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Molecular and Cellular Biology, April 2000, p. 2865-2873, Vol. 20, No. 8
Departments of
Microbiology,1
Pathology,2 Anatomy and Cell
Biology,3 and
Urology4 and Center for
Reproductive Sciences,5 Columbia University
College of Physicians and Surgeons, New York, New York 10032
Received 12 July 1999/Returned for modification 1 September
1999/Accepted 31 December 1999
Nectin-2 is a cell adhesion molecule encoded by a member of the
poliovirus receptor gene family. This family consists of human, monkey,
rat, and murine genes that are members of the immunoglobulin gene
superfamily. Nectin-2 is a component of cell-cell adherens junctions
and interacts with l-afadin, an F-actin-binding protein. Disruption of
both alleles of the murine nectin-2 gene resulted in
morphologically aberrant spermatozoa with defects in nuclear and
cytoskeletal morphology and mitochondrial localization. Homozygous null males are sterile, while homozygous
null females, as well as heterozygous males and females, are fertile.
The production by nectin-2 The human poliovirus receptor (Pvr)
is a member of the immunoglobulin superfamily of proteins
(38) and consists of an NH2-terminal signal
sequence, three extracellular immunoglobulin (Ig)-like domains, a
transmembrane domain, and a cytoplasmic tail. Pvr was identified by its
ability to confer poliovirus susceptibility to receptor-negative cells
(23). Sequence homologs of pvr were subsequently
identified in humans (pvr-related receptor 1 [prr1] and prr2 [8, 21]),
monkeys (agm1 and agm2 [18]),
mice (prr1 and mph/prr2 [murine pvr
homolog] [24]), and rats (pE4
[7]). Only pvr, agm1, and
agm2 encode proteins that can function as cell receptors for
poliovirus (18, 23; V. Racaniello, unpublished data,
1999). Pvr, Prr1, Prr2, and Mph/murine Prr2 are entry cofactors for
alphaherpesviruses (9, 37).
The cellular functions of members of the Pvr protein family are not
known. Some members of the Ig superfamily are involved in cell-cell and
cell-extracellular matrix interactions, and others are receptors for
cytokines and growth factors. Expression of human Prr2 or Mph/murine
Prr2 in cultured cells leads to aggregation, suggesting that these
proteins are homophilic adhesion molecules (1, 20). The
cytoplasmic domains of Prr1 and Prr2 proteins interact with l-afadin,
an actin filament-binding protein (35). l-Afadin is
ubiquitously expressed but is localized at specialized membrane
structures, called adherens junctions, which are involved in cell-cell
adhesion (22). l-Afadin contains one PDZ domain through
which it interacts with a COOH-terminal amino acid motif of Prr1 and
Prr2 as well as an actin filament-binding domain. Thus, Prr1 and Prr2
are linked to the cytoskeleton through l-afadin. The Prr1 and Prr2
proteins have been renamed Nectin-1 and Nectin-2 (35); the
new terminology is used in this paper.
To provide information on the function of Pvr family members, we
disrupted the murine nectin-2 gene. Male mice lacking both alleles of nectin-2 are infertile and produce
morphologically aberrant spermatozoa. Heterozygous males and females
and homozygous null females are fertile and have no overt developmental
defects. The heads of spermatozoa from
nectin-2 Generation of mice lacking Nectin-2.
A genomic
fragment was isolated from a Supercos1::129SVJ genomic
library (Stratagene) by hybridization with a radiolabeled probe
generated from the cDNA of nectin-2 (24). Exon 3 (which encodes amino acids 151 to 250 of Nectin-2) was disrupted by
inserting a gene encoding neomycin resistance between a MunI
and a BamHI site (Fig. 1A).
Relative to the endogenous locus, the final construct, pPNT1-3,
contains only the 5' end of exon 3 and, after a deletion of ~1 kb,
9.5 kb of the genomic sequence; the majority of exon 3 and the 5'
splice site of the downstream intron have been deleted (Fig. 1A).
Targeted embryonic stem (ES) cells can be identified by the loss of the
MunI site in nectin-2 exon 3 and the gain of a
PstI site (Fig. 1B). Three different ES cell lines (CCE, PJ5 [14], and R1 [27]) were used. All
cell lines were maintained on mitotically inactivated mouse embryonic
fibroblasts (31). ES cells were electroporated with
linearized pPNT1-3 and selected with Geneticin and Gancyclovir. Of the
600 CCE, 117 PJ5, and 321 R1 ES cell colonies that survived dual
selection, three clones (one CCE, two PJ5, and one R1) had undergone a
homologous recombination event. Chimeric male mice that were generated
from the injection of targeted ES cell lines into C57BL blastocysts
were mated with C57BL females. Their progeny were observed for
transmission of agouti coat color (6). Mice derived from the
injection of the R1 ES cell clone gave rise to male germ line
transmitters. Tail-derived genomic DNA from agouti progeny of this
mating was analyzed by Southern blot hybridization to identify mice
that were heterozygous for the targeted inactivation of
nectin-2 (11).
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Defects in Nuclear and Cytoskeletal Morphology and Mitochondrial
Localization in Spermatozoa of Mice Lacking Nectin-2, a Component
of Cell-Cell Adherens Junctions
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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mice of normal numbers of spermatozoa containing wild-type levels of
DNA suggests that Nectin-2 functions at a late stage of
germ cell development. Consistent with such a role, Nectin-2 is
expressed in the testes only during the later stages of
spermatogenesis. The structural defects observed in spermatozoa of
nectin-2/ mice suggest a role for this
protein in organization and reorganization of the cytoskeleton during spermiogenesis.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
/ mice contain mitochondria, dense
outer filaments, and misshapen nuclei, and the mitochondrial sheath of
the middle piece is disorganized. These morphological defects may
result from an overall disruption of cytoskeletal structure. In normal
mice, Nectin-2 is expressed in the testes only during the later
stages of spermatogenesis, during which the morphological
transformations that produce spermatozoa from the round spermatid
occur. Signaling through Nectin-2 may be crucial for the cytoskeletal
organization and reorganization that occur during spermiogenesis.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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FIG. 1.
(A) nectin-2 exon 3 targeting construct as it
would appear after linearization. The genomic locus of
nectin-2 is shown at the top (adapted from reference
24). Restriction fragment sizes are approximate.
Black boxes represent exons, and intervening black lines represent
introns. The open box at the 3' end of the targeting construct is
nonhomologous DNA from the vector used to generate the targeting
construct. The neomycin resistance (neo) gene contains more than one
PstI site, but only the first, which decreases the size of
the exon 3 genomic fragment after targeting, is shown. B,
BamHI; P, PstI; M, MunI; TK, thymidine
kinase gene. (B) Southern blot analysis of tail DNA from mice that were
wild type (nectin-2+/+), heterozygous for the
nectin-2 disruption (nectin-2+/ ),
or homozygous for the disruption
(nectin-2/). Genomic DNA was digested with
the restriction enzyme PstI. The hybridization probe used
(shown in panel A) can detect a change in the size of the
PstI genomic fragment that would result from the disruption
of nectin-2. DNA marker sizes and positions are indicated.
(C) Flow-cytometric analysis of Nectin-2 expression on primary kidney
cell cultures derived from nectin-2+/+ mice (top
panels) and nectin-2/ mice (bottom panels).
Analyses with rabbit preimmune serum (preimmune), rabbit anti-Nectin-2
polyclonal serum (anti-Nectin-2), and serum that was preincubated with
excess NED are shown in the two left panels. Analyses with or without
rat anti-Nectin-2 monoclonal antibody (mAb) 6B3 are shown in the two
right panels. Bovine serum albumin did not compete away the reactivity
of rabbit anti-Nectin-2 polyclonal serum with
nectin-2+/+ kidney cells (Dong and Racaniello,
unpublished data). Ab, antibody.
Determination of sperm count and motility. The epididymides and vasa deferentia were removed, cut into 2-mm-long pieces, resuspended in a buffer containing 75 mM NaCl and 24 mM EDTA, and homogenized to dissociate somatic cells. The sperm remaining as a monodispersed suspension were counted by hemacytometry. The total number of sperm in the original sample was calculated after correcting for sample volume and tissue weight. Motility of sperm obtained from the epididymides and vasa deferentia was observed as described elsewhere (3).
Nectin-2 mRNA expression.
A cDNA clone encoding Nectin-2
,
reported to be a secreted form of the protein (2), was
obtained from Akio Nomoto. Expression of nectin-2 cDNA in
cultured cells failed to yield either secreted or membrane-bound
protein. Nucleotide sequence analysis of nectin-2 cDNA
revealed that it lacked the initiating AUG codon and the next 7 amino
acids. The defect was corrected by mutagenesis, and the resulting
nectin-2 cDNA was able to direct the expression of
Nectin-2 on the plasma membranes of cultured cells. We conclude that
nectin-2 mRNA encodes a membrane-bound protein. A similar conclusion has been reached by others who used Western blot analysis with antibodies specific for Nectin-2
and Nectin-2
(35).
Flow cytometry. Expression of surface antigens was determined by fluorescence-activated cell sorter (FACS) analysis as previously described (25). A rabbit anti-Nectin-2 polyclonal antiserum was generated against the purified Nectin-2 extracellular domain (NED) (Y. Dong and V. Racaniello, unpublished data) by Cocalico Biological Inc. (Reamstown, Pa.), and the anti-Nectin-2 monoclonal antibody 6B3, which recognizes domain 1 of Nectin-2 (1), was a gift of Akio Nomoto. Mouse primary kidney cell cultures were generated as previously described (30). To ensure the specificity of the polyclonal antiserum, samples of antibody were also incubated with excess NED (1 mg of NED per ml of antiserum) prior to use in FACS analysis of Nectin-2-expressing and -nonexpressing mouse primary kidney cells. Polyclonal antiserum was incubated with bovine serum albumin as a negative control. For analysis of sperm DNA content, sperm were removed from the epididymides and vasa deferentia and counted with a hemacytometer. Approximately 2 × 106 sperm were fixed in 80% ethanol; stained in a solution containing 0.5 mg of propidium iodide, 0.2% NP-40, and 0.5 mg of RNase A; and subjected to FACS analysis.
Isolation of spermatids. Seminiferous tubules were cut into 3-mm2 fragments and incubated in enriched Krebs-Ringer bicarbonate (EKRB) buffer (4) for 3 h at 32°C, which caused the release of a small number of spermatids from the tubules. After being filtered through 85-µm-pore-size Nitex mesh to remove clumps, spermatids were stained with fluorescein isothiocyanate-conjugated monoclonal antibody 6B3. Staining was detected by fluorescence microscopy.
Staining of tissue sections.
Mice were perfused with a
solution consisting of 1% acrolein, 13% collidine, and 2.5%
glutaraldehyde (3). The testes were removed, paraffin
embedded, and sectioned at 4 µm thick. Sections were stained with
hematoxylin and eosin and photographed by light microscopy. For
immunohistochemistry studies, sections were blocked with 10% serum in
phosphate-buffered saline for 30 min and incubated with
affinity-purified rabbit anti-Nectin-2 antibody for 45 min. After three
washes with PBS, the slides were incubated with a 5-µg/ml
solution of biotinylated anti-rabbit antibody (Vector Laboratories,
Inc., Burlingame, Calif.) for 30 min, washed three times with PBS,
stained with 
-galactosidase-avidin (Vector Laboratories), and
developed with X-Gal
(5-bromo-4-chloro-3-indolyl--D-galactopyranoside) as described previously (41).
Electron microscopy. Spermatozoa were isolated as described above, fixed immediately in 2.5% glutaraldehyde-130 mM sodium cacodylate buffer for 1 h, washed with 130 mM cacodylate buffer, and treated with 1% osmicite in 130 mM cacodylate buffer at room temperature. After being washed three times with 130 mM cacodylate buffer, sperm were incubated with 1% tannic acid in 500 mM sodium cacodylate for 30 min at room temperature, washed twice with 100 mM sodium cacodylate, and dehydrated in 50% ethanol for 5 min. Sperm were next incubated with 4% uranyl acetate in 70% ethanol for 1 h at room temperature and then dehydrated in 70, 95, and 100% ethanol in series. Sperm were embedded in LX-112 resin (Ladd), sectioned at about 60 nm, and stained with 4% uranyl acetate and lead citrate. Sections were examined with a Jeol JEM-1200 EXII electron microscope.
MitoTrack and rhodamine phalloidin staining. Sperm were isolated as described above, incubated with 50 nM MitoTrack (Molecular Probes) in EKRB buffer for 45 min at 37°C, and examined by fluorescence microscopy. For F-actin staining, sperm were fixed in acetone for 5 min, incubated with 80 nM rhodamine phalloidin (Cytoskeleton, Inc.) in phosphate-buffered saline containing 10% goat serum, and examined by fluorescence microscopy.
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RESULTS |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Male mice that lack Nectin-2 are infertile.
To
determine the cellular function of the Pvr-related family of proteins,
we inactivated nectin-2 in mouse ES cells by targeted mutagenesis and generated Nectin-2-deficient mice. We constructed a
targeting vector that would disrupt exon 3 of nectin-2 (Fig. 1A) and introduced the vector into ES cells. Cell lines that had undergone a targeting event were used to generate mice that transmitted the disrupted gene. These mice were mated to produce
nectin-2+/ mice. Intercrosses yielded
offspring (~30 litters) that segregated with the expected Mendelian
frequency: 58 wild type, 127 heterozygotes (nectin-2+/), and 51 homozygotes
(nectin-2/). Inheritance of the targeted
gene was monitored by Southern blot analysis (Fig. 1B).
/ mice (30) were analyzed
by flow cytometry for cell surface expression of Nectin-2 protein (Fig.
1C). Whereas the kidney cells of nectin-2+/+
mice showed high levels of Nectin-2 expression, the protein was not
detected on kidney cells from nectin-2/
mice. A slight reactivity was observed with the rabbit anti-Nectin-2 polyclonal antiserum compared to preimmune serum, but this binding was
not competed by the soluble extracellular domain of Nectin-2 (NED),
demonstrating that it was due to nonspecific antibodies in the immune
serum. In contrast, the fluorescence observed with nectin-2+/+ kidney cells was competed by NED to
levels observed with nectin-2/ cells. These
results indicate that Nectin-2 is not produced in nectin-2/ mice.
Homozygous mutant (nectin-2/) mice did not
display any overt developmental abnormalities. However, intercrosses
between nectin-2/ mice failed to produce
progeny. Male and female nectin-2+/ and female
nectin-2/ mice are fertile, but
nectin-2/ male mice are infertile. When 25 nectin-2/ male mice were mated with
wild-type female mice, copulation plugs were identified, showing that
mating had occurred, but no pregnancies were observed.
Mice lacking Nectin-2 have defects in spermiogenesis.
We
examined spermatozoa of nectin-2/ mice to
determine the basis of the observed infertility. No differences between
the numbers of sperm from the epididymides and vasa deferentia of
nectin-2+/+ and
nectin-2/ mice were observed (Table
1). Spermatozoa from
nectin-2/ mice are motile but
morphologically abnormal. The heads are misshapen, the acrosome and
nucleus are heterogeneous in appearance, and frequently the middle
piece is thinner and more undulate than that of wild-type sperm (Fig.
2A and B). Sperm from
nectin-2/ mice contain the same amount of
DNA as wild-type sperm (Fig. 2C), indicating that they have completed
meiosis.
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/ mice are similar (Table 1).
Histological analyses of testes from
nectin-2/ mice did not reveal abnormalities
in Leydig, peritubular (V. Racaniello, unpublished data), or Sertoli
cells (Fig. 2D to G). Spermatogonia, spermatocytes, and spermatids
(spermiogenesis steps 1 to 10) were normal, but at steps 11 to 16 of
spermiogenesis, in essentially all nuclei were observed defects
involving irregular shapes and prominent translucent vesicles (Fig. 2F
and G). The presence of abnormal spermatids, and not spermatocytes,
indicates that nectin-2/ mice have defects
in spermiogenesis.
Abnormal nuclear morphology and outer dense fiber and mitochondrial
localization in spermatozoa of mice lacking Nectin-2.
Electron
microscopy was used to determine the structural basis for the observed
defects in spermatozoa of nectin-2/ mice.
Four distinct abnormalities were observed (Fig.
3). First, mitochondria are present in
the heads of nectin-2/ spermatozoa.
Mitochondria are normally located in the middle piece, but not the
head, of a wild-type spermatozoan. Second, although the chromatin is
condensed, as in spermatozoa from wild-type mice, the nucleus is
distorted. Third, mitochondria in the middle piece are disorganized and
do not form the tightly packed helical sheath observed in normal sperm.
Fourth, the outer dense fibers are jumbled and extend into the head. In
normal spermatozoa, outer dense fibers surround the axoneme in the
middle and principal pieces.
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/ mice that contain mitochondria in
the head, spermatozoa were stained with MitoTrack Green, a dye that
enters cells and selectively binds to mitochondria (Fig.
4). Spermatozoa from wild-type mice were
stained only in the middle piece (Fig. 4A). By contrast, about
60% ± (mean ± standard error) 10% of spermatozoa
from nectin-2/ mice were stained in
the head. In most cases, these spermatozoa were also stained in
the middle piece. Some spermatozoa from
nectin-2/ mice stained only in the
head (<10%), or in the head and in a bulged region in the middle
piece (<10%). About 40% of spermatozoa from
nectin-2/ mice stained only in the middle
piece, a staining pattern observed in spermatozoa from wild-type mice.
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Expression of Nectin-2 in testis and spermatozoa.
Because mice
lacking nectin-2 have defects in spermiogenesis, we examined
expression of this gene in testes. Two nectin-2 mRNAs
derived by alternative splicing have been described.
Nectin-2 mRNA encodes a membrane-bound form
(24), and nectin-2 mRNA reportedly encodes a
secreted form of the protein (2). Our results indicate that
nectin-2 mRNA encodes a membrane-bound protein
(Dong and Racaniello, unpublished data). Nectin-2 and Nectin-2 proteins have identical extracellular domains but differ in
the transmembrane domain and cytoplasmic tail. Both
nectin-2 and nectin-2 are expressed in
testis, although nectin-2 levels are much higher than
those of nectin-2 (Dong and Racaniello, unpublished data).
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/ mice.
Detection of F-actin in spermatozoa.
It has been reported that
Nectin-2 is linked to F-actin through l-afadin (35). To
determine if the lack of Nectin-2 causes abnormalities in the actin
cytoskeleton, spermatozoa were stained with rhodamine phalloidin, a dye
that specifically stains F-actin (15). Staining was observed
throughout spermatozoa from wild-type mice, although it was most
prominent in the middle piece (Fig. 6A).
This staining pattern was seen in 92% (23 of 25 and 23 of 25) of
the wild-type spermatozoa observed in two different experiments. In
contrast, spermatozoa from nectin-2/
mice stained mainly in the head, with relatively lower levels of
staining occurring in the middle piece and the principal piece (Fig.
6B). This staining pattern was seen in 61 and 69% (11 of 18 and 22 of
32, respectively) of the spermatozoa observed in two different
experiments. These results indicate that the distribution of F-actin in
spermatozoa of wild-type mice differs from that seen in
nectin-2/ mice.
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Spermatogenesis, the production of spermatozoa from precursor germ cells, is a complex process that requires tight regulation of developmental genes and extensive cellular restructuring. This process can be divided into three steps: spermatogonial renewal and proliferation, meiosis, and spermiogenesis (32). Spermatogonia proliferate and differentiate to generate diploid spermatocytes, which undergo two successive meiotic divisions to form haploid cells. During spermiogenesis the haploid cells restructure to form spermatozoa. Several morphogenic processes occur simultaneously during spermiogenesis, including condensation and nuclear shaping, development of an acrosome and a flagellum, reorganization of mitochondria, and elimination of residual cytoplasm.
In mice, mutation and disruption of numerous genes have been reported to affect various phases of spermatogenesis (33). For example, the spermatocytes of male mice that lack the transcriptional activator CREM (cyclic AMP-responsive element modulator) proceed to spermiogenesis, but then the spermatids fail to differentiate and there is an increase in the number of apoptotic germ cells (5, 28). Mice that lack calmegin, a testis-specific endoplasmic reticulum chaperone protein, produce morphologically normal spermatozoa which do not adhere to the zona pellucida of the egg (12). The genes of several structural proteins in the spermatid nucleus, which include transition proteins 1 and 2 and protamines 1 and 2, are transcribed and also translated in postmeiotic spermatids (10, 16, 17, 39). Premature translation of protamine 1 mRNA causes early nuclear condensation and arrests spermatid differentiation in mice (19), indicating that proper timing of gene expression may be critical for normal spermatogenesis. Such mouse models provide tools for gaining an understanding of the roles of various genes in the progression of spermatogonia to spermatozoa.
Here we report a block during late spermiogenesis in mice lacking
nectin-2. Spermatozoa from
nectin-2/ mice have defects in nuclear and
cytoskeletal morphology and in mitochondrial localization. The nuclear
defect was observed beginning at step 11 of spermiogenesis. Mutant mice
produce normal levels of motile sperm containing haploid DNA,
demonstrating that spermatogonial renewal and proliferation and meiosis
proceed normally in the absence of nectin-2. Histological
examination of the testes from both wild-type and
nectin-2/ mice shows no differences that
might suggest an arrest of development at early stages such as germ
cell proliferation, meiosis, or steps 1 to 10 of spermiogenesis.
Immunohistochemical analysis revealed that Nectin-2 is expressed only
at the later steps of spermatid development (step 9 and beyond), which
correlates with a putative role during cytoplasmic and nuclear restructuring.
Male mice lacking Nectin-2 may be infertile because the morphologically
aberrant spermatozoa cannot reach, bind to, or penetrate the egg. Why
does the lack of Nectin-2 lead to the production of morphologically
abnormal spermatozoa? The abnormalities include misshapen nuclei with
indentations, the presence of mitochondria in spermatozoan heads, and
disorganization of mitochondrial helical sheaths and outer dense fibers
in the middle piece. Cytoskeletal elements have been shown to be
crucial in nuclear shaping and in the recruitment of mitochondria from
the cytoplasm of the spermatid to the middle piece of the flagellum
(26, 29, 34, 40). Therefore, the observed defects in
spermatozoa from nectin-2/ mice may be a
consequence of cytoskeletal abnormalities. How might the lack of
Nectin-2 affect cytoskeletal structure? Nectin-2 is a component of
cell-cell anchoring junctions known as adherens junctions and is linked
to F-actin through the actin filament-binding protein l-afadin
(35). Anchoring junctions connect the cytoskeletal elements
of neighboring cells, producing an extensive transcellular network that
is structurally robust. In addition to their adhesive functions,
adherens junctions are also believed to regulate cell shape and
differentiation through signaling pathways. For example, other
components of adherens junctions, the cadherins, are required for
cellular rearrangements that occur during development (36). Like Nectin-2, cadherins are linked to F-actin by cytoplasmic proteins;
the cadherin- and actin-binding proteins are called catenins. The
effects of cadherins on development are mediated in part by signal
transduction. Although the interaction of Ig-like cell adhesion
molecules with the cytoskeleton is poorly understood, our results
suggest that Nectin-2 regulates, directly or indirectly, cytoskeletal
structure during spermiogenesis. This hypothesis is supported by the
finding that the patterns of F-actin staining by rhodamine phalloidin
differ in spermatozoa from wild-type and nectin-2/ mice. In spermatozoa of wild-type
mice, the staining is most intense in the middle piece. In spermatozoa
of nectin-2/ mice, the level of staining in
the middle piece is noticeably lower than that in wild-type mice. These
results suggest that the absence of Nectin-2 leads to reduced levels of
F-actin in the middle piece. The details of how Nectin-2 influences the
cytoskeleton remain to be elucidated. Expression of Nectin-2 during
spermiogenesis might bring the l-afadin-F-actin complex to the middle
piece and mediate structural changes of actin. These changes may be
important in nuclear shaping, mitochondrial relocation, and outer dense fiber organization during spermiogenesis.
Nectin-2 is expressed on the plasma membrane in spermatids, and in
spermatozoa it is expressed primarily on the middle piece. These
observations suggest that Nectin-2 is relocated during late spermiogenesis. The presence of Nectin-2 in the middle piece is intriguing in light of the defects in mitochondrial migration to the
middle piece, the disorganization of the mitochondrial helix sheath,
and the reduced levels of F-actin in the middle piece in
nectin-2/ mice. One possible explanation for
the presence of Nectin-2 on the middle piece is that it is required for
proper localization of F-actin, through the interaction with l-afadin.
Disruption of the murine afadin gene leads to embryonic
lethality (13). Studies of embryonic bodies derived from
cultured ES cells revealed that the distribution of F-actin in cells
lacking l-afadin differs from that in wild-type cells (13).
Thus, changes in F-actin occur when either nectin-2 or
afadin is disrupted.
Nectin-2 is a homophilic adhesion molecule (1, 20, 35), and a purified soluble form of Nectin-2 lacking the transmembrane and cytoplasmic domains exists as a dimer (Dong and Racaniello, unpublished data). It is possible that Nectin-2 on spermatids interacts with Nectin-2 on other spermatids or on Sertoli cells. These interactions might be important for proper function of Nectin-2.
Although Nectin-2 expression is ubiquitous,
nectin-2/ mice have no overt defects
other than infertility in males. Since the structural changes that
occur during spermiogenesis are unique, it is possible that Nectin-2
function is not required in other tissues. Alternatively, Nectin-1,
which is ubiquitously expressed, also binds l-afadin and might be
expected to replace the function of Nectin-2 in other tissues.
The human pvr gene family currently consists of three
members, pvr, nectin-1, and nectin-2
(8, 21, 23). It is not known whether Pvr is a component of
adherens junctions or whether it binds l-afadin; Pvr does not have an
l-afadin-binding domain in the cytoplasmic region. In transgenic mice
containing the human pvr gene, Pvr protein is expressed in
the seminiferous epithelium in a pattern similar to that observed for
Nectin-2 in mice (Dong and Racaniello, unpublished data). In addition,
expression of pvr can partially overcome the
morphological defects in spermatozoa of
nectin-2/ mice (Dong and Racaniello,
unpublished data). These results are consistent with a role for
pvr in spermatogenesis and suggest that Pvr, like Nectin-1
and Nectin-2, may interact with the cytoskeleton.
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ACKNOWLEDGMENTS |
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M.J.B. and Y.D. made equal contributions to this paper.
We thank C. Pavel, T. DiChiara, J. Baker, A. Louvi, S. Zeitlin, T. Ludwig, A. Efstratiadis, S. Silverstein, R. Bohenzky, E. Lium, C. Panagiotidis, V. Papaioannou, C. S. H. Young, A. Stall, J. Rossant, E. Colston, and O. Flore for advice, discussions, and materials.
This work was supported by a grant (AI34418) to V.R. from the National Institutes of Health.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Microbiology, Columbia University College of Physicians and Surgeons, 701 W. 168th St., New York, NY 10032. Phone: (212) 305-5707. Fax: (212) 305-5106. E-mail: vrr1{at}columbia.edu.
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Abstract
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Materials and Methods
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Discussion
References
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