Evaluation of damage to the testicular cells of golden hamsters caused by experimental cryptorchidism using flow cytometry and confocal microscopy

Testicular heat stress, a historical perspective and two postulates for why male germ cells are heat sensitive

Herein, we compare the different experimental regimes used to induce testicular heat stress and summarise their impact on sperm production and male fertility. Irrespective of the protocol used, scrotal heat stress causes loss of sperm production. This is first seen 1-2 weeks post heat stress, peaking 4-5 weeks thereafter. The higher the temperature, or the longer the duration of heat, the more pronounced germ cell loss becomes, within extreme cases this leads to azoospermia. The second, and often underappreciated impact of testicular hyperthermia is the production of poor-quality spermatozoa. Typically, those cells that survive hyperthermia develop into morphologically abnormal and poorly motile spermatozoa. While both apoptotic and non-apoptotic pathways are known to contribute to hyperthermic germ cell loss, the mechanisms leading to formation of poor-quality sperm remain unclear. Mechanistically, it is unlikely that testicular hyperthermia affects messenger RNA (mRNA) abundance, as a comparison of four different mammalian studies shows no consistent single gene changes. Using available evidence, we propose two novel models to explain how testicular hyperthermia impairs sperm formation. Our first model suggests aberrant alternative splicing, while the second model proposes a loss of RNA repression. Importantly, neither model requires consistent changes in RNA species.

Silica nanoparticles cause spermatogenesis dysfunction in mice via inducing cell cycle arrest and apoptosis

The widespread use of silica nanoparticles (SiNPs) has increased the risk of human exposure, which raised concerns about their adverse effects on human health, especially the reproductive system. Previous studies have shown that SiNPs could cause damage to reproductive organs, but the specific mechanism is still unclear. In this study, to investigate the underlying mechanism of male reproductive toxicity induced by SiNPs, 40 male mice at the age of 8 weeks were divided into two groups and then intraperitoneally injected with vehicle control or 10 mg/kg SiNPs per day for one week. The results showed that SiNPs could damage testicular structure, perturb spermatogenesis and reduce serum testosterone levels, leading to a decrease in sperm quality and quantity. In addition, the ROS level in the testis of exposed mice was significantly increased, followed by imbalance of the oxidative redox status. Further study revealed that exposure to SiNPs led to cell cycle arrest and apoptosis, as shown by downregulation of the expression of positive cell cycle regulators and the activation of TNF-α/TNFR Ⅰ-mediated apoptotic pathway. The results demonstrated that SiNPs could cause testicles injure via inducing oxidative stress and DNA damage which led to cell cycle arrest and apoptosis, and thereby resulting in spermatogenic dysfunction.

Overexpression of Endothelial Nitric Oxide Synthase in Transgenic Mice Accelerates Testicular Germ Cell Apoptosis Induced by Experimental Cryptorchidism

Surgical induction of cryptorchidism in experimental animals causes testicular germ cell apoptosis and infertility. The mechanisms of germ cell apoptosis have been associated with oxidative stress or testicular exposure to elevated temperature. Nitric oxide (NO) has been associated with apoptosis in a number of cell types. The objective of this study was to investigate whether overexpression of endothelial NO synthase (eNOS) could accelerate apoptosis of germ cells in the testes of transgenic mice. There are 3 NOS isoforms, and we restricted the analysis to eNOS at this time. For the colocalization of eNOS, staining in degenerating germ cells that were apoptotic cells suggested that eNOS may be related to germ cell apoptosis. eNOS overexpression in the testes of eNOS transgenic (eNOS-Tg) mice was examined using Western blot analysis. Unilateral cryptorchidism was surgically induced in both eNOS-Tg and wild-type (WT) adult mice. The testes were evaluated 1, 3, 5, 7, and 14 days after the operation by weighing the testes and examining histopathologic features and cell apoptosis using in situ microscopic analysis of DNA fragmentation. Immunoblotting for eNOS protein demonstrated increases in eNOS protein expression in testes, as well as the lung and aorta. In eNOS-Tg mice, weight reduction of cryptorchid testis was significantly increased on days 3, 5, and 7 (P = .02, .02, and .04, respectively). The numbers of spermatocytes and spermatids of eNOS-Tg cryptorchid testis significantly decreased compared with those of WT cryptorchid testis from day 3 (spermatocytes: P = .04; spermatids: P = .02). Moreover, terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling demonstrated that eNOS-Tg mice significantly accelerate germ cell apoptotic changes induced by experimental cryptorchidism compared with WT mice from day 3 (P = .03). We have provided evidence that eNOS plays a functional role in mouse spermatogenesis in cryptorchidism-induced apoptosis.

Concentrações plasmáticas de testosterona, triiodotironina (T3) e tiroxina (T4) em bodes submetidos ao estresse calórico

Para verificar o efeito do estresse calórico (EC) nas concentrações plasmáticas de testosterona, triiodotironina (T3) e tiroxina (T4), oito bodes, das raças Saanen (n=4) e Alpina (n=4), foram mantidos em câmara bioclimática, sob condições de termoneutralidade (13,0ºC a 26,7ºC) durante 30 dias e, após um período (60 dias) de descanso, submetidos ao EC (23,7ºC a 34,0ºC) por 30 dias. Para minimizar as variações sazonais nos perfis hormonais devido ao fotoperíodo, durante toda fase experimental, incluindo a de adaptação em condições de termoneutralidade (30 dias), o fotoperíodo foi controlado utilizando-se alternância de dias longos (16h de luz e 8h de escuro) e de dias curtos (8h de luz e 16h de escuro) a cada 30 dias. As amostras de sangue foram coletadas duas vezes por semana durante cinco semanas. No conjunto das raças, o EC não influenciou (P>0,05) as concentrações de testosterona (1,8±0,2 vs 1,3±0,2ng/ml) e nem a de T4 (52,7±2,8 vs 50,0±2,8ng/ml). Houve declínio (P<0,01) das concentrações de T3 nos animais submetidos ao experimento (1,3±0,1 vs 1,0±0,1ng/ml), mas a redução foi observada somente nos bodes Saanen. Em ambas as raças, as concentrações de T3 e T4 variaram (P<0,01) conforme o dia da coleta das amostras de sangue. O EC foi suficiente para produzir uma resposta fisiológica com redução das concentrações plasmáticas de T3 em bodes das raças Saanen, mas não da raça Alpina, assim como não foi capaz de alterar os níveis plasmáticos de testosterona e nem de T4.

An experimental study of the effect of two distinct surgical techniques of orchiopexy on spermatogenesis and testicular damage in cryptorchid testes

OBJECTIVE

To compare the effect of two different techniques of testicular fixation on testicular function.

DESIGN

Experimental study.

SETTING

Surgical animal laboratory at an academic medical center.

PATIENT(S)

Sixteen mature golden hamsters underwent classic transfixation orchiopexy and true dartos pouch orchiopexy.

INTERVENTION(S)

Classic transfixation orchiopexy (CTO) involved transfixation of the testicular wall at two different points and fixation of the dartos fascia. True dartos pouch orchiopexy (TDPO) involved creating a window in the dartos fascia, passage of the testicle, and closure of the window from both sides of the testicle.

MAIN OUTCOME MEASURE(S)

Flow cytometric separation of testicular cells into haploid, diploid, and tetraploid fractions for histogram analysis.

RESULT(S)

A significant decrease in testicular weight was observed in 6 out of 16 animals undergoing CTO. Diploid cells comprised the main cell fraction, and almost no haploid or tetraploid cells were observed, while in the 16 animals undergoing TDPO no change from the control pattern was observed.

CONCLUSION(S)

This experimental work supports our clinical impression that TDPO should replace CTO as the method of choice for the treatment of an undescended testicle in children.

Flow cytometry of human semen: a preliminary study of a non-invasive method for the detection of spermatogenetic defects

BACKGROUND

The pathway of spermatogenesis involves the conversion of diploid stem cells (spermatogonia) to tetraploid primary spermatocytes, followed by meiosis and two cell divisions, first forming diploid secondary spermatocytes and then haploid round spermatids. Differentiation of round spermatids results in spermatozoa containing condensed chromatin. It has long been known that semen from patients with non-obstructive azoospermia or oligospermia contains small numbers of immature germinal cells. In this article, a flow cytometric procedure is described for assessing defects in spermatogenesis by identifying the ploidy of those immature cells.

METHODS

Cells in semen samples from 44 infertile patients and 14 controls were stained with propidium iodide, which displays red fluorescence when intercalated between bases in double-stranded DNA. The resulting cell suspension was examined by quantitative flow cytometry, with excitation by laser light (488 nm) and red fluorescence recorded on a logarithmic scale to allow easy differentiation between intensities of tetraploid, diploid and haploid round spermatids, and spermatozoa containing condensed chromatin.

RESULTS

The flow cytometric method differentiated between cases of 'Sertoli cell-only' syndrome (complete absence of tetraploid and haploid cells) and cases where spermatogenesis was blocked in meiosis or in spermiogenesis. Flow cytometric histograms from semen samples from normozoospermic, oligozoospermic and azoospermic patients fell into patterns that correlated well with the results obtained from testis histology findings.

CONCLUSIONS

The method described may serve as a simple, non-invasive and reliable assay to help clinicians counsel patients with severe male infertility before referring them for testicular surgery to locate spermatozoa for ICSI.

Apoptosis and cell removal in the cryptorchid rat testis

In order to determine that apoptosis is responsible for large-scale germ cell elimination, we analyzed cells from cryptorchid testes both in histological sections and among those isolated in vitro. Apoptotic testicular cells during 3 to 7 days were only 8 to 30%, reaching a maximum of 80% by the end of 15 days of cryptorchidism. A similar trend was also observed with the number of dead cells. The process of large-scale germ cell removal in the initial stages was facilitated by the formation of multinucleated giant cells, which stained negative for apoptosis. Increase in oxidative stress and decrease in intratesticular testosterone was also observed. The above findings indicate that large-scale germ cell removal, at least during initial stages of cryptorchidism is not solely as a result of apoptosis. Declined intra testicular testosterone, elevated temperature and high oxidative stress following cryptorchidism probably affect cell viability and trigger a fast pace cell removal through giant cell formation.