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PTEN 2 , a golgi-associated testis-specific homologue of the PTEN tumor
suppressor lipid phosphatase
By
Yan Wu*, Donald Dowbenko*, Mayte Pisabarro+, Lisa Dillard-Telm#,
Hartmut Koeppen# and Laurence A. Lasky*%
Depts of Molecular Oncology* Protein Engineering+ and Pathology#Genentech, Inc.
460 Pt. San Bruno Blvd.SSF, CA 94080
% address correspondence to L.Lasky: 1-650-225-1123 (phone), 1-650-225-6127(FAX), lal@gene.com (email)
Copyright 2001 by The American Society for Biochemistry and Molecular Biology, Inc.
JBC Papers in Press. Published on March 2, 2001 as Manuscript M101480200 by guest on January 20, 2020
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The tumor suppressor PTEN is a phospatidylinositol phospholipid
phosphatase which indirectly downregulates the activity of the AKT/PKB
survival kinases. Examination of sequence databases revealed the
existence of a highly conserved homologue of PTEN. This homologue,
termed PTEN 2, contained an extended amino terminal domain having 4
potential transmembrane motifs, a lipid phosphatase domain and a
potential lipid-binding C2 domain. Transcript analysis demonstrated
that PTEN 2 is expressed only in testis and specifically in secondary
spermatocytes. In contrast to PTEN, PTEN 2 was localized to the golgi
apparatus via the amino terminal membrane spanning regions. Molecular
modeling suggested that PTEN 2 is a phospholipid phosphatase with
potential specificity for the phosphate at the 3 position of inositol
phosphates. Enzymatic analysis of PTEN 2 revealed substrate specificity
that is similar to PTEN, with a preference for the dephosphorylation of
the phosphatidyl inositol 3,5 phosphate phospholipid, a known mediator
of vesicular trafficking. Together, these data suggest that PTEN 2 is a
golgi-localized, testis-specific phospholipid phosphatase, which may
contribute to the terminal stages of spermatocyte differentiation.
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The production of 3-phosphorylated phosphatidylinositol lipid products by the
PI3 kinase pathway is an important control point for the regulation of cell proliferation,
growth, survival and vesicular trafficking [1]. The activation of this pathway by
various growth factors, extracellular matrices or oncogenic events results in a
diversity of signals including the upregulation of the catalytic activity of the AKT/PKB
kinases [2]. These kinases enhance cell survival by phosphorylation of a number of
substrates including a subfamily of forkhead transcription factors [3]. A novel
mechanism for the control of the AKT/PKB pathway was identified when genetic evidence
pointed to a tumor suppressor locus on chromosome 10 at q23-25. Analysis of a
candidate tumor suppressor gene from this region demonstrated that the locus encoded a
phosphatase, which was termed PTEN (also called MMAC and TEP 1) [4] [5] [6].
Further studies demonstrated that PTEN was mutated in a large percentage of brain,
endometrial and prostate tumors as well as a smaller percentage of other tumors [7] [8]
[9]. In addition, Cowden disease and Bannayan-Zonana Syndrome, which are both
characterized by increased susceptibility to breast and thyroid tumors, showed a range
of germline PTEN mutations, which were similar to those observed in tumors [10].
Enzymatic studies demonstrated that PTEN is a lipid phosphatase which downregulates
the PI3 kinase pathway by removing the 3-phosphate from the phosphatidylinositol-3,
4 and -3,4,5 phosphate phospholipids (PIP 3,4 and PIP 3,4,5) [11]. Importantly,
many of the tumor-derived missense mutations observed in PTEN resulted in a complete
loss of phospholipid phosphatase catalytic activity [12]. The loss of the PTEN lipid
phosphates activity due to mutation was expected to result in increased levels of PIP 3,4
and PIP 3,4,5 and the upregulation of the AKT/PKB cell proliferation/survival
pathway, an event which might induce tumor resistance to chemotherapy and radiation
[13] [14] [15]. Data supporting this conjecture demonstrated that glioblastoma cell
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lines mutated for the endogenous PTEN locus suffered deleterious effects on cell cycle
progression (G1 arrest), proliferative capacity and survival when transfected with a
wild type, but not a catalytically-inactive, form of the phosphatase, suggesting that the
enzymatic activity of the enzyme was involved with the regulation of this phospholipid
signaling [6] [16] [17]. These studies suggested that the loss of this phosphatase in
tumors induced the upregulation of the AKT/PKB signaling pathway, which resulted in
cell cycle progression and inhibition of apoptosis.
A number of animal model studies supported an important role for PTEN in the
control of proliferation, survival and cell size. Importantly, mice with homozygous null
mutations in the PTEN locus showed early embryonic lethality due to an apparent
hyperproliferative effect, while heterozygous animals developed tumors postnatally
with apparent loss of heterozygosity at the PTEN locus [18] [19]. This latter result
suggested that the loss of PTEN expression was an advantageous event, which allowed
tumors to grow in a more unregulated manner after the accumulation of other oncogenic
mutations. Cell lines derived from PTEN null embryonic mice demonstrated higher
levels of PIP 3 phospholipids and enhanced activation of the AKT/PKB kinase [19]. These
cells also showed significant resistance to a diversity of apoptotic stimuli, further
endorsing a role for this phosphatase in the regulation of cell survival through the PI3
kinase pathway. Additional evidence in both C. elegans and Drosophila supported a role
for the PTEN phosphatase in the regulation of cell growth and survival. C. elegans
contains an insulin-like pathway , including an insulin –like receptor tyrosine kinase,
a PI 3 kinase, PDK and AKT/PKB kinases and a forkhead-like transcription factor,
which is involved with dauer formation, a developmental stage where worms undergo a
quiescent state. Genetic analysis of this pathway demonstrated that a worm homologue of
PTEN, termed DAF 18, could suppress upstream mutations in either the insulin-like
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receptor or PI 3 kinase, completely consistent with results found in the mammalian PI
3 kinase pathway [20]. The involvement of this pathway in the regulation cell size was
further suggested by studies in Drosophila. These data demonstrated that the fly
homologue of PTEN was involved with the determination of cell size, consistent with
other studies, which established the importance of several components of the PI 3-
kinase pathway, such as AKT/PKB [21] [22]. Together, these three separate animal
models provided strong proof for the relevance of the PTEN lipid phosphatase in the
regulation of various aspects of the PI 3 kinase pathway.
X ray crystallographic analysis of PTEN structure revealed that this phosphatase
contains a novel substrate recognition pocket with positively charged residues
potentially involved with the association of the phosphates on the inositol ring substrate
[12]. Positioning of many tumor derived mutations known to disrupt catalytic activity
to the active site in part served to explain the mechanism of action of the phosphatase.
The mechanism by which PTEN appears to be associated with its phospholipid substrates
appears to be quite complex. Structural analysis revealed a functional C2 lipid binding
domain in the carboxy-terminal region of the protein, which was proposed to serve as a
lipid association motif [12]. Many tumor-derived mutations have been mapped to the
carboxy-terminus, and a fraction of these are involved with the formation of an
interface between the phosphatase domain and the C2 domain. These latter results helped
to explain why mutations in the carboxy-terminal region appeared to affect catalytic
activity. Human, mouse and Drosophila PTEN all contain a PDZ binding motif (S/TXV) at
their carboxy termini, and yeast two hybrid analyses established that the PTEN
phosphatase binds to PDZ domains of a family of membrane associated guanylate kinases
(MAGUKs), peripheral membrane associated proteins with multiple protein interaction
domains which function to juxtapose signaling molecules and position them near the
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plasma membrane [23]. Interestingly, some tumor derived mutations are found at the
extreme carboxy terminus of PTEN, and these mutations would be expected to disrupt
PDZ domain binding interactions, consistent with an important functional role for PDZ
domain binding in PTEN tumor suppression. Because these MAGUKs are localized
specifically to intercellular tight junction regions, these studies also suggested
mechanisms for the positioning of the PTEN phosphatase to the lipid domains of
subcellular regions such as the epithelial tight junction, a site known to be involved
with the regulation of cell survival [24].
In this paper we describe a novel homologue of PTEN, termed PTEN 2, which has
been identified using database searches. Interestingly, this novel phosphatase is
expressed uniquely in testis, and specifically in the secondary spermatocytes. In
contrast to PTEN, PTEN 2 contains several potential transmembrane domains, which
appear to target the phosphatase to the golgi apparatus. Molecular modeling suggests that
PTEN 2 is a lipid phosphatase with many active site residues conserved with PTEN, and
enzymatic analysis demonstrates that the novel phosphatase actively dephosphorylates
PIP 3,5 and PIP 3,4,5 in vitro. Together, these data suggest that PTEN 2 is a
phospholipid phosphatase which may play a role in the terminal stages of spermatocyte
maturation by regulating intracellular levels of phosphatidylinositol-3-phosphate
phospholipids.
Materials and Methods
PTEN DNA constructs. An human EST related to PTEN was initially identified from
searches of public and private databases. By using various protocols, including
screening a testis cDNA library and PCR methods, we obtained a full-length sequence of
human PTEN 2. A fragment of human PTEN 2 cDNA was used as a probe to isolate a full
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length murine cDNA from a murine testis cDNA library GST-PTEN 2 (amino acids 378-
683 was subcloned into an expression vector containing a CMV promoter. . A
catalytically inactive form of murine GST-PTEN 2 was constructed by changing Cys458 to
Ser. To determine the localization of PTEN 2 in mammalian cells, a myc tag was placed at
the C terminus of the gene. GFP-PTEN 2 was constructed by subcloning either the full
length cDNA or the N- or C-terminus into Clontech’s pEGFPN3 vector. PTEN 2 N-
terminus includes amino acids 1-377, while PTEN 2 C-terminus includes amino acids
378 to 683. FISH mapping of mouse murine PTEN 2 was performed by SeeDNA Biotech
Inc. The probe was an 8kb BamHI genomic DNA containing the first exon of PTEN 2.
Molecular Modeling For the molecular modeling, a sequence alignment was obtained
by using CLUSTAL W and a threading approach. The HOMOLOGY/MODELLER module from
the Insight II package (version 98.0; MSI, San Diego, California) was used for molecular
construction and display. Docking of inositol (1,3,4,5)-tetrakisphosphate in the active
site of PTEN2 was manually performed as previously described for PTEN by Lee and
coworkers [12].
PTEN 2 expression pattern. In addition to Northern analysis, we also determined
the tissue distribution pattern of PTEN 2 using the PCR method. Mouse Multiple Tissue
cDNA panels were purchased from Clontech. After 35 cycles, the mouse PTEN 2 gene was
only detected in testis.
In situ hybridization. PCR primers (upper 5’ GAACTGGAACCATGGTG and lower 5’
TAGGAAGATTCGGAGAGAG) were designed to amplify a 423 bp fragment of pTEN2.
Primers included extensions encoding T7 and T3 RNA polymerase initiation sites to allow
in vitro transcription of sense and antisense probes, respectively, from the amplified
products. The hybridization was performed on 5µ paraffin sections of formalin-fixed
tissues. Prior to hybridization the sections were deparaffinized and treated with
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proteinase K for 15 minutes at 370C. 33P-UTP labeled sense and antisense probes were
hybridized to the sections at 550C overnight. Unbound probe was removed by treatment
with RNase A for 30 min at 37oC, followed by a high stringency wash (0.1 X SSC for 2
hours at 550C) and dehydrated in 70%, 95% and 100% ethanol, respectively. The
slides were dipped in NBT2 nuclear track emulsion (Eastman Kodak), exposed for 4
weeks at 40C, developed and counterstained with hematoxylin and eosin.
Intracellular localization of PTEN 2. The intracellular localization of PTEN 2
gene was done in COS7 cells. 36 hours after transfection, the cells were fixed using
formaldehyde and stained using an anti-myc monoclonal antibody. The YFP-Golgi marker
was purchased from Clontech. Brefeldin was purchased from Sigma and the transfected
cells were treated for 40 minutes before fixation.
Preparation of catalytically active PTEN proteins. Approximately 5 x 108
293 cells are collected and resuspended in 100 ml of 0.5% Triton X-100, 50 mM Tris
pH 7.5, 150 mM NaCl, 10 % glycerol, 2 mM DTT, and protease inhibitors ( Roche,
#1836145). After sitting on ice for 15 minutes, the lysates are centrifuged at 10,000
x g and the supernatant is collected. The lysate is applied to a 2 ml GSH-sepharose
column and recirculated several times. The column is washed in 10 column volumes of
0.03% Brij35 , 50 mM Tris pH 7.5, 0.5M NaCl, 10% glycerol, and 2mM DTT. The
GST-fusion protein is eluted with 50 mM Tris pH7.5, 150 mM NaCl, 2 mM DTT, 30%
glycerol, and 10 mM reduced glutathione. The protein is stored in aliquots of 30 ul at
–20oC. Full length human PTEN cDNA was cloned into the baculovirus expression vector,
PH.hif, as a C-terminal HIS-tag fusion. The PCR primers used for this were: 5’-
CATCGCGATCGCATGACAGCCATCATCAAAGAG3 ’and
5’CTACGCGGCCGCTCAGACTTTTGTAATTTGTGTATGC-3’.Insect “Hi-Five” cells (Expression
Systems) at 7.5 x 105 /ml were infected with a multiplicity of 1.0 for 48 hours and
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then harvested. Pelleted cells were resuspended in 100 ml of 50mM Tris pH 7.5,
300mM NaCl, 250mM sucrose, 1mM DTT, and 5 mM Imidazole. The suspension was
sonicated for 1 minute on ice and centrifuged at 10,000 x g for 15 minutes. The
supernatant was collected and recirculated over a 2 ml column of Ni-NTA superflow
(Qiagen #1004493). The column was washed with 10 column volumes of lysis buffer
and eluted with 5 x 1ml steps of 50 mM Tris pH 7.5, 250 mM sucrose, 150 mM NaCl,
2 mM DTT and 250 mM Imidazole. Enzyme was stored at –70oC in 20 ul aliquots.
Phosphoinositide phosphatase assay. The lipid-based phosphatase reactions were
performed essentially as described [25]. The reactions (50 µl) contained 100 mM
Tris(pH8.0),10 mM dithiothreitol, 100 uM phosphatidyl inositol phosphate substrates,
(Echelon), 1.0 mM phosphatidylserine (Avanti, #830052) and 50 ug/ml PTEN2 or 10
ug/ml PTEN. Reactions were run at 37oC for 3 hours and centrifuged at 20,000g for 15
min. The supernatants were treated with malachite green (Biomol Green, # AK-111)
and absorbance was measured at A650.
Results
Sequence characterization of a PTEN homologue. Perusal of human and murine
DNA sequence databases demonstrated a closely related homologue of PTEN in both
species. Cloning of cDNAs encoding both the human and murine forms of the homologue
revealed that, while a diversity of sequences were expressed in the human, a single
species was found in the mouse. While this work was being completed, a human
homologue of the murine sequence was reported, and chromosomal mapping suggested
that there were a number of different PTEN-homologous genes encoded in the human
genome, some of which appeared to be psuedogenes [26]. The sequence of the 664 amino
acid (m.w. 76, 719 daltons) mouse protein is illustrated in figure 1 and compared with
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the reported human PTEN 2 homologue and with PTEN. This figure illustrates that both
the human and murine PTEN homologues are extended at their amino-termini, and
hydropathy analysis (figure 1) reveals that, in contrast to PTEN, the murine and human
homologues appear to contain four high-probability transmembrane domains followed
by the catalytic domain. Interestingly, all four potential transmembrane domains contain
charged residues embedded within the hydrophobic potential membrane-spanning
sequence (figure 1). Using a structural algorithm , which predicts membrane topology
(Dr. Thomas Wu-personnal communication), we find that the murine homologue of PTEN
may have a membrane spanning structure, which is reminiscent of ion channels (figure
1). This sequence analysis suggests that the murine and human PTEN homologues appear
to have extended amino termini, which may be involved with intracellular membrane
association. FISH mapping revealed that the murine homologue mapped to a single locus
on chromosome 8 between A3 and A4 (data not shown).
The murine homologue appears to have a number of residues throughout the
catalytic domain, which are conserved with PTEN (figure 1). Importantly, many of
these residues are likely to be involved with substrate recognition and catalytic activity
(figure 2) [12]. For example, residues D426, H427, C458, K459, G461, R462 and Q510, which
are identical between the two proteins, were all proposed to be involved with substrate
recognition in the structural analysis of PTEN. In addition, figure 2 also illustrates that
the vast majority of the tumor-associated PTEN mutations, many of which are known to
disrupt catalytic activity, occur at residues that are also either identical or conserved
between the PTEN and the PTEN homologue. These comparative data suggest that the
murine and human homologues are likely to have similar substrate specificity as PTEN,
and we have therefore termed the new protein PTEN 2.
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The structure of PTEN has been recently solved by X-ray crystallography at 2.1
angstroms resolution [12]. This analysis revealed a molecule consisting of an N-
terminal phosphatase domain and a C-terminal C2 lipid binding motif which were tightly
packing against each other through a large interface. The phosphatase active site is
similar to that observed in protein tyrosine phosphatases, including the essential
catalytic residues, but is enlarged to allow for the binding of the larger phosphoinositide
substrate. C2 domains have been shown to mediate membrane lipid association. Based on
the 39% sequence identity between PTEN2 and PTEN, a three dimensional model of the
phosphatase and C2 domains of PTEN2 has been built by homology modeling and threading
techniques using the PTEN structure as template (figure 2). The existence of a C2
domain in PTEN2 (PTEN2-C2) was established by using threading analysis and the high
conservation of residues forming the phosphatase domain/C2 interface (figure 2). This
domain presents a 23% sequence identity with the PTEN C2 domain (PTEN-C2). In
PTEN2 there is a five residue insertion in the "T1 loop" that could allow this loop to
establish more extensive contacts with the C2 domain as compared to PTEN (figure
2).The catalytic residues essential for the activity in all protein tyrosine phosphatases
are conserved in PTEN2 (D426, C458 and R464) and occupy the same position in both, PTEN
and PTEN2 (figure 2). The high conservation of residues forming the substrate binding
site in PTEN and PTEN2 has structural implications for substrate-recognition. In
particular, the positively charged residues that have been proposed to interact with the
negatively charged phosphate groups of the phospholipid substrate in PTEN are
conserved in PTEN2 (H427, K459 and K462). Manual docking of inositol (1,3,4,5)-
tetrakisphosphate (Ins(1,3,4,5)P4) in the active site of PTEN2 was performed as
described by Lee and collaborators [12], and indicated that this phospholipid might
bind to PTEN2 in the same binding mode as that proposed for PTEN (figure 3). Like the
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PTEN-C2, PTEN2-C2 lacks the residues present in other Ca2+-dependent C2 containing
proteins that coordinate Ca2+ and regulate membrane binding. A patch of five lysines or
"CBR3 loop" has been proposed by Lee and collaborators to mimic the Ca2+ charge in
PTEN . In PTEN2, none of the five lysine residues in the CBR3 loop of PTEN is conserved
(P 607, P610, Y613, D614, and C616). A second "positive patch" in helix c2 (K644, K646, K649)
is conserved in both PTEN and PTEN2. This region is similar to a helix in phosphilipase
A2 that has been shown to contribute to membrane binding. Together, these analyses
suggest that many of the functional characteristics of the PTEN structure are conserved
in PTEN 2.
PTEN 2 is expressed in a specific stage of sperm development. Northern blot
analysis (figure 3) of various murine tissues using a PTEN 2 probe revealed a discrete
~ 2.7 kb transcript which was specifically expressed in testis, in agreement with
results for the human PTEN 2 sequence [26]. The specificity of testis expression is
underlined by the observation that PCR analysis of multiple murine tissues revealed a
signal only in testis RNA, even after a large number of PCR cycles (figure 3). Because
testis contains a diversity of cell types, some of which (spermatocytes) pass through a
number of developmental stages [27], we decided to analyze this tissue using in situ
hybridization. Isotopic in-situ hybridization (ISH) was performed on adult testis, as
well as on testes representing various stages of adolescence. In the adult testis a positive
signal was observed in germ cells within seminiferous tubules, while cells in the
interstitium of the testis were negative. The positive signal within the seminiferous
tubules showed an uneven distribution with some tubules displaying a strong signal,
while others were completely negative (figure 4). A positive ISH signal appeared to
correlate with the presence of a specific cell population. The positively reacting cells
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reside in the adluminal portion of the tubule, are of small to medium size, have a round
nucleus with evenly distributed, finely granular chromatin and a distinct nucleolus.
Based on morphological criteria, these cells are most consistent with secondary
spermatocytes and/or very early spermatids. The abundance of the positive signal,
together with the short half-life of secondary spermatocytes, makes it likely that both
cell types express PTEN 2. Sertoli cells, spermatogonia, primary spermatocytes or
mature spermatids did not express PTEN 2 RNA. Expression in these cell types was
ruled out on the basis of their location within the seminiferous tubules, size and shape
of cell body and nucleus and chromatin pattern. Expression of PTEN 2 during testicular
maturation is not detected until day 19 of postnatal development (figure 4). In a time
course experiment we were unable to demonstrate PTEN 2 RNA in testes removed on days
3, 7, 10 and 16. The expression of PTEN 2 RNA therefore slightly precedes sexual
maturity in the male mouse, consistent with an association of PTEN 2 with late events of
spermatogenesis.
PTEN 2 is associated with the golgi apparatus. Examination of the PTEN 2
sequence suggested that 4 potential transmembrane domains are found in the protein,
consistent with the possibility that PTEN 2 is a membrane associated molecule which
passes through the secretory pathway. In order to examine the subcellular localization of
PTEN 2, a plasmid encoding a form of the protein with a carboxy-terminal MYC epitope
tag was transfected together with a plasmid encoding a yellow fluorescent protein-
trans/medial golgi marker (encoding the first 81 amino acids of ß1,4
galactosyltransferase) into COS cells, and confocal microscopy was performed. Figure
5 shows that examination of permeabilized cells revealed that PTEN 2 clearly
colocalized with the golgi-associated marker in perinuclear, vesicular structures,
consistent with the suggestion that PTEN 2 was found in the secretory pathway of the
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cell. This localization was further emphasized by examining transfected cells treated
with the golgi disrupting agent, brefeldin. The vesicular, perinuclear localization of both
PTEN 2 as well as the YFP golgi marker was disrupted in these cells (figure 5),
consistent with the localization of both of these proteins to the golgi apparatus.
In order to determine if the amino-terminal transmembrane-containing region
was involved with golgi localization, truncated forms of the protein encoding either the
N-terminal transmembrane motifs or the C-terminal phosphatase and C2 domains were
also expressed in COS cells. Figure 5 reveals that the C-terminal fragment of the protein
appeared as a diffusely stained signal throughout the cytoplasm and in the nucleus, while
the amino terminal fragment containing the transmembrane motifs was found to
colocalize with the perinuclear golgi apparatus in a manner that was similar to the full
length protein, consistent with the suggestion that the subcellular localization of the
protein is mediated by these hydrophobic domains. These results suggest that, in
contrast to PTEN which appears to be cytoplasmically localized in transfected cells,
PTEN 2 appears to be localized to the golgi apparatus via an interaction that is likely to
be mediated by one or more of the amino-terminal transmembrane motifs.
Enzymatic activity of PTEN 2. Homology modeling (figure 2) strongly suggested
that PTEN 2 might be a lipid phosphatase with specificity for the 3-phosphorylated
phosphatidylinositols that are products of a PI3 kinase reaction. In order to examine the
lipid phosphatase activity of PTEN 2, a truncated form of the protein including the
catalytic region and the potential C2 domain was produced in and isolated from
transfected mammalian cells. As a control, a truncated form of PTEN 2 with a mutation
at the critical active site cysteine (Cys458Ala) was also produced. Full length wild type
PTEN and active site mutated (Cys124Ala) were also produced as positive controls using
the baculovirus system. Each of these isolated proteins was tested for dephosphorylation
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of a variety of phosphatidyl inositol substrates in an in vitro malachite green enzyme
assay. Figure 6 illustrates that the wild type version of PTEN was able to release
phosphate from a diversity of substrates, including those containing phosphate at the 3
position. This activity was completely abolished in the Cys124Ala active site mutant (data
not shown). While this apparent lack of substrate specificity is at odds with the accepted
activity of PTEN towards only the 3 phosphate position, it should be remembered that
this assay is performed under artificial conditions in vitro. Importantly, the activity of
the PTEN 2 phosphatase domain appeared to be directed towards substrates containing
phosphates at both the 3 and 5 positions. Thus, while the enzyme showed strong activity
against PIP 3,5 and PIP 3,4,5 substrates, there was lower activity against PIP 3 and
PIP 3,4. Because molecular modeling predicts that this enzyme is a 3 phosphatase,
together with the complete lack of homology between PTEN 2 and phosphatases with
specificity for the 5 position of phosphatidyl inositols, we propose that PTEN 2 removes
the 3 phosphate from the PIP 3,5 and PIP 3,4,5 substrates. However, further analysis
of the structures of the dephosphorylated substrates will be required to delineate the
exact specificity of this enzyme. In summary, as predicted from molecular modeling,
PTEN 2 appears to be a lipid phosphatase with specificity for a subset of 3-
phosphorylated phosphatidylinositols.
Discussion
The regulation of phosphatidyl inositol levels is a critical component of a
diversity of cellular functions ranging from cell survival to membrane trafficking [1].
The levels of these various phospholipids are determined by a number of factors
including the activities of various lipid kinases and phosphatases. One lipid phosphatase,
termed PTEN, is especially interesting because of its association with a survival
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pathway in cells as well as its apparent tumor suppressor activity . Because PTEN is the
first phosphatase, which appears to dephosphorylate phospholipids at the 3 position, the
identification of other phosphatases with similar activity is of great interest. The data
described here report a novel relative of PTEN, termed PTEN 2, which has many of the
enzymatic characteristics of PTEN, but which shows significant differences with the
original enzyme, including a unique cell-type specificity and an association with the
golgi secretory compartment.
The three-dimensional structure of PTEN provided a number of insights into the
potential mechanisms by which this phosphatases recognizes and dephosphorylates its
3-phosphate-containing phospholipid substrates [12]. Because of the high degree of
sequence homology between PTEN and the novel PTEN 2 described here, we were able to
produce a model for the novel enzyme by homology modeling. This model predicted a
number of interesting aspects about the novel enzyme. First the model suggested that the
novel enzyme should have lipid phosphatase activity specific for the 3 position of the
phospholipid, and this prediction was confirmed in our enzymatic assays. In addition, the
model predicted that the novel phosphatase contains a C-terminal C2 domain which has
the potential for interacting with membrane lipids. Perhaps more interesting is the
conservation in the interface between the phosphatase and C2 domain in both PTEN and
PTEN 2. This conservation suggests that this region may have functional importance, and
analysis of tumor-derived mutations in this region of PTEN suggested that this interface
is important for the maintenance of enzyme activity [12]. Interestingly, enzymatic
analysis suggests that PTEN 2 has a greater degree of specificity for phospholipids
containing phosphate at both the 3 and 5 positions. It will be important to examine the
differences between the PTEN and PTEN 2 phosphatase domains to determine the
mechanism by which this specificity is attained. The current model of PTEN 2, together
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with the crystal structure of PTEN, should prove useful for structural predictions that
can be tested in enzymatic assays.
A major difference between PTEN and PTEN 2 is the extended N-terminus, which
contains 4 potential transmembrane domains. These domains appear to be involved with
the localization of PTEN 2 to the golgi apparatus, as demonstrated by colocalization with
a known golgi marker protein as well as mislocalization of both PTEN 2 and the marker
protein in the presence of the golgi disrupting agent brefeldin. PTEN was previously
suggested to localize to the cell surface restricted phospholipid substrate, and
particularly to the tight junctions of epithelial cells, through a PDZ domain mediated
interaction with a family of tight junction MAGUK proteins termed the MAGIs [23].
PTEN 2 appears to have solved the membrane localization dilemma by incorporating the
hydrophobic N-terminal region. However, this hydrophobic region appears to have more
complex functions than mere localization to the golgi apparatus. For example, the
multiple transmembrane domains in the N terminus of PTEN 2 are reminiscent of ion
channels, and homology analysis of this region of PTEN 2 suggests a distant relationship
with sodium channels (data not shown). The role that PTEN 2 plays in the regulation of
the golgi apparatus remains to be determined. However, a diversity of studies has
suggested that 3 phospholipids are involved with membrane trafficking and,
particularly, with the formation of multivesicular bodies [28] [29] [30] [31] [32]
[33]. For example, yeast mutants in phospholipid kinases, which produce either PIP 3
or PIP 3,5, are found to be defective in the formation of the multivesicular body [30]. It
should be noted that PTEN 2, which has specificity for the PIP 3,5 phospholipid, might
thus be involved with the regulation of this structure in mammalian cells. Further work
will be required to determine the exact role of PTEN 2 in membrane trafficking, but its
localization to the golgi, an important mediator of vesicular trafficking, together with
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its specificity for PIP 3,5, a known mediator of membrane trafficking, jointly suggest
that this enzyme may play a role in regulating some aspect of vesicular localization in
the cell.
Finally, the highly specific expression of the PTEN 2 phospholipid phosphatase in
a specific subset of developing sperm cells suggests that it might play an important role
in the terminal differentiation of sperm. The cell type which shows predominant
expression of PTEN 2 was the secondary spermatocyte, a stage of spermatogenesis that
occurs just before the large morphological changes which accompany the production of
mature sperm [27]. A potential role for PTEN 2 in terminal sperm differentiation is
also supported by our finding that the transcript for the enzyme appears simultaneously
with the development of mature sperm and sexual maturity (figure 4). Interestingly,
the golgi of the late spermatocyte undergoes a profound morphological change to become
the acrosome of the mature sperm. The possibility that PTEN 2 may be involved with
this morphological change is appealing for a number of reasons. First, of course, is the
temporal expression of the mRNA encoding this phosphatase at a time when this profound
morphological change occurs. Second is the subcellular localization of the phosphatase in
the golgi apparatus of transfected cells. Finally, and perhaps most interestingly, is the
notion that modulation of phospholipid levels in subcellular compartments might be
involved with aspects of vesicular trafficking, as mentioned above. Together, these
results suggest that the specific expression of PTEN 2 in the golgi of secondary
spermatocytes might be required for at least one of the important developmental changes
which sperm progenitors undergo as they differentiate to become mature sperm.
In summary, the results reported here suggest that a closely related homologue of
PTEN, termed PTEN 2, appears to be a golgi-associated lipid phosphatase, which is
expressed, in the terminal stages of sperm development. While the exact function of this
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phosphatase remains to be determined, the data suggest a potential role in membrane
trafficking regulated by the golgi apparatus. It will be of significant interest to produce
mice that are null mutants of this enzyme to determine its role in spermatogenesis, and
we are currently analyzing mice with mutations in this phosphatase. In addition,
further studies into the exact specificity of the phosphatase in vivo, as well as the effects
of the expression of this enzyme on vesicular trafficking, should provide insights into
its function. Finally, the mechanisms by which this phosphatase specifically degrades
3,5-containing phospholipids will require a further understanding of the structure-
function relationships of the catalytic site. Together, these data may highlight a novel
role for this phosphatase in a critical aspect of mammalian reproduction.
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Figure Legends
Figure 1. Sequence, hydropathy and domain model of PTEN 2. A. The
sequence comparison between murine and human [26] PTEN 2 and human PTEN. The
localization of putative transmembrane domains as predicted by a structural algorithm
(Dr. Thomas Wu-unpublished data) as well as the predicted phosphatase domain are
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overlined. B. Hydropathy analysis of the murine PTEN 2 sequence illustrated in A
reveals the localization of the 4 potential transmembrane domains. The localization of
the phosphatase domain is also illustrated. The human PTEN 2 sequence showed a similar
pattern (data not shown). C. A domain model of PTEN 2 illustrating the membrane
association mediated by the 4 potential N-terminal transmembrane domains and the
phosphatase domain.
Figure 2. Modeling of PTEN 2. A. Sequence alignment of PTEN and PTEN2 used for
the molecular modeling. Hydrophilic and charged residues are displayed in red, and
aromatic/hydrophobic residues are shown in black. The consensus is shown below the
alignment, with conserved hydrophilic/charged and aromatic/hydrophobic mutations
marked as red and black squares, respectively. Residues forming the active site of the
phosphatase and the phosphatase/C2 interface are boxed pink and green, respectively.
Cancer related mutations are highlighted with blue asterisks. Charged residues in the C2
loop involved in contacts with the lipid membrane are marked with red asterisks. B.
Ribbon diagram of the superimposition of the x-ray structure of PTEN (in blue), and
the modeled structure of PTEN 2 (in white). Alpha helices are shown as cylinders, and
beta strands as arrows (r.m.s.d C_ 0.33 Å). a. Zoom in of the active site showing binding
mode of a phosphatidyl inositol 4 phosphate molecule as well as tartrate, a substrate
mimic [12]. Key residues for substrate recognition are shown and labeled in blue for
PTEN and white for PTEN2. b. Zoom in of the PTP/C2 interface highlighting residue
conservation between PTEN and PTEN2.
Figure 3. Transcript distribution of PTEN 2. Northern blot (A) and PCR (B)
analysis of PTEN 2 transcript reveals that the message is only found in testis.
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Figure 4. In Situ hybridization analysis of PTEN 2 expression in the
testis. Brightfield (A) and darkfield (B) image (200x magnification) of adult testis
showing expression in three of four testicular tubules. (C) mPTEN 2 RNA expression
in subpopulation of germ cells (arrow; 400x magnification). These cells demonstrate
the morphologic features of secondary spermatocytes and early spermatids (see text).
(D- I ) Dark- and brightfield images of testes at day 10 (D&G), 16 (E&H) and 19
(F&I ) of postnatal life. Day 19, the time when sexual maturity is reached, is the
earliest timepoint with mPTEN 2 expression in testicular germ cells (200x
magnification).
Figure 5. Subcellular localization of PTEN 2. The top panel illustrates confocal
analysis of COS cells transfected with a PTEN 2 construct with a C-terminal myc tag
(red), a marker for the golgi consisting of the first 81 amino acids of ß1,4
galactosyltransferase and the yellow fluorescent protein (green) and the overlapping
image (yellow). Note the perinuclear, vesicular morphology of the costained subcellular
region, which is consistent with the golgi apparatus. The middle panel shows that cells
transfected as in the top panel show delocalization of the two markers when they are
treated with the golgi disrupting agent, brefelfdin. The bottom panels illustrate the
subcellular distribution of various forms of PTEN 2. Note that the full length and N-
terminal, potential transmembrane containing, forms associate with the perinuclear
golgi region, while the C-terminal form shows a diffuse staining over the whole cell,
including the nucleus.
Figure 6. Phospholipid phosphatase activity of PTEN 2. A. The enzymatic
activity of a GST fusion of PTEN 2 produced in mammalian 293 cells and containing the
phosphatase and C2 domains was assayed using the illustrated phospholipids as
substrates. Released phosphate was assayed using the malachite green reagent. B. The
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enzymatic activity of PTEN, including the phosphatase and C2 domains, produced in
baculovirus infected cells was assayed as described in A. In both cases, analysis of
mutants where the active site cysteine was converted to serine showed absolutely no
activity (data not shown).
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0.1
0.2
0.3
0.4
0.5PTEN2
PIP1-3P PIP1-4P PIP1-5P PIP2-3,4P PIP2-4,5P PIP2-3,5P PIP3-3,4,5P
0
0.1
0.2
0.3
0.4
0.5
0.6
PTEN
PIP1-3P PIP1-4P PIP1-5P PIP2-3,4P PIP2-4,5P PIP2-3,5P PIP3-3,4,5P
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Laurence A. LaskyYan Wu, Donald Dowbenko, Mayte Pisabarro, Lisa Dillard-Telm, Hartmut Koeppen and
lipid phosphatasePTEN 2 , a golgi-associated testis-specific homologue of the PTEN tumor suppressor
published online March 2, 2001J. Biol. Chem.
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