Role of glyoxalase I and II in somatic and spermatogenic testicular cells during the postnatal development of the domestic cat

Like humans, many felid species suffer from teratozoospermia and frequently produce low numbers of normal spermatozoa. Male fertility can be affected by oxidative and dicarbonyl stress. Because of the high level of glycolytic activity in testes, reactive dicarbonyl metabolites may arise as side-products of glycolysis; their generation is further promoted by oxidative stress. Alpha-oxoaldehydes, including methylglyoxal (MG), are reactive dicarbonyl metabolites and substrates for the formation of advanced glycation end products. Elevated levels of both may lead to dicarbonyl stress and cause cellular dysfunction. However, MG and other α-oxoaldehydes can be converted to less dangerous molecules via the glyoxalase pathway. In this pathway, α-oxoaldehydes react with glutathione (GSH), forming a thioacetal, which becomes metabolized by glyoxalase I (GLO I) to S-D-lactoyl-glutathione (SLG). Glyoxalase II (GLO II) converts SLG to d-lactate upon the release of GSH. Nothing is known about the glyoxalase system in the feline testis and its capacity to mitigate an excess of dicarbonyl metabolites. To study whether GLO I and GLO II are present and have a specific function in the testis of the domestic cat, the gene expression of both enzymes were analyzed in testis samples of different developmental stages (prepubertal, pubertal, postpubertal). Furthermore, the presence of GLO I and GLO II proteins was investigated via immunohistochemistry. The GLO I gene expression does not change between developmental stages. Immunohistochemistry revealed strong signals for GLO I in the cytoplasm and nuclei of Sertoli and Leydig cells during all developmental stages. GLO I was described as catalyzing the rate-limiting step in the glyoxalase pathway. This implies a function on the part of this enzyme of sustaining the homeostasis of somatic testicular cells. For GLO II, we observed stage-dependent mRNA expression, which was significantly increased after puberty. In accordance with this observation, clear immunohistochemical GLO II signals were observed in nuclei of individual germ cells. The most intense signals were visible in spermatocytes. The different localizations of the strong GLO I and GLO II signals indicate that GLO II, in addition to the classical glyoxalase pathway, may have additional functions in meiotic germ cells, for example, providing lactate as an energy substrate and/or GSH as an antioxidant. Moreover, protein functions may be modulated via S-glutathionylation.