1 Service de BactériologieVirologieParasitologieHygiène, CHU Bicêtre, Paris-Sud, 78 rue du Général Leclerc, 94275 Le KremlinBicêtre, 2 Institut National de la Santé et de la Recherche Médicale Unité 355 et Institut Fédératif de Recherche sur les Cytokines,32 rue des Carnets, 92140 Clamart and 3 Laboratoire d'Analyse d'Images en Pathologie Cellulaire, Institut Universitaire d'Hématologie, Hopital Saint Louis, 1 avenue Claude Vellefaux, 75475 Paris Cedex 10, France
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Abstract |
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Key words: cytomegalovirus/Herpesviridae/human sperm/motility/seminal fluid
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Introduction |
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Several viruses are present in the genital tract. The most common are the herpes simplex virus type 2 (HSV2) and human cytomegalovirus (HCMV), which are sexually transmissible and can lead to fetal and neonatal anomalies (Huraux et al., 1999; Ranger-Roger et al., 1999). Sperm are formed in seminiferous tubules in the testes, where they are protected from the environmental tissue by the haematotesticular barrier. We previously showed that no viral particles are found within the seminiferous tubules in MCMV-infected murine testes. However, the peritubular cells, Leydig cells and endothelial cells contained high viral loads (Tebourbi et al., 2001
). Several other papers have reported the presence of HSV2 (Deture et al., 1976
) and of CMV (De Paepe et al., 1990
) in the testes, but this does not automatically mean that the seminiferous tubules were contaminated (Baskar et al., 1986
; Stephanopoulos et al., 1989
). However, viruses may be present in the epididymis (Dalton and Harcourt-Webster, 1991
; MacCarthy et al., 1991
), deferent duct (Kimura et al., 1993
), prostate (Boldogh et al., 1983
; Benson and Smith, 1992
; Mastroianni et al., 1996
) or seminal vesicles (Deture et al., 1976
; Kimura et al., 1993
). If the virus is present in the annexial glands, it may be discharged in the seminal fluid before coming into contact with sperm. The presence of the virus in the semen indicates a genital tract infection. One study (Moore et al., 1989
) found infective HSV2 virus in the semen of a healthy donor with an asymptomatic primary infection, and showed that insemination led to the horizontal transmission of the virus. However, cell culture methods have rarely detected HSV2 in sperm (Deture et al., 1978
; MacGowan et al., 1983
), because semen contains inhibitors that may interfere with these methods (Deture et al., 1978
; Sherman and Morgan, 1989
). More sensitive methods, such as PCR and in-situ hybridization (ISH), have made it possible to detect viral DNA in the semen of men with genital HSV2 infection (Kotronias and Kapranos, 1998
; Wald et al., 1999
) and in the semen of a high-risk population (Tabrizi et al., 2000
). HCMV has been identified in sperm (Lang and Kummer, 1972
). The prevalence of HCMV elements was found to be variable in men who did not have human immunodeficiency virus (HIV) or other sexually transmitted diseases (Lang and Kummer, 1972
; Bantel-Schaal et al., 1993
; Shen et al., 1994
; Mansat et al., 1997
), but it may be high in high-risk populations (Biggar et al., 1983
; Leach et al., 1993). Detection rates are generally higher for viral DNA than for infective particles. In a recent study involving men taking part in an IVF programme (Witz et al., 1999
), 25% of ejaculates, including those from HCMV-negative men (who may or may not have gone on to become positive), were found to contain viral DNA.
Thus, sperm are protected from viral contact in the upper regions of the genital tract, i.e. the testes, whereas sperm in the semen can easily come into contact with viral particles (in the epididymis, deferent duct and annexial glands). This is important as sperm can be harvested from testicular biopsies for ICSI in cases of azoospermia. This then disrupts the haematotesticular barrier, thus removing the protective effect and placing the sperm in close contact with endothelial cells, Leydig cells and peritubular cells. Sperm can also be harvested from the other genital organs or from the semen. In this case, the fertilizing sperm for ICSI are choosen according to their motility. The relationship between the virus and sperm motility is not very clear and the interaction between sperm and virus are of importance.
Some authors have reported an inverse correlation between the presence of HSV2 in semen and sperm motility (Kotronias and Kapranos, 1998). Similar observations have been reported concerning CMV (Torino et al., 1987
). A high concentration of HCMV was detected in the semen of a patient with CMV mononucleosis, and this was associated with a transient decrease in sperm motility (Lang and Kummer, 1972
; Lang et al., 1974
). We were interested to know whether this decrease in sperm motility was due to a direct effect of high concentrations of the virus on sperm or if these results were due to an indirect effect. Few papers have addressed the viral load of semen (Lang and Kummer, 1972
; Biggar et al., 1983
). Therefore it is not clear how the virus and sperm interact. No relationship has been found between sperm and HSV2 (Sherman and Morgan, 1989
), whereas ISH has been used to demonstrate that there is a close relationship between sperm and HSV2 (Kotronias and Kapranos, 1998
). Only one group has found CMV within human sperm (Huang et al., 1986
); another group (Baskar et al., 1986
) observed virus-like particles in mouse sperm.
We developed experimental models to analyse the effects of viruses on sperm motility and the interaction between viruses and sperm in assisted reproduction indications. On the one hand, we used semen, i.e. sperm plus seminal fluid, which is the physiological environment from which motile sperm are selected for intrauterine insemination, IVF and ICSI. On the other hand, we used sperm without seminal fluid (selected by use of a PureSperm gradient), which corresponds to sperm collected in the epididymis before the formation of seminal fluid or to sperm collected from testicular biopsies in azoospermic men for ICSI. The viruses used were HSV2 and HCMV. This study enabled us to study the relationship between viruses and sperm in different regions of the genital tract and to determine whether the new assisted reproduction techniques (especially ICSI in the case of azoospermia) affect the risks of virus adherence to sperm, leading to the introduction of viral particles into oocytes.
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Materials and methods |
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Human sperm
Sperm samples were taken from male patients undergoing IVF or who attended the American Hospital in Neuilly (France) with fertility problems. The selected patients all had 50% motile sperm, as tested in seminal fluid (six samples) or after selection on PureSperm (JOD, Lyon, France) gradient (five samples). For PureSperm gradient selection, 0.22 ml of semen was passed over two successive layers of PureSperm. The culture medium was used to prepare a 45% dilution of the upper layer and a 90% dilution of the 1 ml lower layer. After centrifugation (600 g for 20 min), the sperm pellet was washed in 10 ml PBS (600 g for 10 min) and then diluted in MEM.
Sperm incubated with virus
Sperm (5x105 sperm in 125 µl of MEM) were incubated with the virus (<104 to 106 PFU for 105 sperm) in a Petri dish (Corning 35 mm, tissue culture) for 1 h at 37°C in a moist atmosphere containing 5% CO2. In the controls, the viral suspension was replaced by the culture medium used to prepare the cells.
Interaction between sperm and virus
Sperm motility
Analysis at the optical level. After 1 h incubation, 50 µl of each sample was placed on a slide and the percentage of motile sperm was assessed under the microscope by three independent observers.
Analysis with a CASA system. We used a CASA system to analyse sperm motility. The system used was composed of a microscope (Olympus BHx200), a high speed video camera (Lhesa-Electronic) with a video recorder (Sony time lapse 168) associated with a sytem consisting of a pentium PC, a digitalized Matrox PIP card and an original Siam-Trac software. The following parameters were studied: percentage of motile sperm, straight line velocity (VSL), curvilinear velocity (VCL), linearity (LIN) mean amplitude of lateral head displacement (ALH) and linear acceleration (LA).
For this analysis, sperm were selected on PureSperm gradient and incubated with HSV2 for 1 h (106 sperm/106 PFU in 125 µl DMEM). The control was treated in the same way but replacing the viral suspension with culture medium.
Ultrastructural analysis
The sperm were then incubated with the viral suspensions for 1 h in a glutaraldehyde solution (2.5% in Sörensen buffer). After washing several times with the same buffer to which 1 mol/l sucrose solution had been added, the sperm were incubated in osmic acid (1% in Sörensen buffer) for 1 h before dehydrating by successive passages in 70°, 90°, 95° (3x10 min) and 100° (3x20 min) ethanol. This was followed by a final incubation in araldite for 3 days at 60°C. Ultrathin sections were recovered on 600 mesh grids, before being stained with uranyl acetate in ethanol and then with lead citrate. The sections were examined under a Hitachi electron microscope at a magnification of x12 000. The sections analysed were 10 µm away from each other. The proportion of sperm sections (95 nm thickness) in which viral particles were attached to the membrane or contained in the cell was determined for each experimental condition.
Paired t-tests were used to compare sperm motility (CASA) parameters of seminal fluid-free sperm incubated with either HSV2 or with culture medium. P 0.05 was considered significant.
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Results |
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HCMV. Two samples underwent ultrastructural analysis. Complete and incomplete viral particles, and dense bodies were found to co-exist. Only a few of the sperm were in close contact with viral particles [two out of 238 sperm for sample 1 (0.8 %), and two out of 319 sperm for sample 2 (0.6 %)].
Sperm without seminal fluid incubated with HSV2 or HCMV
A comparative study was carried out using sperm obtained from the same ejaculate and selected by PureSperm gradient. They were incubated with either HSV2 or HCMV.
HSV2. We found 28 viral particles in close contact with the 350 sperm sections observed (8%). The viral particles were either very near the membrane or directly stuck to the membrane of the sperm head (Figure 1E could correspond to fusion of HSV2 virion with the sperm membrane) or of the flagella (Figure 1B,C,D). We did not detect any viral particles inside the sperm. Viral particles were also observed either in isolation or in clusters in the preparation (Figure 1A
), showing that they had not been removed from the sperm sample exposed to HSV2 despite the washes carried out before inclusion in araldite.
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Discussion |
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Some studies have shown that the presence of viral particles in the semen is correlated with a lower percentage of motile sperm (Lai et al., 1997; Kotronias and Kapranos, 1998
). Our study shows that the presence of HSV2 or HCMV in the sperm suspension does not inhibit sperm motility, regardless of the viral concentrations used and the method used to treat the sperm: sperm with seminal fluid, sperm selected by PureSperm gradient (no seminal fluid), or sperm selected by centrifugation and migration (data not shown). These observations were the same for all the samples studied, and CASA system applied to HSV2 strengthened our results. It would therefore appear that the in-vivo correlation between the reported reduction of percentage of motile sperm and the presence of viral particles (Lai et al., 1997
; Kotronias and Kapranos, 1998
) is due to indirect interactions between the virus and the sperm rather than to a direct effect on motility. However, we observed modifications of motility parameters such as VCL, LIN, ALH and LA, showing that in the presence of HSV2, sperm moved more rapidly with a greater ALH.
We showed that human sperm do not bind to HSV2 in the presence of seminal fluid, although free viral particles were found in the seminal fluid. These findings are similar to those of other investigators (Sherman and Morgan, 1989) who did not find a close relationship between sperm and HSV2, and those of another study (Deture et al., 1978
), which observed free viral particles in the seminal fluid. The seminal fluid seems to impede the adherence of HSV2 with sperm. Sherman and Morgan (1989) hypothesized that spermine phosphate is involved. Seminal fluid contains high molecular weight proteins that could impede the interaction of HSV2 with sperm or behave as a receptor for HSV2 thus preventing further contact by sperm.
Conversely, in the absence of seminal fluid, sperm were able to adhere to HSV2. It was difficult to evaluate the exact percentage of sperm with HSV2 adhering to their surface because we observed sections of sperm (95 nm thick) and not whole sperm (45 µm thick). The percentage of sperm bearing viral particles was 8% but may have been as high as 45% if only one viral particle adhered to each sperm. This percentage is within the range described for ISH HSV2 DNA-positive sperm cells (Kotronias and Kapranos, 1998). These results also raised questions about the nature of the relationship between HSV2 and sperm. It may consist of a simple passive attachment that is able to resist the repeated washes. This is highly possible given our results. However, in one spermatozoon, the virus particle seemed to be closer to the sperm membrane, and this could even be a beginning of fusion. Thus, we cannot exclude the possibility that this is a true ligand/receptor relationship that only occurs when sperm have been separated from their seminal fluid. Numerous HSV2 receptors have been identified, including heparan sulphate-like glycosaminoglycans (Trybala et al., 2000
), nectins and a receptor belonging to the tumour-necrosis factor family (Campadelli-Fiume et al., 2000
). It is possible that the sperm have one of these membrane receptors, which is not accessible to the virus when seminal fluid is present.
In conclusion, sperm motility, which is the parameter used to select sperm for ICSI, is not a good enough criterion on which to prove the presence of viral elements in the medium or on the sperm.
From our experiments with virus and sperm with seminal fluid, we can conclude that when the virus is mixed with semen in the annexial glands in vivo, HSV2 does not interact with the sperm and the virus remains in the seminal fluid. In these conditions, the techniques used in assisted reproduction to eliminate the seminal fluids also eliminate the viral particles and improve the sperm preparation. This means that either PureSperm gradient selection or swim-up migration can be used efficiently.
Sperm inside the seminiferous tubules are protected from viruses by the haematotesticular barrier. When this barrier is ruptured, sperm can come into contact with viral particles. Indeed, this barrier is always destroyed when sperm are collected from the testis. This increases the risk of sperm coming into contact with high local concentrations of HSV2 due to contamination from the blood or interstitial tissues. The washing procedure cannot eliminate viral particles, meaning that they are directly injected into the cytoplasm.
The HCMV virus particle did not interact with the sperm when HCMV was added to the semen. However, the relationship between sperm and virus in the absence of the seminal fluid was not so clear as for HSV2, perhaps due to the fact that this virus binds non-specifically. However, as for HSV2, the viral particle may be accidentally injected into the ooplasm during ICSI, either as a result of passive transport by the sperm or from the surrounding environment as washing did not eliminate the virus from the preparation.
Some studies used sperm as vectors (Perry et al., 1999). These experiments concerned purified DNA or plasmids, and we did not study this aspect of the problem as we focused only on infectious virions visible under the electron microscope.
We have attempted to investigate whether there may be a specific risk of viral infection associated with ICSI. Our main conclusion is that ICSI creates a new risk of contaminating sperm with viruses in cases of ICSI for azoospermia. Sperm inside the seminiferous tubules are protected from viruses by the haematotesticular barrier. When this barrier is ruptured, sperm can come into contact with viral particles. Indeed, this barrier is always destroyed when sperm are collected from the testes. This increases the risk of sperm coming into contact with high local concentrations of HSV2 due to contamination from the blood or interstitial tissues. The washing procedure cannot eliminate viral particles, meaning that they are directly injected into the ooplasm.
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Acknowledgements |
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Notes |
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References |
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Submitted on October 8, 2001; accepted on January 2, 2002.