A Sertoli cell-specific connexin43 knockout leads to altered interstitial connexin expression and increased Leydig cell numbers.

The Sertoli cell (SC)-specific knockout (KO) of connexin43 (Cx43) results in spermatogenic arrest at the level of spermatogonia and/or SC-only syndrome. Histology of the interstitial compartment suggests Leydig cell (LC) hyperplasia. Our aim has been to investigate possible effects of the SC-specific KO of Cx43 (SCCx43KO) on interstitial LC. We therefore counted LC via the optical dissector method (per microliter of testicular tissue and per testis) and found LC to be significantly increased in SCCx43KO(-/-) compared with wild-type mice. Semiquantitative western blot together with Cx43 and 3ß-hydroxysteroid dehydrogenase immunohistochemistry showed that Cx43 protein was significantly reduced and barely detectable in LC in adult SCCx43KO(-/-) mice. This reduction of Cx43 protein was accompanied by a reduction of Cx43 mRNA as analyzed by laser-assisted microdissection of interstitial cells and subsequent quantitative real-time polymerase chain reaction (PCR). Interestingly, Cx45, another recently detected connexin in LC, was also downregulated. Preliminary qualitative data of LC differentiation markers (Thb2, Hsd3b6) and a steroidogenic marker (Hsd17b3) obtained by reverse transcription plus PCR revealed no obvious differences. Thus, the loss of Cx43 in SC also provokes the downregulation of connexins in interstitial LC at the transcriptional and translational levels. Moreover, SCCx43KO leads to alterations in LC numbers. Despite these alterations, steroidogenesis seems not to be impaired. Further studies, including ultrastructural analysis of the tissue as well as quantitative examination of additional LC markers and testosterone, and functional in vitro experiments, should provide more information about LC differentiation and function in SCCx43KO(-/-) mice.

Germ cell loss is associated with fading Lin28a expression in a mouse model for Klinefelter's syndrome.

Klinefelter's syndrome is a male sex-chromosomal disorder (47,XXY), causing hypogonadism, cognitive and metabolic deficits. The majority of patients are infertile due to complete germ cell loss after puberty. As the depletion occurs during development, the possibilities to study the underlying causes in humans are limited. In this study, we used the 41,XX(Y*) mouse model to characterise the germ line postnatally. We examined marker expression of testicular cells focusing on the spermatogonial stem cells (SSCs) and found that the number of germ cells was approximately reduced fivefold at day 1pp in the 41,XX(Y*) mice, indicating the loss to start prenatally. Concurrently, immunohistochemical SSC markers LIN28A and PGP9.5 also showed decreased expression on day 1pp in the 41,XX(Y*) mice (48.5 and 38.9% of all germ cells were positive), which dropped to 7.8 and 7.3% on 3dpp, and were no longer detectable on days 5 and 10pp respectively. The differences in PCNA-positive proliferating cells in XY* and XX(Y*) mice dramatically increased towards day 10pp. The mRNA expression of the germ cell markers Lin28a (Lin28), Pou5f1 (Oct4), Utf1, Ddx4 (Vasa), Dazl, and Fapb1 (Sycp3) was reduced and the Lin28a regulating miRNAs were deregulated in the 41,XX(Y*) mice. We suggest a model for the course of germ cell loss starting during the intrauterine period. Neonatally, SSC marker expression by the already lowered number of spermatogonia is reduced and continues fading during the first postnatal week, indicating the surviving cells of the SSC population to be disturbed in their stem cell characteristics. Subsequently, the entire germ line is then generally lost when entering meiosis.

Experimental endocrine manipulation by contraceptive regimen in the male marmoset (Callithrix jacchus).

Marmosets are used as preclinical model in reproductive research. In contrast to other primates, they display short gestation times rendering this species valid for exploration of effects on fertility. However, their peculiar endocrine regulation differs from a those of macaques and humans. We subjected male marmosets to previously clinically tested hormonal regimens that are known to effectively suppress spermatogenesis. Beside a control group, seven groups (each n=6) were investigated for different periods of up to 42 months: regimen I, (four groups) received testosterone undecanoate (TU) and norethisterone enanthate (NETE); regimen II, (two groups) received TU and NETE followed by NETE only; and regimen III, (one group) received NETE only. Testicular volume, cell ploidy and histology, endocrine changes and fertility were monitored weekly. TU and NETE and initial TU and NETE treatment followed by NETE failed to suppress spermatogenesis and fertility. Testicular volumes dropped, although spermatogenesis was only mildly affected; however, testicular cellular composition remained stable. Serum testosterone dropped when NETE was given alone but the animals remained fertile. Compared with controls, no significant changes were observed in sperm motility and fertility. Administration of TU and NETE affected testicular function only mildly, indicating that the regulatory role of chorionic gonadotrophin and testosterone on spermatogenesis is obviously limited and testicular function is maintained, although the endocrine axis is affected by the treatment. In conclusion, marmosets showed a different response to regimens of male contraception from macaques or men and have to be considered as a problematic model for preclinical trials of male hormonal contraception.

Sperm competition leads to functional adaptations in avian testes to maximize sperm quantity and quality.

The outcome of sperm competition (i.e. competition for fertilization between ejaculates from different males) is primarily determined by the relative number and quality of rival sperm. Therefore, the testes are under strong selection to maximize both sperm number and quality, which are likely to result in trade-offs in the process of spermatogenesis (e.g. between the rate of spermatogenesis and sperm length or sperm energetics). Comparative studies have shown positive associations between the level of sperm competition and both relative testis size and the proportion of seminiferous (sperm-producing) tissue within the testes. However, it is unknown how the seminiferous tissue itself or the process of spermatogenesis might evolve in response to sperm competition. Therefore, we quantified the different germ cell types and Sertoli cells (SC) in testes to assess the efficiency of sperm production and its associations with sperm length and mating system across 10 species of New World Blackbirds (Icteridae) that show marked variation in sperm length and sperm competition level. We found that species under strong sperm competition generate more round spermatids (RS)/spermatogonium and have SC that support a greater number of germ cells, both of which are likely to increase the maximum sperm output. However, fewer of the RS appeared to elongate to mature spermatozoa in these species, which might be the result of selection for discarding spermatids with undesirable characteristics as they develop. Our results suggest that, in addition to overall size and gross morphology, testes have also evolved functional adaptations to maximize sperm quantity and quality.

Testicular blood supply is altered in the 41,XXY* Klinefelter syndrome mouse model.

Hypergonadotropic hypogonadism is a major feature of Klinefelter syndrome (KS), assumed to be caused by testicular hormone resistance. It was previously shown that intratesticular testosterone levels in vivo and Leydig cell function in vitro seem to be normal indicating other functional constraints. We hypothesized that impaired testicular vascularization/blood flow could be a co-factor to the observed hypergonadotropic hypogonadism. We evaluated the testicular vascular system by measuring blood vessel sizes during postnatal development and testis blood flow in adult 41,XXY* mice. Proportional distribution and size of blood vessels were analyzed during testicular development (1, 3, 5, 7, 10, 21 dpp, 15 wpp). While ratios of the vessel/testis area were different at 15 wpp only, a lower number of smaller and mid-sized blood vessels were detected in adult KS mice. For testicular blood flow determination we applied contrast enhanced ultrasound. Floating and reperfusion time for testicular blood flow was increased in 41,XXY* mice (floating: XY* 28.8 ± 1.69 s vs XXY* 44.6 ± 5.6 s, p = 0.0192; reperfusion XY* 19.7 ± 2.8 s vs XXY*: 29.9 ± 6.2 s, p = 0.0134), indicating a diminished blood supply. Our data strengthen the concept that an impaired vascularization either in conjunction or as a result of altered KS testicular architecture contributes to hormone resistance.

Impaired recognition memory in male mice with a supernumerary X chromosome.

Several aberrant chromosomal constellations are known in men. Of these the karyotype XXY (Klinefelter syndrome, KS) is the most common chromosomal disorder with a prevalence of about one in 800 live-born boys. KS is associated with hypogonadism and is suspected to cause variable physical, physiological and cognitive abnormalities. As a supernumerary X chromosome is also associated with infertility, sound animal models for KS are difficult to obtain. In this study, male mice with two X chromosomes (XX(Y*)) were derived from fathers carrying a structurally rearranged Y chromosome (Y*) that resulted in physical attachment of a part of the Y chromosome to one X. These animals display certain physiological features that resemble closely those of human KS and can also be utilized to study X chromosomal imbalance and cognition. Therefore 15 XX(Y*) males and 15 XY* controls were subjected to a battery of behavioral tests, including a general health check, analysis of spontaneous exploration and locomotor activity, measures for anxiety-related behavior and the "novel object task" to test memory performance. Physiologically, XY* males did not differ from C57Bl/6 wild type mice carrying a normal Y chromosome, which provided a valid control group. All mice appeared healthy. XX(Y*) mice did not differ from their wild type littermates with respect to locomotion, exploration and anxiety-related behavior. XX(Y*) male mice, however, exhibited no significant recognition memory performance in contrast with wild type XY* males that readily fulfilled a given task. These findings support the hypothesis that the presence of a supernumerary X in male mice influences cognitive abilities. We suggest that the altered endocrine state and/or changes in the dosage of X-linked genes in the XX(Y*) mouse model affect brain function, in particular those regions responsible for cognition and learning behavior.

Direct but no transgenerational effects of decitabine and vorinostat on male fertility.

Establishment and maintenance of the correct epigenetic code is essential for a plethora of physiological pathways and disturbed epigenetic patterns can provoke severe consequences, e.g. tumour formation. In recent years, epigenetic drugs altering the epigenome of tumours actively have been developed for anti-cancer therapies. However, such drugs could potentially also affect other physiological pathways and systems in which intact epigenetic patterns are essential. Amongst those, male fertility is one of the most prominent. Consequently, we addressed possible direct effects of two epigenetic drugs, decitabine and vorinostat, on both, the male germ line and fertility. In addition, we checked for putative transgenerational epigenetic effects on the germ line of subsequent generations (F1-F3). Parental adult male C57Bl/6 mice were treated with either decitabine or vorinostat and analysed as well as three subsequent untreated generations derived from these males. Treatment directly affected several reproductive parameters as testis (decitabine & vorinostat) and epididymis weight, size of accessory sex glands (vorinostat), the height of the seminiferous epithelium and sperm concentration and morphology (decitabine). Furthermore, after decitabine administration, DNA methylation of a number of loci was altered in sperm. However, when analysing fertility of treated mice (fertilisation, litter size and sex ratio), no major effect of the selected epigenetic drugs on male fertility was detected. In subsequent generations (F1-F3 generations) only subtle changes on reproductive organs, sperm parameters and DNA methylation but no overall effect on fertility was observed. Consequently, in mice, decitabine and vorinostat neither affected male fertility per se nor caused marked transgenerational effects. We therefore suggest that both drugs do not induce major adverse effects-in terms of male fertility and transgenerational epigenetic inheritance-when used in anti-cancer-therapies.

Reassembly of somatic cells and testicular organogenesis in vitro.

Testicular organogenesis in vitro requires an environment allowing a reassembly of testicular cell types. Previous in vitro studies using male murine germ cells cultured in a defined three-dimensional environment demonstrated tubulogenesis and differentiation into spermatozoa. Combining scaffolds as artificial culture substrates with testicular cell culture, we analysed the colonization of collagen sponges by rat testicular cells focusing on cell survival and reassembly of tubule-like-structures in vitro. Isolated testicular cells obtained from juvenile Sprague Dawley and eGFP transgenic rats were cultured on collagen sponges (DMEM high glucose+Glutamax, 35°C, 5% CO2 with or without gonadotropins). Live cell imaging revealed the colonization of cells across the entire scaffold for up to 35 days. After two days, histology showed cell clusters attached to the collagen fibres and displaying signs of tubulogenesis. Clusters consisted mainly of Sertoli and peritubular cells which surrounded some undifferentiated spermatogonia. Flow cytometry confirmed lack of differentiation as no haploid cells were detected. Leydig cell activity was detected by a rise of testosterone after gonadotropin stimulation. Our approach provides a novel method which is in particular suitable to follow the somatic testicular cells in vitro an issue of growing importance for the analysis of germ line independent failure of spermatogenesis.

Early social instability affects plasma testosterone during adolescence but does not alter reproductive capacity or measures of stress later in life.

The social environment plays an important role in modulating processes of the hormonal and behavioural profile of an animal in a variety of group-living species. In wild cavies for instance, unstable social environmental conditions during pregnancy and lactation lead to an infantilised biobehavioural profile of the male offspring. In the present study, the influence of the social environment during pregnancy and lactation on the male wild cavy offsprings' plasma testosterone development, reproductive capacity and stress system activity was investigated. To this purpose, 12 sons whose mothers had lived in an unstable social environment during pregnancy and lactation were compared with 12 sons whose mothers had lived in a stable social environment during the same time. Plasma testosterone (T) and plasma cortisol (C) concentrations were determined from days 20 to 107 of age. Adrenal tyrosine hydroxylase (TH) activity and different parameters of reproductive capacity (weights of testes, epididymides and accessory sex glands, cellular composition of the testes, DNA fragmentation indices and sperm motility parameters) were analysed at day 107 of age. TH activity and plasma C were unaffected by different social environmental conditions early in life. The developmental time course of T concentrations, however, was significantly different: Sons whose mothers had lived in an unstable social environment during pregnancy and lactation showed a delayed increase in T concentrations around adolescence compared to controls. In contrast, no reproduction-related parameters measured within this study differed significantly between the two groups. Thus, early social instability affects plasma testosterone development during adolescence in a significant way but does not alter reproductive capacity or measures of stress later in life.

Maturation of sperm volume regulation in the rat epididymis.

Sperm maturation in the epididymis may involve differences between mature and immature spermatozoa in their volume regulatory osmolyte response. Spermatozoa obtained from the rat caput and cauda epididymidis were examined for their ability to regulate volume after transfer from in situ epididymal osmolality (measured to be 343 +/- 13 and 365 +/- 19 mmol kg(-1), respectively) to that of the female tract in single- and multiple-step protocols. Cells withstood the single-step treatment better than the multistep protocol. Sperm volume estimates by flow cytometric measurements of forward scatter of cells with intact head membranes was more sensitive than those by assessing cell coiling microscopically. At osmolalites below 210 mmol kg(-1) both caput and cauda cells ruptured, limiting the use of flow cytometry. Above this critical value, the use of quinine showed that both caput and cauda cells could regulate volume, but cauda cells were the more effective. Of several organic osmolytes studied, myo-inositol, glutamate and KCl caused only temporary and slight swelling of spermatozoa cells in hypotonic medium. Spermatozoa of both maturities seemed to use potassium as the preferred osmolyte for regulating volume.

Male 41, XXY* mice as a model for klinefelter syndrome: hyperactivation of leydig cells.

Sex chromosome imbalance in males is linked to a supernumerary X chromosome, a condition resulting in Klinefelter syndrome (KS; 47, XXY). KS patients suffer from infertility, hypergonadotropic hypogonadism, and cognitive impairments. Mechanisms of KS pathophysiology are poorly understood and require further exploration using animal models. Therefore, we phenotypically characterized 41, XX(Y)* mice of different ages, evaluated observed germ cell loss, studied X-inactivation, and focused on the previously postulated impaired Leydig cell maturation and function as a possible cause of the underandrogenization seen in KS. Xist methylation analysis revealed normal X-chromosome inactivation similar to that seen in females. Germ cell loss was found to be complete and to occur during the peripubertal phase. Significantly elevated FSH and LH levels were persistent in 41, XX(Y)* mice of different ages. Although Leydig cell hyperplasia was prominent, isolated XX(Y)* Leydig cells showed a mature mRNA expression profile and a significantly higher transcriptional activity compared with controls. Stimulation of XX(Y)* Leydig cells in vitro by human chorionic gonadotropin indicated a mature LH receptor whose maximal response exceeded that of control Leydig cells. The hyperactivity of Leydig cells seen in XX(Y)* mice suggests that the changes in the endocrine milieu observed in KS is not due to impaired Leydig cell function. We suggest that the embedding of Leydig cells into the changed testicular environment in 41 XX(Y)* males as such influences their endocrine function.