Rodent epididymal cDNAs identified by sequence homology to human and canine counterparts

Aim: Identification of the rodent counterparts of human and canine epididymal cDNAs HE3, HE4 and CeS/Ly6G5C by sequence homology and analysis of their expression patterns and regulation level in the rat. Methods:“Electronic screening“ of Expressed Sequence Tag (EST) and genomic databases, followed by RT-PCR and Northern blot analysis. Results: Rodent ESTs and genomic sequences homologous to HE3, HE4 and CeS/Ly6G5C were identified in the public databases and the “full-length“ rat cDNAs cloned. To emphasise their homology to the human and canine genes, they were named Me3/Re3, Me4/Re4 and Re8 for mouse and rat counterparts, respectively, mRNA expression patterns were analysed in rats, including rat HE1 and HE5/CD52 counterparts as controls. Re3 and Re8 mRNAs were only found in the rat epididymis, while Re4 showed a broader tissue distribution. Within the epididymis,Re3 and Re4 mRNAs were detected in all regions; ReS, on the other hand, was restricted to the caput. During postnatal development, Re3 and control mRNAs were found from the earliest stages investigated, while Re8 mRNA was observed only from day 24 postnatum, corresponding to the onset of spermatogenesis in the prepubertal testis.Castration and testosterone supplementation of adult male rats suggested that none of the cloned mRNAs was directly androgen-regulated. Efferent duct ligation, however, showed that Re8 mRNA levels depended on testicular factors other than androgens. Conclusion: The novel rodent cDNAs can now be used to monitor epididymal gene expression more closely and to set up various regulatory and functional studies.     

Gene expression in the dog epididymis: a model for human epididymal function

The physiology of the epididymis is an integral part of the maturation process by which human spermatozoa acquire the abdity to reach and fertilize an oocyte. Because of the high degree of species specificity exhibited by the epididymal proteins involved in sperm maturation, we have assessed tissue from several alternative species for their suitability as a model for human epididymal physiology. Of these, the dog appears to offer an appropriate system. Northern hybridization using cDNA probes specific for human epidldymal genes established that, irrespective of dog breed, the canine equivalents of the epididymis-specific HE1, HE4 and HE5 mRNAs were expressed highly in the canine epididymis. cDNA cloning and sequencing confirmed that the canine gene products, CE1, CE4 and CE5 were indeed true structural homologues of their human counterparts. Finally, tissue culture conditions were established wherein all three specific canine genes remained up-regulated after 5 days of culture. Thus, the prerequisite criteria for the development of a system which models human epididymal physiology are to a large degree fulfilled by this canine culture system.     

Variable distribution of aminopeptidase A in male reproductive organs of mammals

Aminopeptidase A (AP-A) was analysed in the reproductive organs of the boar, bull, gerbil and man. High hydrolysis of alpha-L-glutamyl-beta-naphthylamide (GluNA) and alpha-L-aspartyl-beta-naphthylamide (AspNA) with activation by alkaline earth metals was detected in the ampulla, seminal vesicles, and seminal vesicle secretions of the bull and in the cauda epididymis of the boar and gerbil. In man, weak AP-A activity was found in all reproductive tissues. Histochemically, AP-A was localized in the epithelial cells of tissues having a high specific activity for the enzyme. AP-A was absent from human seminal fluid, whilst bovine seminal fluid had strong, and boar seminal fluid weaker, AP-A activity. Gel filtration of bull seminal vesicle secretions and seminal fluid, boar seminal fluid or an homogenate of boar and gerbil epididymal cauda and human epididymis and seminal vesicles on Sephacryl S-300 resulted in a major high-molecular-weight activity peak A at Ve/Vo = 1.17 and another low-molecular-weight peak B at Ve/Vo = 1.51 (man), 1.62 (boar, bull) or 1.75 (gerbil). This fractionation was not in all cases able to separate AP-A from aminopeptidase(s), which were active on L-alanine-beta-naphthylamide (AlaNA) but showed no activation by alkaline earth metals. Homogenates of bovine epididymis showed only the low-molecular-weight GluNA peak B, but two areas of activity for AlaNA hydrolysis. In bovine seminal vesicles and porcine epididymis, AP-A activity appeared to be linked with the functional maturity of these organs. The high-molecular-weight AP-A (peak A) appeared to be the predominant form in seminal fluid.     

Changes in the Acetylcholinesterase Activity of Mammalian Spermatozoa during Maturation

Acetylcholinesterase (AChE) activity of sperm recovered from the testes and several epididymal sites was studied in the boar, bull, and rat. AChE was highest in the bull spermatozoa followed by those of the rat and the boar. Between the testis and caput epididymis washed spermatozoa lost about 86% (bull), 60% (boar) or 32% (rat) in AChE activity while between the caput and cauda epididymides, a further loss of 28, 10, and 27% in the enzyme activity occurred in the respective species. Sperm AChE activity was negatively related to the development of sperm motility during sperm maturation and with sperm abnormality.     

附睾分泌蛋白2β1在青春期雄性大鼠睾丸和附睾中的表达

目的:探讨附睾分泌蛋白2(HE2/EP2)的一种异构体———HE2β1在青春期雄性大鼠睾丸和附睾中的表达及其意义。方法:应用免疫组化SP法检测15只青春期SD大鼠睾丸和附睾组织中HE2β1的定位及其表达情况。结果:HE2β1在青春期大鼠睾丸和附睾组织中均有表达。在附睾中,HE2β1主要表达于附睾管上皮主细胞胞质内,而在亮细胞、晕细胞及基细胞内未见阳性表达;其表达水平在附睾头部远段较弱,在体部近、中段及尾部较强,而在附睾始段未见阳性表达。在睾丸生精小管中,部分精原细胞核及支持细胞核均可见明显的棕褐色的阳性颗粒,其他生精细胞以及间质细胞均为阴性。结论:HE2β1在青春期雄性大鼠的睾丸和附睾上皮中均有表达,其定位及表达水平具有区域特异性和细胞特异性,提示其在大鼠精子发生、成熟及附睾上皮天然抗感染机制中发挥重要的作用。     

Glutathione, L-glutamic acid and γ-glutamyl transpeptidase in the bull reproductive tissues

The distribution of glutathione (GSH), L-glutamic acid (Glu) and gamma-glutamyl transpeptidase (gamma-GT) was studied in bull reproductive organs and fluids. Glutathione, the physiological substrate of gamma-GT, was localized specifically by a fluorescence method in the testis, epididymis and spermatozoa. Of the reproductive tissues, the testis, caput epididymis and ampulla had the highest levels of GSH, but it was also present in seminal fluid. Washed caput epididymal sperm had three times the GSH content of cauda epididymal or ejaculated sperm. In spermatozoa, GSH displayed maximal staining in the midpiece and tail regions. The highest levels of gamma-GT were encountered in the epididymis. The concentration of Glu was also high in the epididymis. Its formation may be due to the hydrolytic activity of gamma-GT, which, in addition, may have an important role in the transfer of Glu residues to reactive groups on the sperm surface.     

ConA-binding proteins of the sperm surface are conserved through evolution and in sperm maturation

Summary.  Lectin-binding glycoconjugates present on the surface of spermatozoa are believed to play a crucial role in sperm maturation, capacitation, acrosome reaction, or sperm-egg interaction. We have studied ConA-binding surface proteins on spermatozoa from different mammalian species. First, ConA-binding proteins were isolated from boar spermatozoa by affinity chromatography. ConA-binding ability was confirmed by Enzyme-linked Lectin assay (ELLA). Monoclonal (MAb436/10) and polyclonal antibodies were raised against chromatography fractions containing purified ConA-binding proteins of boar spermatozoa. MAb436/10 (IgG_2a) recognizes a 40 kD ConA-binding antigen. Indirect immunofluorescence on fixed and unfixed boar spermatozoa with MAb436/10 indicated a plasma membrane localization of antigen 436/10 in the acrosomal macrodomain. Interspecies cross-reactivity with MAb436/10 was found by whole cell ELISA and immunocytochemistry. MAb436/10 cross-reacted with human, horse, guinea-pig, bull, and ram spermatozoa in both assays. Expression of ConA-binding antigen 436/10 on guinea pig sperm surface was detectable during spermiogenesis and in early stages of sperm maturation. Change of regionalization of the antigen did not occur during the epididymal passage. ConA-binding antigen 436/10 was also detectable in testis and caudal segments of the epididymis. These findings suggest that ConA-binding proteins located in the acrosomal region are highly conserved through evolution as well as in sperm maturation indicating an important role for the physiology of spermatozoa.     

Monoclonal antibodies to epididymis-specific proteins using mice rendered immune tolerant to testicular proteins

Monoclonal antibodies (mabs) have been used as a powerful tool for identification of newer sperm proteins. However, conventional hybridoma technology rarely provides chance to obtain mabs to epididymal proteins. To increase this chance, we have used an alternate method of neonatal tolerization. In this protocol, animals were tolerized at birth using testicular proteins followed by immunization with cauda epididymal sperm protein (which is a cocktail of proteins both from testicular and epididymal origin). This protocol induced a specific immune response to epididymal sperm proteins. Spleen from one of these animals was then used for preparation of mabs. This fusion resulted in a number of mabs reacting specifically to epididymal proteins. Although mabs identified a protein of approximately similar molecular weight on 1-dimensional Western blot analysis, there were differences in regional localization on rat sperm as seen by indirect immunofluorescence. Immunohistochemical localization of these proteins in rat epididymis showed region specific synthesis. The synthesis of proteins was seen in the distal caput epididymis, and maximum expression was seen in supranuclear region of corpus epithelium. The proteins were localized on sperm from corpus and cauda region. Epididymis specific synthesis of the proteins and agglutinating nature of the mabs to these underlines the functional importance of these proteins in sperm maturation in epididymis. These antibodies could therefore, be used as tools for understanding the physiology of maturation of sperm in epididymis and role of the epididymal protein in fertilization.     

Cloning and characterization of an androgen-dependent acidic epididymal glycoprotein/CRISP1-like protein from the monkey.

A cDNA encoding an acidic epididymal glycoprotein (AEG)-like, CRISP1 (cysteine-rich secretory protein) protein from the monkey (Macaca mullata) epididymis has been cloned and sequenced. The monkey AEG (mAEG) has an open reading frame that encodes a protein containing 249 amino acids with a deduced molecular mass of 28 kDa. The mAEG protein sequence is 85% identical to human and 44% identical to mouse CRISP1, including all 16 conserved cysteine residues. mAEG also shows a significant amino acid homology with other CRISP proteins, rat AEG/DE, human TPX1/CRISP2, and guinea pig acrosomal autoantigen 1 (AA1). In addition, mAEG shows somewhat less homology to a toxin from the Mexican beaded lizard and to a human glioma pathogenesis-related protein. Northern blot analysis shows that the mRNA for mAEG is expressed in all the regions of the epididymis except the caput and was not detected in the testis, prostate, seminal vesicle, and brain. In castrated animals, mAEG gene expression in the epididymis is significantly diminished; however, testosterone enanthate replacement restored the normal level of expression, demonstrating that expression of mAEG is androgen dependent. Western blot analysis of monkey epididymal regions using mouse antirecombinant human AEG identified a 28-kDa protein only in the caudal region. Immunohistochemical analysis identified mAEG only in the principal cells of the cauda epididymal epithelium. Immunofluorescence analysis identified mAEG on the principal piece of the sperm tail and as small patches over the middle piece and head regions. The results described in the present study suggest that mAEG (CRISP1) is secreted in the monkey epididymis, regulated by androgens and present on epididymal spermatozoa.