Introduction

Coronaviruses (CoV) are single-stranded RNA viruses, so named after the crown-like appearance given by glycoprotein spikes around the viral envelope, which can be observed by electron microscope. Coronaviridae family includes several genera (from α to δ) that are capable to affect human and other vertebrates: the α-CoV and β-CoV can affect human and various mammals by infecting respiratory, gastrointestinal, and central nervous system, while γ-CoV and δ-CoV mainly affect birds [1, 2]. Since the outbreak of severe acute respiratory syndrome (SARS)-CoV in the south of China in 2002, coronaviruses have been recognized as the cause of several epidemics throughout the world. Recently, a new viral strain appeared in the middle of the same country, in Wuhan [3], starting a pandemic that is currently involving over two million people around the world, more than 100,000 deaths and whose numbers are still increasing each day [4]. Italy is one of the most severely involved countries with up to 160,000 assessed cases and more than 20,000 deaths [5]. This new viral strain belongs to the β-CoV genus and has been named SARS-CoV-2. According to the current knowledge, the clinical manifestations of SARS-CoV-2 are commonly characterized by fever, cough, nasal congestion, asthenia, anosmia, ageusia and dyspnea. The infection may further evolve with the onset of systemic symptoms characterized by cardiovascular coagulation and liver impairment and an atypical pneumonia, that might require hospitalization [6]. The relatively high frequency of these life-threatening complications, together with the high transmissibility and swift global diffusion, forced serious responses from world authorities leading to severe restrictions in the attempt to control the pandemic of the coronavirus disease (COVID-19) [7]. With the aim to contain the disease, researchers activated globally to clarify viral transmission routes and to validate diagnostic tests to quickly identify infected subjects. There is evidence of the SARS-CoV-2 RNA presence in various biological matrices such as stool samples, blood and urine: in stool in particular there seems to be a relatively high detection rate, with longer clearance time than nasopharyngeal swabs from respiratory secretions; blood and urine, instead, seem to have a very low frequency of viral RNA detection [8,9,10]. Nonetheless, this suggests that infection routes other than respiratory droplets are theoretically possible. The presence of SARS-CoV-2 in seminal fluid could have sexual and reproductive implications [11] and reflect in COVID-19 infection and transmission, but this matter has been under-investigated so far. Sperm cryopreservation is routinely used to preserve male fertility and to manage couple infertility in several clinical settings [12]. Cytotoxic agents used in cancer or some surgical intervention can impair spermatogenesis and alter ejaculation. In addition, surgical sperm extraction in azoospermic patients represents another specific indication for sperm freezing [13]. While conventional or microsurgical sperm extraction in patients with obstructive or non-obstructive azoospermia can be easily delayed because of the pandemic, semen cryopreservation cannot be delayed in cancer patients who need to start chemotherapy. In the latter situation, sperm cryobanks represent the only chance of patient’s fertility preservation.

Based on the aforementioned considerations, the possibility that SARS-CoV-2 can be identified in seminal fluid has important implications in reproductive medicine, especially regarding medically assisted reproduction and gamete cryopreservation, where there is a wide margin of uncertainty [14, 15]. The aim of the present paper is to summarize available evidence providing an official position statement of the Italian Society of Andrology and Sexual Medicine (SIAMS).

Methods

A comprehensive Pubmed, Web of Science, Embase, Medline and Cochrane library search was conducted based on the following keywords: ("testis"[MeSH Terms] OR "testis"[All Fields]) AND ("sars virus"[MeSH Terms] OR ("sars"[All Fields] AND "virus"[All Fields]) OR "sars virus"[All Fields] OR ("sars"[All Fields] AND "cov"[All Fields]) OR "sarscov"[All Fields]).

Due to the limited level of evidence and a lack of good study quality and design, producing recommendations according to the Oxford 2011 Levels of Evidence criteria was not possible. However, specific statements summarizing the SIAMS position based on discussion on the available data amongst a board of experts of the field were provided.

SARS-CoV-2 pathogenetic mechanisms of infection: the basis for testis localization

As previously reported, SARS-CoV-2 is a novel β-coronavirus sharing 80% sequence homology with the earlier SARS-CoV virus causing the SARS outbreak in 2003 [16]. However, SARS-CoV-2 presents distinct characteristics. Its 3D structure shows a more compact configuration, which increases its binding affinity for angiotensin converting enzyme 2 (ACE2) that serves as a viral receptor [17]. In addition, SARS-Cov-2 presents a polybasic (furin) cleavage site increasing the virus’ ability to internalize into cells. All these features can explain, at least partially, the strongest clinical impact when compared to the other coronavirus [17].

ACE2 is highly expressed in a wide range of human tissues including testis [18]. In particular, within the testis ACE2 expression has been documented on seminiferous ducts cells, as well as on spermatogonia, Leydig and Sertoli cells confirming the potential risks associated with SARS-CoV-2 infection in the reproductive system [18]. In addition, furin domains are expressed in the epididymis of various domestic mammals including humans, further supporting the risk of genitalia localization of SARS-CoV-2 [19]. If SARS-CoV-2 uses the SARS-CoV receptor ACE2 for cell entry, the transmembrane protease, serine 2 (TMPRSS2) for S protein is priming such internalization resulting in an enhanced isolation of SARS-CoV-2 in cells expressing this type II transmembrane serine protease [20]. TMPRSS2 is highly expressed in the prostate epithelial cells, including the apical plasma membrane of the prostate luminal cells. Its expression is regulated by androgens (apparently an androgen responsive elements is the only known promoter enhancer of this gene) and is also released into semen as a component of prostasomes, organelle-like vesicles that may facilitate sperm function and enhance male reproduction [21].

SARS-CoV-2 and male fertility

S-1 orchitis has been reported as a possible complication of SARS-CoV infection. Similar findings have not been reported for SARS-CoV-2.

S-2 testicular function including testosterone and sperm concentrations should be monitored in patients recovered from with SARS-CoV-2.

S-3 available data do not support the presence of SARS-CoV-2 in seminal fluid of infected subjects.

Evidence

As previously reported, the presence of ACE2 in adult Leydig cells in the testis was proven long ago, with a putative steroidogenesis regulatory role [22], but its precise function, as well as the role for the entire renin-angiotensin system in testicular function regulation, has been investigated with respect to gender differences but not yet fully elucidated [23]. It is possible that viral binding to this metalloprotease might compromise testicular function and the consequent inflammation might lead to epididymo-orchitis with long lasting testicular damage and spermatogenesis impairment. While such occurrence has not yet been described for SARS-CoV-2, it was instead reported for a similar coronavirus SARS-CoV [24]. Alternatively, the orchitis could be the result of a vasculitis as COVID-19 has been associated with abnormalities in coagulation and the segmental vascularization of the testis could account for an orchitis-like syndrome. These observations indicate that it is imperative to monitor recovered COVID-19 men reproductive functions for any abnormalities that might impair future fertility. Accordingly, limited evidence documented that when compared to age-matched healthy men with normal fertility, COVID-19 patients showed a significant increase in serum LH level and a dramatic decrease in serum testosterone (T) to luteinizing hormone (LH) ratio, supporting the presence of a subclinical or compensated hypogonadism [25]. The latter is supported by the epidemiological observation of a higher incidence of complications in older diabetic men that have hypogonadism [26]. Finally, a rise in LH levels is known to increase testicular vascularization [27]. Another hot topic would be the safety and potential consequences of utilization of reproductive cells from SARS-CoV-2 positive subjects: the lack of knowledge currently prevents us from performing a thorough and exhaustive risk analysis regarding possible adverse events in the short or long term. The possible presence of SARS-CoV-2 has not yet been reported and there are only a few case reports investigating this issue. Recently, Paoli et al. [28] reported the absence of viral RNA in the semen fluid of a man with history of COVID-19. This was also confirmed by Pan et al. [29] in a small cohort of Chinese subjects. The latest research letter from Li et al. [30] drew attention for reporting 6 cases of positive SARS-CoV-2 semen samples in severe COVID-19 cases (about 16% of the tested subjects). However, several concerns were raised for methodological issues [31].

Remarks and further perspective

It is important to recognize that all available data on the specific effects of SARS-CoV-2 on testicular function are derived from clinical cases or case series, which represent a major limitation for the data analysis. Hence further studies are required to draw final conclusions. However, data derived from other SARS-CoV infections suggest that in patients recovered from COVID-19, especially for those in reproductive age, andrological and sexological consultation and gonadal function evaluation including semen examination should be suggested [11]. In addition, it should be stressed that the results derived from the studies from Paoli et al., Pan et al. and Li et al. [28,29,30] can allow to speculate that SARS-CoV-2 clearance in seminal fluid overlaps with the clinical recovery or that the virus has never been present in the seminal fluid of the subject. The evaluation of the presence of SARS-CoV-2 in seminal samples is particularly important for semen cryopreservation, because viruses stored in liquid nitrogen retain their pathogenic properties [32]. For this reason, studies in larger cohorts of currently infected subjects are warranted to confirm (or exclude) the presence of risks for male gametes that are destined either for cryopreservation in liquid nitrogen or for assisted reproduction techniques.