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First published online 23 April 2008
doi: 10.1242/dev.020461
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1 Department of Applied Animal Science, Graduate School of Biosphere Science,
Hiroshima University, Higashi-Hiroshima, Hiroshima, 739-8528, Japan.
2 Infertility Center, Daigo-Watanabe Clinic, Fushimi-ku, Kyoto, 601-1375,
Japan.
3 Department of Molecular and Cellular Biology, Baylor College of Medicine,
Houston, TX 77030, USA.
* Author for correspondence (e-mail: mashimad{at}hiroshima-u.ac.jp)
Accepted 4 April 2008
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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B pathway and induced Il6, Ccl4 and
Ccl5 mRNA expression within 2 hours. Anti-TLR2 and anti-TLR4
neutralizing antibodies significantly suppressed hyaluronan fragment- and
hyaluronidase-induced activation of the NFB pathway and the expression
of these genes. When ovulated COCs were cultured with sperm, the expression
and secretion of cytokine/chemokine family members were induced in a
time-dependent manner that could be blocked by TLR2/TLR4 antibodies or by a
hyaluronan-blocking peptide (Pep-1). The chemokines secreted from
TLR2/TLR4-stimulated COCs activated cognate chemokine receptors (CCRs)
localized on sperm and induced sperm protein tyrosine phosphorylation, which
was used as an index of capacitation. Significantly, in vitro fertilization of
COC-enclosed oocytes was reduced by the TLR2/TLR4 neutralizing antibodies or
by Pep-1. From these results, we propose that TLR2 and TLR4 present on cumulus
cells were activated by the co-culture with sperm in a hyaluronan
fragment-dependent manner, and that chemokines secreted from COCs induced
sperm capacitation and enhanced fertilization, providing evidence for a
regulatory loop between sperm and COCs during fertilization.
Key words: Toll-like receptor, Cumulus cell, Cytokine/chemokine, Fertilization, Sperm
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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; Richards,
2005). Some of the matrix-associated genes that have been
identified encode hyaluronan synthase 2 (HAS2)
(Fülöp et al.,
1997a), TNF-
-induced protein 6 (TNFAIP6, also known as
TSG6) (Fülöp et al.,
1997b; Fülöp et al.,
2003) and pentraxin 3 (PTX3)
(Varani et al., 2002;
Salustri et al., 2004).
Polymeric HA directly binds to serum-derived inter--trypsin inhibitor
(II) (Chen et al., 1992;
Camaioni et al., 1993) and
interacts with TNFAIP6. PTX3 binds directly to TNFAIP6 to provide an
additional link of stability to the matrix scaffold within COCs
(Fülöp et al., 2003;
Salustri et al., 2004).
The functional relevance of HA and HA-binding proteins has been documented
by a wealth of biochemical data and physiological studies using mutant mouse
models. Specifically, the level of Tnfaip6 mRNA was significantly
lower in mice null for either Ptgs2 (prostaglandin-endoperoxide
synthase 2, also known as COX2) or Ptger2 (prostaglandin E
receptor 2, also known as EP2) than in their wild-type littermates
(Ochsner et al., 2003a;
Ochsner et al., 2003b),
indicating that Tnfaip6 gene expression was dependent on
prostaglandin E2 and its receptor pathway. Ovulation in both mouse models was
reduced slightly, but cumulus expansion, as well as fertilization, was
completely suppressed in these mutant mice
(Lim et al., 1997;
Kennedy et al., 1999;
Hizaki et al., 1999).
Additionally, Ptx3-null mice showed abnormal cumulus-oocyte complex
morphology and reduced in vivo fertilization
(Varani et al., 2002;
Salustri et al., 2004). The
fertilization defects of Ptgs2-, Ptger2- or Ptx3-null mice
were related to defective matrix stability/function because mature oocytes
retrieved from these mutant mice could be fertilized in vitro by the use of
capacitated spermatozoa (Matsumoto et al.,
2001; Salustri et al.,
2004). Collectively, these reports suggest that the
hyaluronan-rich matrix produced by COCs is essential not only for ovulation,
but also for in vivo fertilization, and perhaps more specifically for sperm
capacitation.
Specific biochemical roles of the HA-rich matrix have been implicated by
recent studies showing that HA fragments can impact immune cell responses by
binding to specific membrane receptors. CD44, a cell surface molecule that is
generally considered to be a primary HA receptor
(Aruffo et al., 1990;
Miyake et al., 1990), is
expressed in cumulus cells of mouse, human and porcine COCs during the
ovulation process (Ohta et al.,
1999; Kimura et al.,
2002; Hernandez-Gonzalez et
al., 2006). CD44 recognizes both high molecular weight HA present
within extracellular matrices and small fragments of HA generated during
tissue injury, inducing the expression of cytokine and chemokine families
(Hodge-Dufour et al., 1997;
Cuff et al., 2001;
Kothapalli et al., 2007). HA
fragments have also been reported to stimulate members of the pathogen
recognition receptor surveillance pathway, toll-like receptor 2 (TLR2) and
TLR4, which are present in macrophages
(Termeer et al., 2002;
Fieber et al., 2004).
Interestingly, Chang et al. reported that TLR2 and TLR4 do not recognize the
high molecular weight of HA, but that fragments of less than 230 kDa can
activate these receptors (Chang et al.,
2007); maximal effects were observed with 30-mer fragments,
suggesting a gradient of responses during HA degradation. Moreover, very small
HA fragments can activate the TLR-dependent pathway but not CD44 in acute lung
injury (Jiang et al., 2005),
providing additional evidence that HA may exert pleomorphic effects on
TLR2/TLR4-positive cells. Our recent study
(Shimada et al., 2006)
documented that cumulus cells of ovulated COCs express numerous immune
cell-related genes, including members of the TLR family, TLR4 and related
molecules. When the ovulated COCs were cultured with the TLR4 ligand, LPS, the
expression of Il6, Ptgs2 and Tnf mRNA was increased.
These results indicated that the TLR4 pathway was present and functional in
cumulus cells of ovulated COCs. Although the physiological relevance of the
TLR pathway in ovulation and fertilization has not been explored, the ability
of capacitated sperm to secrete hyaluronidase, leading to the modification and
breakdown of the COC HA-rich matrix, is well known
(Srivastava et al., 1965;
Rogers and Morton, 1973;
Talbot and Franklin, 1974).
These reports, and our previous study, led us to hypothesize that, during the
fertilization process, sperm-secreted hyaluronidase would generate small HA
fragments capable of activating TLR2 and/or TLR4 on cumulus cells.
To examine this hypothesis, ovulated COCs were cultured with the TLR4 ligand LPS, the TLR2 ligand Pam3Cys-Ser-(Lys)4 HCl (Pam3Cys), or with small HA fragments. The functional responses of cumulus cells to these ligands were analyzed by determining ligand-mediated secretion of specific cytokines and chemokines. Neutralizing antibodies for TLR2, TLR4 or CD44 were used to verify receptor activation. siRNA approaches were used to examine the responses (or lack thereof) in a granulosa cell culture system. Hyaluronidase and in vitro fertilization of COC-enclosed ooctyes by sperm provided further evidence consistent with a role for HA-induced TLR activation in the fertilization process. Finally, we show that TLR2 and TLR4 are expressed by the cumulus cells of ovulated human COCs, and that a positive correlation occurs between the in vitro fertilization of human oocytes and the levels of chemokine family members secreted by the COC. Therefore, the TLR pathway may have physiological relevance in human fertility as well.
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MATERIALS AND METHODS |
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SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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-amanitin and LPS
were purchased from Sigma Chemical Co. (Sigma; St Louis, MO), and Pam3Cys was
from Calbiochem (Los Angeles, CA). Hyaluronan fragments purified from pig skin
were obtained from Saikagaku Kougyou (Tokyo, Japan). CCL2 (MCP1), CCL4
(MIP1β) and CCL5 (RANTES) were from R&D Systems (Minneapolis, MN).
Anti-TLR2 neutralizing antibody (MAb mTLR2) and anti-TLR4 neutralizing
antibody (MAb mTLR4/MD2) were purchased from InvivoGen (San Diego, CA),
anti-CD44 neutralizing antibody (A020) from Calbiochem, and anti-CCL5
neutralizing antibody (anti-mouse CCL5/RANTES antibody) from R&D Systems.
Routine chemicals and reagents were obtained from Nakarai Chemical Co. (Osaka,
Japan) or Sigma.
Animals
Immature female C57BL/6 mice were obtained from Clea Japan (Tokyo, Japan).
At 23 days old, female mice were injected intraperitoneally (IP) with 4 IU of
eCG, to stimulate follicular growth, followed 48 hours later by injection with
5 IU hCG to stimulate ovulation and luteinization
(Robker et al., 2000). Animals
were housed under a 16-hour light/8-hour dark schedule in the Experiment
Animal Center at Hiroshima University, and provided food and water ad libitum.
Animals were treated in accordance with the NIH Guide for the Care and Use of
Laboratory Animals, as approved by the Animal Care and Use Committee at
Hiroshima University.
Cumulus-oocyte complex isolation and culture
Ovulated COCs were recovered from oviducts and 50 COCs were cultured in
separate wells of a Falcon 96-well plate (Becton Dickinson, Franklin Lakes,
NJ) in 150 µl of defined medium
(Ochsner et al., 2003a),
containing 1% (v/v) FBS with LPS, Pam3Cys or HA fragment in the presence or
absence of each specific neutralizing antibody (anti-TLR2 rat polyclonal IgG,
anti-TLR4 rabbit polyclonal IgG or anti-CD44 rabbit polyclonal IgG). After
culture of COCs, the culture medium was recovered for use in the Bio-Plex
Protein Array System (BioRad, Hercules, CA, USA). Total RNA or protein was
extracted from cumulus cells isolated from COCs (see below).
In vitro fertilization
Ovulated COCs were collected from oviductal ampullae 16 hours after the hCG
injections and placed into 150 µl of human tubal fluid (HTF) medium.
Spermatozoa were collected from the cauda epididymi of 4-month-old ICR strain
mice into 500 µl of HTF medium. After 15, 30 or 60 minutes, the spermatozoa
were introduced into fertilization medium at a final concentration of 1000
spermatozoa/µl. Twelve hours after insemination, oocytes were washed
thoroughly five times, and then checked for the formation of pronuclei under a
phase-contrast microscope. Some COCs were recovered after 2 or 4 hours of
culture with sperm; cumulus cells were then isolated to prepare the total
RNA.
Synthesis of Pep-1 and control peptide
Pep-1 (GAHWQFNALTVR) and scrambled control peptide (WRHGFALTAVNQ), both
with an amidated GGGS linker (Mummert et
al., 2000; Jiang et al.,
2005), were synthesized by Scrum (Tokyo Japan). Peptide solutions
were prepared immediately before use by dissolution in DMSO to a concentration
of 500 mg/ml. The COCs were pre-cultured with 0.5 mg/ml peptides (final
concentration of DMSO was 0.1%) for 30 minutes, and then treated with
hyaluronidase or cultured with sperm as described above. The scrambled control
peptide did not significantly affect the gene expression in cumulus cells and
sperm penetration (data not shown).
Sperm culture
Spermatozoa were collected from the cauda epididymi of 4-month-old mice
into 500 µl of HTF medium. The sperm were cultured with 100 pg/ml of CCL2,
CCL4 or CCL5 for 30 or 60 minutes. After culture, sperm were lysed by Laemmli
sample buffer and then analyzed for tyrosine phosphorylation as described
below.
Sperm accumulation assay
Sperm were collected from the cauda epididymi of 4-month-old mice into 500
µl of HTF medium and placed into a m-Slide VI flow chamber for live cell
analysis (Ibidi GmbH, Munich, Germany). The chamber plate has two wells
connected by a narrow channel. First, 100 µl of HTM medium was added to the
plate and 1x105 sperm were placed on one side. The agonists
were added to other side chamber, and the plate was incubated for 30 minutes.
After culture, the number of sperm that had moved to other side was
counted.
siRNA treatment procedure in cultured mouse granulosa cells
TLR2 and TLR4 Silencer Pre-designed siRNA were purchased from Ambion
(Austin, TX). The sequences were:
TLR2, GGCAUUAAGUCUCCGGAAUtt (sense) and AUUCCGGAGACUUAAUGCCtt (antisense);
TLR4, GCAUCUAUGAUGCAUUUGUtt (sense) and ACAAAUGCAUCAUAGAUGCtt (antisense).
Scrambled siRNA duplex (Ambion) was used as a negative control. Mouse
granulosa cells (1x106 cells/well) recovered from
eCG/hCG-primed mice were plated in 12-well culture plates for 3 hours before
transfection. Transfection of siRNA (25 nM) was accomplished using the HVJ
envelope vector kit GenomONE neo (Ishihara Sangyo, Tokyo, Japan), according to
the manufacturer's instructions and our previous study
(Shimada et al., 2007). Cells
were incubated at 37°C in a CO2 incubator, and the culture
medium was replaced 5 hours after transfection. After transfection, granulosa
cells were cultured with 100 µg/ml of HA fragment for 2 hours. After
culture, total RNA was collected and gene expression analyzed by real-time
PCR.
Collection of human COC from periovulatory follicles, and the media after in vitro fertilization
Women were stimulated with human menopausal gonadotrophin (HMG; HMG
Injection TEIZO, Teikoku-zouki, Tokyo, Japan) according to routine procedures.
Ovarian follicle diameter was assessed by transvaginal sonography, and
gonadotropins were administered daily until the second largest follicle
reached a diameter of 18 mm. When the follicle grew beyond that diameter,
10000 IU HCG (Gonatropin; Teikoku-zouki) or 600 µg GnRH-agonist was
administered; 35 hours later, oocytes were retrieved under ultrasonographic
guidance. The oocytes underwent conventional IVF for 5 hours, before being
transferred to 500 µl P-1 medium (preimplantation-1 medium; Irvine
Scientific) under mineral oil with 10% (v/v) human serum at 37°C in a
humidified atmosphere of 5% CO2, 5% O2 and 90%
N2. After 12 hours of culture, the formation of pronuclei was
observed. The medium after conventional IVF was kept below -80°C before
Bio-Plex protein array analysis using the Human Cytokine 9-Plex Panel
(BioRad), as described below. All patients gave written informed consent to
participate in this study.
RT-PCR analyses
Total RNA was obtained from cumulus cells or granulosa cells using the
RNAeasy Mini Kit (Qiagen Sciences, Germantown, MD), according to the
manufacturer's instructions. Real-time or quantitative (Q) RT-PCR analyses
were performed as described previously
(Shimada et al., 2007).
Briefly, total RNA was reverse transcribed using 500 ng poly-dT (Amersham
Pharmacia Biotech, Newark, NJ) and 0.25 U avian myeloblastosis virus-reverse
transcriptase (Promega, Madison, WI) at 42°C for 75 minutes and 95°C
for 5 minutes.
For real-time PCR analysis, cDNA and primers were added to the Power SYBR Green PCR Master Mix (Applied Biosystems, Foster City, CA, USA) to give a total reaction volume of 15 µl. PCR reactions were then performed using the iCycler thermocycler (Bio-Rad). Conditions were set to the following parameters: 10 minutes at 95°C, followed by 45 cycles each of 15 seconds at 95°C and 1 minute at 60, 62 or 64°C. Specific primers were selected and analyzed as indicated in Table 1.
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Western blot analyses
Protein samples from cumulus cells, sperm, spleen or testes were prepared
by homogenization in whole cell extract buffer and then diluted by the same
volume of 2xSDS sample buffer
(Hernandez-Gonzalez et al.,
2006). Extracts (5 µg protein) were resolved by SDS
polyacrylamide gel (10%) electrophoresis and transferred to Immobilon-P nylon
membranes (Millipore, Bedford, MA). Membranes were blocked in Tris-buffered
saline and Tween 20 [TBST: 10 mM Tris (pH 7.5), 150 mM NaCl and 0.05% Tween
20], containing 5% (w/v) non-fat Carnation instant milk (Nestle, Solon, OH).
Blots were incubated with primary antibody as shown in
Table 2 overnight at 4°C.
After washing in TBST, enhanced chemiluminescence (ECL) detection was
performed by using ECL western blotting detection reagents (Amersham) and
appropriate exposure of the blots to Kodak X-ray film. Specific bands were
quantified by densitometric analyses using a Gel-Pro analyzer (Media
Cybernetics, Bethesda, MD).
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Bio-Plex protein array system
During culture, media samples were collected and cytokines present in the
media were analyzed with the Bio-Plex Protein Array System (BioRad) using the
Bio-Plex Mouse Cytokine 23-Plex Panel, including antibodies for interleukin
(IL) family members [IL1, IL1β, IL2, IL3, IL4, IL5, IL6, IL9,
IL10, IL12 (p40), IL12 (p70), IL13, IL17], Eotaxin (CCL11), granulocyte
colony-stimulating factor (GCSF), granulocyte-macrophage colony stimulating
factor (GMCSF), interferon 
(IFN), keratinocyte-derived
chemokine (KC), monocyte chemotactic protein 1 (MCP1, CCL2), macrophage
inflammatory protein 1 (MIP1, CCL3), MIP1β (CCL4), RANTES
(Regulated upon Activation, Normal T-cell Expressed and Secreted; CCL5), and
tumor necrosis factor (TNF), or the Human Cytokine 9-Plex
Panel, including IL1β, IL6, IL12 (p70), IL17, Eotaxin (CCL11), GCSF, MCP1
(CCL2), MIP1β (CCL4), and RANTES (CCL5), according to our previous report
(Shimada et al., 2007).
Statistics
Statistical analyses of data from three or four replicates were carried out
by one-way ANOVA followed by Duncan's multiple-range test (Statview; Abacus
Concepts, Berkeley, CA).
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RESULTS |
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SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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β and
NFB showed that the levels of these proteins were increased in COCs
collected at 8 and 16 hours post-hCG administration compared with at 0 hours,
except for NFB, confirming and extending previous studies
(Shimada et al., 2006) that
the TLR2/TLR4 pathway is expressed in cumulus cells of ovulated COCs. To
determine if the TLR2/TLR4 pathways were functional, 23 different cytokines
and chemokines were analyzed in the medium of COCs that had been cultured for
24 hours with the TLR4 ligand (LPS), the TLR2 ligand (Pam3Cys) or the small HA
fragment, using the Bio-Plex Protein Array system.
As shown in Table 3, COCs
cultured with LPS or Pam3Cys secreted increased levels of several cytokines
and chemokines [IL1, IL1β, IL6, IL9, IL12 (p40), IL12 (p70), GCSF,
Eotaxin, CCL2, CCL3, CCL4 and CCL5] compared with COCs cultured without
agonists. When COCs were cultured with HA fragments, the levels of IL6, as
well as those of IL12 (p40), CCL2, CCL4 and CCL5, were higher than those
observed in controls. Although COCs released IL1, IL1β, I12 (p70),
GCSF and CCL2, the levels between control and HA fragment-treated samples were
not dramatically different. The secreted levels of other tested
cytokines/chemokines were below the detection limit. The dramatic increase in
the secretion of specific cytokine family members in response to LPS, Pam3Cys
or HA fragments confirmed the concomitant upregulation of gene expression
(Fig. 1B) and previous studies
stating that cumulus cells are highly secretory
(Shimada et al., 2007).
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HA fragments induced the TLR2-, TLR4- and CD44-targeted signal transduction pathways
Previous studies have implicated p38MAPK phosphorylation, ERK1/2
phosphorylation and the activation of Iβ-NFB signaling as
downstream targets of the TLR pathway
(Kawai and Akira, 2005).
Therefore, we investigated whether these signaling pathways were activated via
TLRs in the cumulus cells of ovulated COCs cultured with HA fragments. As
shown in Fig. 2, these pathways
were activated by HA fragments, but the temporal pattern of MAP kinase
phosphorylation was different from that of NFB pathway. Specifically,
phosphorylation of p38MAP kinase and ERK1/2 was rapidly but transiently
upregulated: high levels at 15 minutes returned to basal levels after 60
minutes. By contrast, the phosphorylation of NFB was induced
progressively from 15 minutes to 120 minutes. At that time, degradation of
Iβ was also detected.
To determine if the regulation of MAP kinase family and NFB pathways
was mediated by TLR2/TLR4, ovulated COCs were cultured in the presence of both
anti-TLR2 and anti-TLR4 neutralizing antibodies (anti-TLRs), or the anti-CD44
neutralizing antibody for 15 minutes or 2 hours, respectively. The rapid
phosphorylation of p38MAP kinase and ERK1/2 by HA fragments at 15 minutes was
suppressed by both anti-TLRs and anti-CD44 antibodies, suggesting that HA
activated the TLR receptors. Conversely, anti-TLR2 and anti-TLR4 neutralizing
antibodies suppressed the decrease of Iβ and the phosphorylation
of NFB at 2 hours. Anti-CD44 antibody did not affect the NFB
pathway, at least not during the time interval examined.
Hyaluronidase impacts gene expression and NFB pathway activation in cumulus cells of ovulated COCs
When ovulated COCs were incubated with different concentrations of
hyaluronidase for 2 hours, significant increases in the expression of Il6,
Ccl4 and Ccl5 mRNA were detected at the 1.0 IU/ml dose, and
further increases in Ccl5 mRNA were detected at hyaluronidase
concentrations of 10 or 100 IU/ml (Fig.
3A). Hyaluronidase (10 IU/ml) also significantly stimulated
Ccl2 mRNA expression (Fig.
3A).
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β and the phosphorylation of NFB in cumulus cells of COCs,
responses that were reversed by anti-TLR2 and anti-TLR4 neutralizing
antibodies (Fig. 3B).
TLRs mediate the expression and secretion of cytokine/chemokine families during in vitro fertilization procedures
The expression of Il6 and Ccl5 mRNA in cumulus cells was
also induced within 2 hours by the co-culture of ovulated COCs with sperm
(Fig. 4A). The induction of
these genes in cumulus cells was suppressed by the addition of anti-TLR2 plus
anti-TLR4 neutralizing antibodies, or by treatment with the HA-blocking
peptide Pep-1, described by Mummert et al.
(Mummert et al., 2000),
whereas the anti-CD44 antibody had no significant effect
(Fig. 4A). These treatments did
not significantly affect the expression of Snap25 mRNA
(Fig. 4A). To analyze the
secretion levels of cytokines/chemokines, we collected the medium 0.5, 1, 2 or
4 hours after ovulated COCs were cultured with capacitated sperm. The results
show that high levels of IL6, CCL4 and CCL5 were secreted within 4 hours
culture. The secretion of each cytokine was rapidly and significantly induced
within 1 hour, and secretion further increased in time-dependent manner
(Fig. 4B). After 1 hour of
culture, the release of these cytokines from COCs was independent of de novo
mRNA transcription, because addition of the transcriptional inhibitor
-amanitin (10 µg/ml) did not alter the levels of CCL4, CCL5 or IL6
in the culture medium (Fig.
4C). However, -amanitin did significantly suppress the
levels of these cytokines after 2 hours culture with sperm
(Fig. 4C). Moreover, when COCs
were cultured with sperm in the presence of anti-TLR2 plus anti-TLR4
neutralizing antibodies, significantly lower levels of cytokines were detected
at both 1 and 2 hours of culture (Fig.
4C). Lastly, pronuclear formation in oocytes was analyzed after 12
hours of in vitro fertilization with sperm. Approximately 70% of the oocytes
were fertilized and contained two pronuclei
(Fig. 4D), responses that were
reduced by the addition of neutralizing antibodies to TLR2/TLR4
(Fig. 4D). The HA-blocking
peptide Pep-1 also significantly suppressed pronuclear formation
(Fig. 4D).
Sperm express chemokine receptors (CCR1, CCR2, CCR3 and CCR5) that are required for sperm capacitation during the fertilization process
Cumulus cells of cultured COCs secrete various kinds of
cytokines/chemokines during the sperm-mediated fertilization process (see
Table S1 in the supplementary material). Of note, IL6 and CC chemokine family
members (CCL2, CCL3, CCL4 and CCL5) were predominantly produced from COCs at
more than 100 pg/ml. Whereas CCL2 stimulates the CCR2 receptor, CCL3 binds
mainly to CCR1 and partly to CCR5, and CCL4 selectively activates CCR5. All of
receptors (CCR1, CCR2, CCR3 and CCR5) were activated by CCL5
(Charo and Ransohoff, 2006).
The CCR receptors are members of the G-protein coupling receptor family that
induce phospholipase C to increase Ca2+ and PKC activation in
cytoplasm (Meyer et al.,
1996). In sperm, the Ca2+-PKC pathway is involved in
capacitation (Rotem et al.,
1992), suggesting that the COC-secreted CC chemokine family might
play an important role in sperm capacition during the fertilization process.
The RT-PCR analysis shown in Fig.
5A shows the expression of Ccr1, Ccr2, Ccr3 and
Ccr5 mRNA in sperm collected from the cauda epididymis. The positive
immunofluorescent signals observed following the use of an anti-CCR3 antibody
localized CCR3 to luminal region of the testicular seminiferous tubules, and,
at higher magnification, showed that CCR3 was detected near the tail of
spermatozoa; however these signals were very weak and a few cells also stained
positive with the rabbit IgG control antibody
(Fig. 5B). Whole-mount
preparations of spermatozoa provided additional evidence that CCR3 is present
preferentially in the mid-piece of sperm
(Fig. 5C). The immunoreactive
band at about 55 kDa that corresponds to CCR3 was present in spleen used as
positive control. In the testis sample, a 55 kDa band (as well as three other
minor bands) was detected by the anti-CCR3 antibody. Sperm contained only one
immuno-positive band of the correct size, indicating that sperm do express
CCR3 (Fig. 5D).
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).
Tyrosine phosphorylation in protein extracts from sperm exposed to CCL2, CCL4
or CCL5 for 30 and 60 minutes was analyzed by western blotting using a pan
anti-Tyr phosphorylation antibody. Positive immunoreactive bands were detected
at 
110 kDa, 75 kDa, 65 kDa and 50 kDa when sperm were cultured with
BSA for 60 minutes (data not shown). Although the level of phosphorylation of
the band at 110 kDa was not dramatically changed from that of the
control, for each ligand, the level of phosphorylation of other bands was
increased within 30 minutes culture; the highest intensity was detected in
sperm cultured with CCL5 for 60 minutes
(Fig. 5E). To determine the role of CCL5 during the fertilization process, we examined whether the addition of CCL5 could overcome the inhibitory effects of TLR neutralizing antibodies on fertilization, and, conversely, whether antibodies to CCL5 could reduce fertilization. The results showed that fertilization was suppressed by anti-TLR2/TLR4 neutralizing antibodies and that the addition of CCL5 slightly, but not significantly, increased the fertilization rate (Fig. 5F). However, the anti-CCL5 neutralizing antibody significantly suppressed the percentage of oocytes that completed fertilization (Fig. 5F).
It is known that when the high concentrations of sperm recovered from the
cauda epididymis are cultured for more than 60 minutes (pre-culture),
capacitation is induced spontaneously
(Fraser, 1977). Therefore, we
examined whether the prolonged pre-culture of sperm that allows capacitation
would overcome the negative effects of the anti-TLR2/4 neutralizing antibodies
and the anti-CCL5 neutralizing antibody on sperm penetration. Without
pre-culture or antibody exposure, fertilization was highly variable (control,
Fig. 5G). The number of oocytes
fertilized increased in controls in a duration-dependent manner, with maximal
success obtained when the sperm were pre-cultured for 60 minutes (i.e.
complete capacitation; Fig.
5G). The addition of neutralizing antibodies significantly
suppressed the penetration of sperm that were pre-cultured for 15 or 30
minutes (Fig. 5G). However,
these negative effects were not detected when sperm were pre-cultured for 60
minutes and hence were fully capacitated
(Fig. 5G).
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DISCUSSION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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; Shimada et al.,
2006). Specifically, we have documented that, when ovulated COCs
were cultured with the TLR4 ligand bacterial lipopolysaccharide (LPS), the
expression of Il6 and Tnf was induced. However, the
endogenous ligand(s) for TLR2/TLR4 and the physiological role of this
signaling cascade in ovulated COCs remained unclear. Because cumulus cells
produce and are surrounded by a HA-rich extracellular matrix and because HA
fragments have been shown recently to activate TLR2 and TLR4
(Termeer et al., 2002;
Jiang et al., 2005), we
hypothesized that HA fragments generated during matrix degradation might act
as an endogenous ligand for TLR2 and/or TLR4 that are present in cumulus cells
of ovulated COCs. Herein, we provide the first evidence that TLRs can play a
functional role in the, at least in vitro, fertilization process. Notably, we
show that hyaluronidase treatment and culture with sperm (used as a biological
source of hyaluronidase) activate TLR2/TLR4 on cumulus cells. Activated
cumulus cells, but not sperm itself, then release specific cytokines capable
of enhancing sperm capacitation and fertilization. Thus, a functional
regulatory loop appears to be operative between sperm and the ovulated
COCs.
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B, and the expression of specific genes (Il6, Ccl2, Ccl4 and
Ccl5) in cumulus cells. This response was similar to that observed
when ovulated COCs were exposed to LPS, a known ligand of TLR4
(Shimada et al., 2006),
indicating that HA fragments could serve as ligands for cumulus cell TLRs. The
ability of HA fragments to active these signaling cascades and to induce the
expression of specific cytokines in cumulus cells was selectively mediated by
TLR2 and TLR4, as TLR2 and TLR4 neutralizing antibodies, but not the anti-CD44
antibody (see Fig. S1 in the supplementary material), blocked the effects of
HA. The HA-rich matrix generated during COC expansion is presumed to be of
high molecular weight, as cumulus cells express primarily HAS2
(Fülöp et al.,
1997a), which is known to generate HA with a broad but extremely
large size (average molecular weight of more than 2x103 kDa)
(Itano et al., 1999). Although
the functions of high molecular weight HA are not entirely clear for any cell
system, it can bind and activate CD44, but not TLR2 and TLR4 in macrophages
(Cuff et al., 2001;
Chang et al., 2007). To
determine whether HA is a physiologically relevant ligand for TLRs on cumulus
cells, ovulated COCs were treated with exogenous hyaluronidase or were
cultured with sperm that are known to secrete hyaluronidase. The results show
that exogenous hyaluronidase significantly upregulated Il6, Ccl2,
Ccl4 and Ccl5 mRNA expression, and induced activation of the
NFB pathway in cumulus cells. The induction of these genes and the
activation of specific signaling pathways by hyaluronidase were suppressed by
anti-TLR2/TLR4 neutralizing antibodies. Moreover, the culture with sperm
induced the expression of Il6 and Ccl5 mRNA through
TLR2/4-dependent, but CD44-independent, mechanisms. Additionally, we used the
HA blocking peptide Pep-1, which has been shown to function effectively in
vitro to inhibit the binding of HA to its receptors
(Mummert et al., 2000;
Taylor et al., 2004). Pep-1
significantly suppressed the expression of Il6 and Ccl5 mRNA
in cumulus cells and sperm penetration in in vitro fertilization assays. It
has been shown that hyaluronidase depolymerizes high molecular weight HA to
10-40 kDa end products (Sampson et al.,
1992), suggesting that the small HA fragments generated by
sperm-secreted hyaluronidase probably activated TLR2 and TLR4 on cumulus
cells, leading to cytokine and chemokine expression via the NFB
pathway.
The high level of cytokine secretion from cumulus cells 2-4 hours after
exposure to sperm was dependent on the increased transcription of specific
genes, as -amanitin blocked this effect. By contrast, the initial rapid
release of IL6, CCL4 and CCL5 by the TLR2/TLR4 pathway during fertilization
did not require de novo mRNA synthesis. The mechanism by which the rapid
release is regulated could involve an exocytosis system because cumulus cells
express components of the SNARE complex [synaptosomal-associated protein 25
(Snap25), syntaxin 1a (Stx1a) and synaptotagmin 1
(Syt1)] (Shimada et al.,
2007) (M.S., unpublished). In mast cells, vesicle degranulation
and the release of cytokines occurs in a TLR2- and TLR4-dependent manner
(Supajatura et al., 2002), via
exocytosis involving SNAP25 localized to the secretory granules
(Salinas et al., 2004;
Stow et al., 2006). Thus, it
is possible that the SNAP25-associated exocytosis system present in cumulus
cells is also activated by the small HA fragment-induced TLR pathway during
the fertilization process, although the precise mechanisms remain to be
resolved.
The functional role of secreted CC chemokines appears to be part of a
regulatory loop between COCs and sperm, because chemokines can enhance
fertilization by the activation of GPCRs (CCRs) and calcium release. We show
here that multiple CCRs are expressed in mouse sperm, as well as in human
sperm (Isobe et al., 2002;
Muciaccia et al., 2005), and
that CCR3 is localized to the mid-piece of mature sperm. During capacitation,
the increase of Ca2+ is observed around the mid-piece of
spermatozoa (Harper et al.,
2004), and the Ca2+-dependent pathway evokes protein
tyrosine phosphorylation (Carrera et al.,
1996), suggesting that secreted CC chemokine families are involved
in sperm capacitation. When sperm collected from cauda epididymi were cultured
with CCL2, CCL4 or CCL5, increased levels of immunoreactive phosphotyrosine
were detected in extracts of the CCL5 treatment group. CCL5 treatment also
increased sperm motility in a dose-dependent manner (see Fig. S2 in the
supplementary material). Moreover, using COC-conditioned medium, we showed
that factors secreted by COCs induced not only sperm motility but also
capacitation, and that these effects were suppressed by the addition of
anti-CCL5 neutralizing antibody (see Fig. S3 in the supplementary material).
Furthermore, the fertilization of oocytes was suppressed significantly by
either anti-TLR2/TLR4 or anti-CCL5 neutralizing antibodies if short-term
pre-cultured sperm was used for insemination. However, after prolonged
pre-culture (over 60 minutes), which mediates complete sperm capacitation,
fertilization was not impaired by the presence of neutralizing antibodies.
Based on these results, we conclude that during the fertilization process,
TLR2 and TLR4 present on the cumulus cells are activated by co-culture with
sperm in a hyaluronan fragment-dependent manner, leading to the secretion of
CCL5 and other CC chemokine family members. These, in turn, stimulate CC
receptors on sperm to enhance sperm motility and to induce sperm capacitation,
thereby enhancing successful fertilization. Thus, there is a functional
regulatory loop between the COCs and sperm.
Finally, we report that Tlr2 and Tlr4 mRNA are also expressed in human peri-ovulatory cumulus cells, and that human COCs secret IL6, CCL2, CCL4 and CCL5 during in vitro fertilization. Therefore, it is likely that the TLR system in human cumulus cells plays a similar role to in mouse cells in facilitating fertilization. Importantly, human oocytes collected from COCs that produced high amounts of CCL4 or CCL5 showed higher fertilization rates than did oocytes from COCs that produced low levels of these cytokines. On the basis of these data in human and mouse COCs, the addition of CC chemokines such as CCL5 might improve IVF or intracytoplasmic sperm injection (ICSI) protocols.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/135/11/2001/DC1
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ACKNOWLEDGMENTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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