µM (solid black). B. Treatment with putrescine, does not provide the same level of protection 573 against membrane permeabilization by NaD1; putrescine concentrations 100µM (solid grey), 25µM 574 (dotted grey), 12.5µM (dotted black), 0µM (solid black). C. Permeabilization of the F. oxysporum 575 plasma membrane by 20µM NaD1 in the presence of 100µM spermidine (solid grey), 12.5 µM 576 spermidine (dotted grey), 100µM putresceine (dashed black), 12.5µM putrescine (dotted black) and 577 no added polyamine (solid black). As with S. cerevisiae, permeabilization of the F. oxysporum 578 membrane by NaD1 was inhibited better by spermidine than putrescine. Data is representative and 579 consistent over a minimum of three independent replicates. 580
Figure 4. Spermidine protects S. cerevisiae against the antifungal activity of NaD1. BY4741 cells 581 were treated with 20µM NaD1 in the presence of 2 fold serial dilutions of spermidine from a top 582 concentration of 100µM. Spermidine protected BY4741 cells against the activity of NaD1 in a 583 concentration dependent manner. The activity of NaD1 on BY4741 in the presence of 100µM 584 spermidine is similar to the activity on agp2Δ. 585
Figure 5. Cells lacking the polyamine transporter Agp2p have reduced uptake of NaD1 compared 586 to wildtype. A. Time course confocal microscopy of 40µM BODIPY-NaD1 on the wildtype and agp2Δ. 587 Images are overlays of the green and DIC channel. Time points in seconds are in the top left of each 588 panel. Scale bar is 20µm. Uptake of labelled defensin was retarded in agp2Δ compared to wildtype 589 at each time point up to 36 min (2160s). B. Representative FACS histogram of BODIPY-NaD1 uptake 590 after 30min BODIPY-NaD1 concentrations are 0µM (grey), 5µM (red), 10µM (green), 20µM (blue). 591 Less defensin was taken up by agp2Δ compared to wildtype at all concentrations. C. Relative uptake 592 of BODIPY-NaD1 in wildtype and agp2Δ cells from FACS histograms; BY4741 (grey), agp2Δ (black). 593 Labelled defensin uptake was concentration dependent. Data is averaged across three independent 594 replicates and the difference between BY4741 and agp2Δ has a p-value<0.05 at all concentrations. 595 D. Anti-NaD1 Western blot of pull down experiments comparing binding of NaD1 to BY4741 in the 596 presence of 100µM spermidine(SPD), 100µM putrescine (PUT) and with no added polyamine. E. . 597 Anti-NaD1 Western blot of pull down experiments comparing binding of NaD1 to agp2Δ and 598 sam3Δ/dur3Δ to the wildtype BY4741. F. Densitometry of bands from western blot pull down. Less 599 NaD1 was pulled down by agp2Δ and the spermidine treated cells than wildtype, the double 600 mutants or the putrescine treated cells. Data is averaged across three independent experiments. 601
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Figure 6. Phenotypes of polyamine transporter double mutants. Growth inhibition of single and 602 double mutants across a range of NaD1 concentrations. Single mutants dur3Δ (square) and sam3Δ 603 (triangle) have similar growth phenotypes to wild type BY4741 (diamond). Double mutants 604 dur3Δ/agp2Δ (asterisk) and sam3Δ/agp2Δ (circle) have similar growth phenotypes to agp2Δ (X). This 605 indicates that Dur3 and Sam3 do not play a role in the antifungal activity of NaD1. Error bars are 606 standard deviation of three biological replicates. The trend was consistent over a minimum of three 607 independent experiments. 608
Figure 7. Resistance of agp2Δto other cationic antifungal proteins. Growth inhibition of wildtype 609 BY4741 (black) and agp2Δ (grey) when incubated with increasing concentrations of H2O2 (A), NaD1 610 (B), Bac2a (C), BMAP28 (D), CP29 (E) and HBD2 (F). Resistance in agp2Δ is observed for all cationic 611 peptides but not for H2O2. 612
Figure 8. Susceptibility of sam3Δ/dur3Δ to cationic antifungal peptides. Growth inhibition of 613 wildtype BY4741 (black) and sam3Δ/dur3Δ (grey) when incubated with increasing concentrations of 614 H2O2 (A), NaD1 (B), BMAP28 (C) and CP29 (D). The double mutant is slightly sensitive to NaD1, 615 CP29and H2O2 and there is no difference in susceptibility to BMAP28. 616
Figure 9. Cytochrome c binding to BY4741 and agp2Δ. Cytochrome c is a cationic protein with an 617 absorption maximum at 530 nm. Cells were incubated with 0.5mg/mL cytochrome c for 20min and 618 pelleted. Levels of cytochrome c remaining in the supernatant were estimated 619 spectrophotometrically at 530nm. The supernatant from BY4741 cells contained less cytochrome c 620 than the supernatant from agp2Δ cells which were not found to bind much more cytochrome c than 621 the buffer control with no cells. 622
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