INTRODUCTION

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Concern about the sexual transmission of viruses in humans and its health consequences has peaked with the appearance and development of the AIDS pandemic. There is also much concern about the possibility of sexual transmission of viruses in animals, particularly in economically important farm animals. Such sexually transmissible diseases (STDs) may cause epidemics, which may be spread further by the worldwide export of the gametes and embryos of these animals. In light of these major health and economic issues concerning sexually transmitted viral diseases (Table 1), it is paradoxical that, to our knowledge, no general review has been published concerning the presence of viruses in human and animal reproductive tracts and semen and the possible effects of these viruses within infected organs and on reproductive endocrinology. This review aims to address this subject by describing the various viruses identified in the semen and reproductive tracts of mammals, their distribution in tissues and fluids, their possible targets, and the functional consequences of their infectivity on the reproductive and endocrine systems.

VIRUSES AND SEMEN

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Human Semen

The viruses present in human semen and their consequences are listed in Table 2 and Fig. 1.

View larger version (43K): [in this window] [in a new window]   FIG. 1.   Summary of the viruses found in the genital tract and semen of mammals.

Human immunodeficiency virus type 1. Human immunodeficiency virus (HIV) is now the most extensively studied sexually transmitted virus. Its presence in the semen was rapidly established, but the nature of the cells infected remains unclear. One key question is whether the virus strains present in semen arise from the same compartment as those detected in blood cells, since new multidrug therapies are still unable to eradicate the virus completely (71).

Human T-lymphotropic virus type I. HTLV-I, like HIV, is a retrovirus that infects T cells. It is epidemiologically linked to adult T-cell leukemia-lymphoma (230). HTLV-I is sexually transmitted by semen (231, 317, 318), most probably via contaminated lymphocytes in the semen.

Human herpesvirus 8. Kaposi's sarcoma (KS) is frequently associated with AIDS and occurs mainly in homosexual men. The epidemiology of KS in HIV-infected patients suggests that it may be caused by a sexually transmitted infectious agent (37, 144). This agent has recently been identified as a new human herpesvirus called human herpesvirus 8 (HHV-8) or KS-associated herpesvirus. According to many studies using extremely sensitive serologic techniques (76, 97, 133, 145, 223, 321, 322), the prevalence of HHV-8 in the general population is low. However, it is generally accepted that the virus can be detected in the semen of KS-positive patients. A recent study detected HHV-8 DNA in 12% of semen samples from KS patients, with a mean copy number per microgram of positive target DNA of 300, versus 9,000 in blood cells (182). Significant amounts of HHV-8 DNA were also detected in semen samples from 28 HIV-1-infected individuals and were shown to infect the mononuclear cell fraction (45). A recent multicenter comparison study concluded that HHV-8 DNA is present in semen but at concentrations that are probably too low to facilitate its consistent detection (251). Thus, the semen viral load should be measured to determine whether it is high enough for sexual transmission to occur. In addition, the prevalence of HHV-8 in the semen of healthy men has not yet been accurately established. It should, however, been borne in mind that the incidence of KS in HIV-negative individuals is much higher in Italy than, for example, in the United Kingdom (30 times higher) or the United States (20 times higher). In Denmark, a recent study performed on 100 healthy donors did not detect any seminal HHV-8 DNA (161). Therefore, the prevalence of HHV-8 in semen may be higher in some geographical areas than in others. The nature of the infected cells in semen and the origin of the virus also remain to be determined.

Cytomegalovirus. CMV also belongs to the Herpesviridae family. It is very common, with 50% of the otherwise healthy population being infected (349). Infection is spread by intimate contact with infected body fluids including semen (185), and 40% of the semen from healthy donors is infected. This virus was previously erroneously reported to be cold labile, whereas it in fact survives in frozen and thawed semen (137). CMV is thought to be a possible causative agent of hematospermia (169). The virus generally remains in a latent form and causes a lifelong infection, but it may be activated either by a primary infection, for example after organ transplantation, or by the impairment of cellular immunity. Prospective studies in the United States have demonstrated that CMV is responsible for more prenatal and perinatal virus infections than is any other transmissible agent identified to date. The impact of these infections on fetal and neonatal health is unclear. However, preliminary data suggest that CMV is probably the most important agent responsible for congenital infection and damage (185). The French government decided some time ago to reject CMV-seropositive donors for artificial insemination. It then pulled back from this decision, deciding instead to reject only donors with recent seroconversion.

Epstein-Barr virus. Epidemiological studies have shown that Epstein-Barr virus (EBV) infection is most common in the age group at which sexual activity begins, strongly indicating that it is sexually transmitted (334). The presence of EBV in semen has not yet been investigated, but several studies have reported that human seminal plasma activates replication of this virus. Thus, EBV early-antigen expression is stronger in infected cells cultured in the presence of semen (149, 151, 330, 357). In vitro inhibition by seminal plasma of both the T- and B-lymphocyte responses to infection has also been described (193, 334). These results suggest that seminal plasma may facilitate EBV replication in the cervix of the uterus and may therefore have some relevance to the etiology of cervical cancer.

Papillomavirus. Papillomaviruses, like EBV, cause cancer. There has been extensive testing for these viruses in the male genital tract, especially in the prostate, since they are thought to be a possible cause of prostate cancer; this is discussed below (see "Viruses and the prostate and other accessory glands"). Human papillomavirus (HPV) DNA was detected in the semen of three patients, and the data obtained were consistent with the contention that HPV can be transmitted sexually via semen, as suggested by epidemiological data on the sexual transmission of HPV (247). Since that first report, papillomaviruses have been detected in semen in several studies (130, 131, 150, 181, 184). These results conflict with early work by Nieminen, which claimed that papillomavirus DNA was not transmitted by semen since the semen of the sexual partners of 17 women positive for HPV DNA was uninfected (238). However, these results actually show only that transmission from the woman to the man is rather inefficient. Indeed, other studies have indicated that HPV type 16 and 18 DNA is present in sperm cells and may be transmitted to the partner (64, 181, 183, 184). Thus, HPV type 16 DNA and RNA were detected in the semen of 25 and 8% of 24 randomly selected patients, respectively, whereas the prevalence of detection for HPV type 18 DNA and RNA was higher (46 and 21%, respectively). The incidence of asthenozoospermia is significantly higher in patients with HPV in their semen (183).

Hepatitis viruses. Hepatitis viruses may cause acute diseases (fulminant hepatitis) or chronic diseases such as liver cancer and cirrhosis. The ability of human semen to transmit hepatitis B virus (HBV) was first demonstrated by the inoculation of gibbons (291). HBV antigens were subsequently detected in human semen (155), and it is now well established that this biological fluid is a vector for the spread of hepatitis B (84, 107, 115, 153, 158). However, few studies have tried to identify the contaminated cells within semen. Hadchouel et al. (135) showed that HBV DNA was integrated into the DNA of spermatozoa in two of three patients with acute hepatitis, suggesting that there may be true transmission of HBV via the germ line. Another study of chronic HBV antigen carriers showed that HBV DNA was present in all of the semen samples tested with the infected cells being both spermatozoa and mononuclear cells (85). Persistent free HBV DNA has also been detected in the semen of patients with no markers of viral replication in serum, indicating that the genital tract may act as a reservoir and that these patients may transmit the virus sexually (85).

Herpesvirus and adenovirus. HSV is a sexually transmitted agent that may be associated with cervical cancer and may cause high morbidity and mortality in perinatal infection (7, 233). Centifanto et al. (60) were the first to suggest that it was present in the male genital tract: inclusion bodies that resembled those of herpesvirus were found in tissue cultures of semen from two subjects, but no infectious virus could be cultured directly from the samples (94). Moore et al. (226) described an individual in a therapeutic donor insemination program who asymptomatically acquired a primary HSV-2 infection and transmitted it to one of two HSV-seronegative partners, in whom a primary HSV-2 infection developed, providing evidence for the sexual transmission of HSV-2. HSV DNA was recently detected in the semen of men with genital HSV-2 infection, mainly during recurrences of herpes (345). Concerning the type of cell infected within semen, an early electron microscopy study found no ultrastructural relationship between the virion and the spermatozoon (302). However, HSV DNA has recently been detected in human spermatozoa by in situ hybridization (172). The association of HSV DNA with spermatozoa has been linked to fertility problems, because HSV infection was found to be almost three times as common in the semen of patients with a low sperm count attending an infertility clinic as in individuals with a normal sperm count (172). A significant association was also found between infertility and positive tests for HSV in another study performed on 153 men (109). A possible relationship between infertility and the presence of the adenovirus in semen has also been a matter of concern. Csata and Kulcsar (80) detected HSV or adenovirus in the semen of 40% of infertile patients tested and found that these viruses were present in a latent form in 60% of their spermatozoa.

Several viruses have been detected in the semen of a number of animal species (Table 3). DNA from Rous sarcoma virus binds to Xenopus laevis spermatozoa and is transferred to ova during fertilization, inducing developmental malformations in 25 to 30% of embryos (134). In gibbons, sperm abnormalities are frequently encountered and have often been shown to be related to the presence of herpesvirus (36, 327).

Feline immunodeficiency virus is shed into the semen of both experimentally and naturally infected cats (154). Simian immunodeficiency virus (SIV) is also present in the semen of monkeys and is transmitted by this vector (217).

In mice, high concentrations of retroviral particles have been detected in the epididymal fluid (162-164). These viruses are mostly endogenous retroviruses, but some exogenous infectious retroviruses (mouse ecotropic virus and Friend ecotropic virus) have also been described (254), and the association of retroviral particles with spermatozoa may lead to congenital infection. Murine leukemia virus has been found free in the seminal fluid, fixed to spermatozoa, and associated with macrophages (164, 194). The main site of virus synthesis within the male genital tract is the epithelial cells lining the epididymis duct. Murine CMV DNA has also been detected in spermatozoa, and the affected mice remained fertile (31).

The porcine reproductive respiratory syndrome (PRRS) was first recognized in the United States in 1987 and in Europe in 1990 and has now spread worldwide. The PRRS virus (PRRSV) has been detected in semen (341) and is transmitted sexually (6, 237). Attempts have been made to determine the origin of PRRSV in semen by inoculating vasectomized and nonvasectomized boars intranasally with the virus. PRRSV RNA was detected in semen from all the boars and was most consistently found within macrophages. Therefore, macrophages in semen are probably infected via the infection of local tissue macrophages or via infected circulating monocytes or macrophages (69). In contrast, porcine parvovirus DNA, detected in the epididymal semen of oronasally inoculated boars, was found to bind to spermatozoa (128) but seemed to have no negative effect. Lastly, porcine rubulavirus has been reported to reduce sperm quality in sexually mature boars by decreasing spermatozoon motility and concentration (263).

Since viral contamination of semen is common in bulls and since frozen semen is widely distributed and is of major economic importance, national and international organizations have laid down guidelines aimed at establishing disease-free bull studs producing semen free from potential pathogens. Many different viruses have been detected in bull semen. In particular, bovine diarrhea virus has been detected at high titers in semen (28) and is transmitted by semen (214, 215, 285). This virus does not seem to cause sperm defects (170). Bluetongue virus (BTV) has also been isolated from bull semen (51, 146, 250, 252), and a positive relationship has been found between the infectivity of semen samples from bulls infected with latent BTV and semen abnormalities (118), with virus-like particles occasionally observed in the heads of affected spermatozoa (118). BTV is associated with reproductive disorders including early embryo death, abortion, malformation of fetal calves and lambs, and transient infertility in bulls and rams coinciding with the shedding of virus into semen (245). Bulls were experimentally inoculated with BTV to investigate the frequency, duration, and pathogenesis of virus shedding into the semen. The shedding of BTV into semen in infected bulls closely followed peak virus titers in blood, and in no case was the virus isolated from semen without also being isolated from blood. Three of nine heifers inseminated with semen from a bull shedding BTV became viremic, seroconverted, and became pregnant. However, there was no evidence of fetal infection (48, 49). Bovine herpesvirus 1 (BHV-1), one of the most common viral pathogens in bovine semen, may also be associated with a decrease in semen quality, and bull semen is therefore systematically tested for this virus before being used for insemination (106). BHV-1 is present in the seminal plasma rather than the cell fraction (337). The risk of transmitting BHV-1 to cows by insemination has been investigated, and such transmission has been shown to lead to fertility disturbances (337-339). Foot-and-mouth disease virus has also been detected in bull semen and is transmitted by artificial insemination (35, 58, 78, 86, 285, 292, 300, 307). In contrast, bovine leukemia virus is present in semen but does not seem to be transmitted by it (35, 225, 271, 313, 332), possibly due to the presence of an inhibitory factor in fresh semen that prevents bovine leukemia virus infection from becoming established (271). Finally, bovine immunodeficiency virus, a lentivirus, is associated with a lymphoproliferative disease and is prevalent in dairy and beef cattle in the southeastern United States. Its mode of transmission is unknown, but semen is suspected to be a potential vector of infection. Indeed bovine immunodeficiency virus DNA has been detected in the leukocyte fraction of cryopreserved semen specimens (234).

Semen is known to be an important vector in the dissemination of viral diseases, and several viruses are present in cell-free semen and in seminal cells including spermatozoa, macrophages and lymphocytes (see "Viruses and semen" above). Paradoxically, testing for viruses in the testis has not been extensive despite the possibility that they are involved in some of the disorders of this organ, such as orchitis, decrease in semen quality, azoospermia, and testicular carcinoma. The blood-testis barrier makes it likely that the testis acts as a reservoir for viruses (which may be protected against antiviral treatments), and this is another crucial reason for considering the testis to be an organ of special interest in the context of viral infection and STDs. Viruses present in the testis are listed in Fig. 1.

The mammalian testis has two main compartments: (i) the interstitium, which contains the Leydig cells responsible for testosterone production, macrophages, fibroblasts, blood, and lymphatic vessels; and (ii) the seminiferous tubules, which are bordered by the peritubular myoid cells and are composed of the various generations of germ cells (from spermatogonia [the stem germ cells] to the meiotic spermatocytes and the haploid spermatids that differentiate into spermatozoa) that are associated with the somatic Sertoli cells (152). Viruses have been found in both these compartments in humans and other mammals.

The best-known viruses causing testicular disorders in humans are mumps virus and HIV. A few studies have considered the role of oncogenic viruses, such as EBV or papillomavirus, in the etiology of testicular carcinoma even though testicular germ cell tumors are the most common malignant tumors in young adults and the incidence of testicular cancer has been steadily increasing in all countries for which epidemiological data are available (2, 39, 331). The viruses found in the human testis are listed in Table 4; see also Table 6.

Mumps virus. Mumps is caused by an RNA virus of the paramyxovirus group. In prepubertal boys, the symptoms of mumps are usually limited to infectious parotitis, but, in men, orchitis is the most common complication (29, 34). Orchitis develops in 5 to 37% of all adult patients infected with mumps (120). Within the first few days of infection, the virus directly attacks the testes, destroying the testicular parenchyma (44, 242) and decreasing androgen production (4). This accounts for the testicular atrophy observed in 40 to 70% of patients with orchitis (29, 34). Unilateral involvement is the most common, while bilateral involvement occurs in 15 to 30% of the patients with orchitis (201). Bilateral orchitis leads to hypofertility with oligospermia and testicular atrophy in 13% of those patients (59). Morphological studies of mumps-associated orchitis were carried out in the 1940s by Gall (122) and Charny and Meranze (65). They showed the focused nature of the inflammation and described the sequential stages of the disease. During the initial stage, an interstitial edema was commonly detected. Blood vessels were congested and surrounded by lymphocytes. Increased permeability of the blood vessels was found to lead to local interstitial hemorrhage and to exudation of leukocytes and fibrin. The seminiferous epithelium degenerated, but the Sertoli cells seemed little affected. Repair of the damage caused by infection involved the deposition of collagen within the interstitium, followed by tubular atrophy and peritubular concentric fibrosis, the usual residue of mumps orchitis. Sterility may be transient or definitive and is due to the loss of the germinal epithelium (290). There are several possible explanations for the mumps-induced degeneration of germ cells. Since mumps virus does not seem to induce germ cell transformation or proliferation in vitro, it may have an indirect effect (243): (i) high fever associated with the disease leads to a change in testicular temperature, contributing to germ cell degeneration (the most common hypothesis); (ii) germ cell degeneration may be caused by seminiferous tubule congestion following the interstitial edema (201); or (iii) a modification of testosterone production by Leydig cells may have a deleterious effect on seminiferous tubule function. Data concerning the consequences of orchitis on testicular endocrine function are rare. Adamopoulos et al. (3) described a severe alteration of Leydig cell function during the acute phase of the disease. These authors observed a drop in the testosterone level together with an increase in luteinizing hormone (LH) and follicle-stimulating hormone (FSH) levels in 27 patients suffering from mumps orchitis, suggesting a testicular failure. In another study (4) examining three patients, testicular atrophy, libido decrease, impotence, and gynecomasty were associated with the reduction of testosterone and the increase in LH and FSH levels. Thus, in some cases, the Leydig cell function seems to be damaged by the mumps infection. Whether this alteration is due to a direct or indirect effect of the virus on the cells is unknown. Such a dysfunction would also account for the higher incidence of testicular cancer in men who have had mumps than in control men (34). Two publications suggested that mumps virus replicates within the testis: Bigazzi et al. (42, 43) showed viral replication in the interstitial tissue in organotypic culture of monkey testis following virus inoculation through the testicular vein, and Bjorvatn et al. (44) rescued mumps virus by needle aspiration of testis biopsy specimens from mumps-infected patients. Two studies (113, 177) showed that systemic treatment with interferon (IFN) prevented the testicular atrophy caused by mumps orchitis in all treated patients (4 of 4 and 13 of 13, respectively). In the second study, where patients were randomly assigned into two groups, atrophy of the testes was observed in three of eight men in the control group. However, asthenospermia was still detected in four patients 7 years after interferon treatment (177).

Oncogenic viruses. Orchitis has been described as a symptom of infectious mononucleosis caused by EBV, indicating that this virus may have a direct effect on the testis (268). EBV DNA was detected in the testes of three individuals with no EBV-related disease, showing that the testis may be a target organ (67). Rajpert De Meyts et al. (262) found that EBV was not directly involved in the testicular germ cell tumors of 20 patients but thought that germ cell proliferation might be stimulated by testicular EBV-transformed lymphocytes. However, more recently, Shimakage et al. (305) detected EBV RNA and EBV-related proteins in all of the 27 seminomas they tested but in none of 25 nonmalignant testes, providing further support for the hypothesis that EBV is associated with testicular tumors. In addition, transgenic mice expressing papillomavirus genes develop germ cell tumors resembling human seminoma (171). Recently, 39 patients with testicular germ cell tumors were screened for EBV, CMV, and parvovirus B19 DNA by PCR. Neither EBV nor CMV DNA was detected in the testis. In contrast, parvovirus B19 DNA sequences were found in the testicular tissues of 85% of patients with testicular cancers but in none of the normal testicular tissue samples (129). However, the cellular targets of parvovirus B19 within normal and cancerous testes are unknown and the possible role (direct or indirect) of this virus in the development of testicular germ cell tumors is unclear.

Other viruses. HSV-2 was detected in the testes of 4 of 10 corpses at autopsy, suggesting that this organ acts as a reservoir for transmission of the virus (95). Csata and Kulcsar (80) studied the relationship between male infertility and the presence in the semen or testis of HSV-1 or adenovirus. In 40% of patients with infertility either HSV-1 or adenovirus was present within the testis. Testicular cells were also infected in vitro by either HSV-1 or adenovirus, and these two viruses were found to penetrate and replicate (80).

Endogenous retroviruses. Endogenous retroviruses (ERV) are chromosomal elements that have a genomic organization analogous to that of exogenous retroviruses. Their relevance to this review is that they may originate from ancient infections of germ cells by exogenous retroviruses (199), thus demonstrating that viral genomes can be incorporated into the germinal genome. Retrotransposons are closely related to ERV, but differ from them in that they do not have the env gene and, therefore, produce particles that are intracellular and not infectious (178).

The viruses found in the animal testis and their consequences are listed in Table 5. The effects of viruses on the reproductive endocrine systems in men and animals are listed in Table 6.

Viruses and the seminiferous epithelium. In rhesus monkeys experimentally infected with SIV, many seminiferous tubules were found to be necrotic and infiltrated with neutrophils due to opportunist CMV infection. No inclusion-bearing cells (characteristic of CMV infection) were observed in the interstitial tissue, but considerably more were present in the seminiferous tubules than anywhere else in the body (33). CMV antigens were detected by immunohistochemistry in the testes of SIV-infected monkeys in another recent study (179). Malignant lymphoma associated with SIV-induced immunodeficiency in macaques is a high-grade malignant tumor that most frequently affects the viscera, skin, central nervous system, and testes. It has been associated with an EBV-like simian herpesvirus (116). Testicular atrophy is a relative common finding in monkeys infected by SIV (218).

Viruses and the interstitial compartment. The induction of feline acquired immune deficiency syndrome by feline leukemia virus (FeLV) in cats alters hormone production in the hypothalamic-pituitary-gonadal system. Thus, 12 weeks after the infection of male cats with FeLV, much lower levels of testicular testosterone production were observed following the injection of human chorionic gonadotropin in infected cats than in uninfected cats (346). Other glands, such as the hypothalamus and pituitary were also affected, with lower levels of release of LH, FSH, and luteinizing hormone-releasing hormone LHRH (346).

The effects of viruses on the human and animal prostate are listed in Table 7.

In terms of incidence, prostate cancer is one of the most important cancers in men throughout the world. Putative causative agents have therefore been extensively studied. The etiology of prostate cancer is still unknown, but there are two main hypotheses. The first and most popular is the hormonal hypothesis, i.e., that the disease is caused directly or indirectly by endogenous or exogenous androgenic hormonal factors. The other hypothesis is that prostate cancer is caused by an oncogenic virus that may be transmitted venereally. There is indeed some evidence supporting an association between prostate cancer and STD, in particular the link between a high level of sexual activity and prostate cancer reported in some studies. Before reviewing the various viruses detected in the prostate, we should bear in mind that there are two different clinical entities: benign prostate hyperplasia and carcinoma of the prostate. It is unknown whether benign prostate hyperplasia coexists with prostate cancer and has a common etiology or whether it is a totally separate condition, etiologically unrelated to prostate cancer. According to Sokol-Roseman et al. (306), latent carcinoma of the prostate and prostate cancer are etiologically related and the latent carcinoma may correspond to a stage in the natural history of prostate cancer.

Papillomavirus. A link between HPV, a family of oncogenic viruses, and prostate cancer has been sought. McNicol and Dodd (210) detected type 16 and 18 HPV DNA by Southern blotting in prostate tissue from 4 of 12 Canadian patients with benign prostate hyperplasia and in 3 of 4 patients with prostate carcinoma. The viral DNA was in an episomal or integrated form, and the authors concluded that this may have important implications for the etiology of prostate disease. In the following year, they published their results with a larger series of 88 prostate biopsy specimens and found a much higher prevalence of type 16 HPV than of type 18 (211). However, no significant difference was observed between patients with benign disease and those with evidence of malignancy, with nearly half of the patients testing positive in each case. Furthermore, the prevalence of type 16 HPV DNA in diseased prostates did not differ significantly from that in normal prostates. Several studies on the prevalence of HPV in the prostate were published in 1992 and are reviewed in detail elsewhere (81, 279). When the data were combined, 32% of the cancers tested positive for HPV, versus 49% of the benign lesions and 9% of the normal tissue samples. The highest rates of detection were found in earlier studies (probably due to problems of PCR contamination), whereas more recent results have been predominantly negative (81). In particular, one study of 84 American patients carried out using PCR and in situ hybridization (148) reported a low prevalence of type 16 HPV in both normal and cancerous prostates and, in two other studies, no HPV DNA was detected in 30 benign and malignant prostate tissues samples, even by PCR (108, 297). A secondary adult human prostate epithelial cell culture, on transfection with a plasmid containing the entire type 18 HPV genome, acquired an indefinite, life span in culture but did not undergo malignant conversion (267). Thus, although there are strong arguments in favor of the prostate being an important reservoir for the transmission of HPV (18, 101, 282, 333, 350), the involvement of HPV in the pathogenesis of prostate cancer is still a subject of great controversy. For example, two laboratories with extensive experience in HPV research recently tested specimens from two populations with different risks of prostate carcinoma, using three different PCR assays and two serologic assays for HPV. They concluded that HPV was not associated with prostate carcinoma (239, 314). However, another group found that a subgroup of prostate tumors (10 of 47) had a significantly larger number of copies of type 16 HPV sequence than did control tissue samples (1 of 37) (298). Thus, we cannot rule out the possibility that HPV is involved in the etiology of a minority of prostate cancers, as recently suggested by a serological and epidemiological study (98).

Herpes simplex virus. The importance of HSV in prostate disease was first suggested when the virus was isolated from 2 men with prostatitis and from none of 10 men with no prostatic symptoms (227). A later study in which HSV was isolated from the prostate tissue of 15% of the men in a randomly selected population of 190 men suggested that the prostate acts as a reservoir of the virus (60). HSV antigens have also been found in prostate cancer cells (62), and antibodies against an HSV antigen were detected in the sera of all eight patients with prostate cancer tested (280). However, a larger serological epidemiological study investigating whether there was an association between antibodies against HSV-2 and cancer of the prostate showed no significant difference in the level of HSV-2 antibodies between patients with cancer of the prostate and those with benign prostate hypertrophy (139). Specific immunofluorescence was used to test for HSV-2 in prostate carcinoma in 305 patients: 5% of the patients had HSV-2 antigen in the prostate, and a higher prevalence was observed in patients with carcinoma of the prostate than in controls with benign prostate hypertrophy (27). This higher prevalence of HSV-2 was not confirmed in another study of 27 prostate carcinoma and 33 benign prostate hyperplasia patients (136). It therefore seems that HSV-2 infection of the prostate is common (25% in the most recent study), but no causal relationship with prostate carcinoma has yet been demonstrated. However, in vitro transformation of hamster embryo cells by tumor-associated HSV-2 from a human prostate carcinoma has been reported (61).

Cytomegalovirus. CMV was first reported to be present in the prostate in a 3-year-old male donor from whom a cell line was obtained that expressed CMV-specific antigen at the cell surface (264). Geder et al. (124) reported that human prostate cancer cell lines expressed CMV-specific membrane antigen and suggested that CMV might be associated with prostate cancer. Primary cells were then transformed in vitro by a strain of CMV isolated from a normal prostate (123). These authors also showed that prostate cancer cells in culture possessed intracellular antigens specific for CMV but produced no infectious virus particles. However, normal human prostate tissue yielded a CMV isolate that transformed cells, and lymphocytes from prostate cancer patients were found to have specific reactivity against CMV-transformed cells (123). Antibodies against CMV have also been found at higher titers in patients with prostate cancer than in controls with benign prostate hyperplasia (123). Although CMV DNA has been detected in both normal and cancerous prostates, CMV RNA and antigens have only been detected in benign prostate hyperplasia and prostate carcinoma. This suggests that CMV may be associated with prostatic abnormality and that latent CMV may be harbored by normal prostates (46). However, in another study, CMV antigens were not detected in any of the 21 tissue samples from patients with benign prostate hyperplasia (309). Finally, CMV has been detected in the prostate of a patient with prostatitis (208).

Human immunodeficiency virus type 1. HIV-1-related proteins have been found in several adjacent glandular epithelial cells in prostate sections from patients who died from AIDS (82), indicating that this organ may act as a reservoir of the virus (1). However, morphologic analyses of reproductive tissues obtained at autopsy from the bodies of 43 male AIDS patients revealed no major abnormalities of the prostate (257). In another study, viral nucleic acids were not detected by PCR amplification in the epithelium of the prostate but a few macrophages infected with the virus were observed (240).

Human herpesvirus 8. Initially, two studies from the same group claimed to have detected HHV-8 in normal, hyperplastic, and neoplastic prostate glands from HIV-negative individuals (222, 224), but other studies did not find HHV-8 to be associated with this s