The expression of the new epididymal luminal protein of PDZ domain containing 1 is decreased in asthenozoospermia.

Spermatozoa are not mature until they transit the epididymis where they acquire motility and the ability to fertilize an egg through sequential modifications. The epididymis has three functional regions, caput, corpus, and cauda, and the luminal proteins of the epididymis play important roles in the above modifications. However, the proteins with differential enrichment between the caput and cauda are still largely unknown. To reveal the functions of the caput and cauda during sperm maturation, luminal proteins from caput and cauda of mice were analyzed by isobaric tag for relative and absolute quantitation (iTRAQ). Overall, 128 differentially enriched proteins were found, of which 46 were caput enriched and 82 were cauda enriched. Bioinformatic analysis showed that lipid metabolism was active in the caput; while anion- and cation-binding activity and phosphorus and organophosphate metabolism were active in the cauda. A new epididymal luminal protein, the caput-enriched PDZ domain containing 1 (Pdzk1), also named Na+/H+ exchange regulatory cofactor 3 (NHERF3), which plays a critical role in cholesterol metabolism and carnitine transport, was found in the lipid metabolism. Western blotting and immunofluorescence analyses showed that Pdzk1 was expressed in the epididymis but not in the testis, and localized at the middle piece of the sperm tail. Pdzk1 protein level was also reduced in the spermatozoa in case of asthenozoospermic patients compared with that in normozoospermic men, suggesting that Pdzk1 may participate in sperm maturation regulation and may be associated with male infertility. These results may provide new insights into the mechanisms of sperm maturation and male infertility.

Androgenic regulation of beta-defensins in the mouse epididymis.

BACKGROUND: The majority of beta-defensin family members are exclusively expressed in the epididymis, and some members have been shown to play essential roles in sperm maturation and fertility in rats, mice and humans. Therefore, beta-defensins are hypothesized to be potential targets for contraception and infertility diagnosis and treatment. Clarifying the regulatory mechanisms for the expression of these genes is necessary. Androgen/androgen receptor (AR) signaling plays an important regulatory role in epididymal structure and function. However, very little is known about the androgenic regulation on the production and secretion of the epididymal beta-defensins. METHODS: The expression of beta-defensins was detected by quantitative RT-PCR. The androgen dependence of beta-defensins was determined by bilateral orchiectomy and androgen supplementation. The androgen response elements (AREs) in the promoters of beta-defensins were identified using the MatInspector software. The binding of AR to AREs was assayed by ChIP-PCR/qPCR. RESULTS: We demonstrated that 23 mouse caput epididymal beta-defensins were differentially regulated by androgen/androgen receptor. Six genes, Defb18, 19, 20, 39, 41, and 42, showed full regulation by androgens. Ten genes, Defb15, 30, 34, 37, 40, 45, 51, 52, 22 and Spag11a, were partially regulated by androgens. Defb15, 18, 19, 20, 30, 34, 37, 39, 41, 42, 22 and Spag11a were associated with androgen receptor binding sites in their promoter or intronic regions, indicating direct regulation of AR. Six genes, Defb1, 12, 13, 29, 35, and spag11b/c, exhibited an androgen-independent expression pattern. One gene, Defb25, was highly dependent on testicular factors rather on androgens. CONCLUSIONS: The present study provides novel insights into the mechanisms of androgen regulation on epididymal beta-defensins, enabling a better understanding of the function of beta-defensins in sperm maturation and fertility.

[Androgen/androgen receptor directly regulates the expression of Caveolin-1 in mouse epididymides].

OBJECTIVE: To investigate the mechanisms of androgen/androgen receptor (AR) regulating the expression of Caveolin-1 in the mouse epididymis. METHODS: The AR binding sites associated with the Caveolin-1 gene were identified by searching the database of genomewide AR binding sites in mouse epididymides obtained from chromatin immunoprecipitation-sequencing (ChIP-seq). Total RNA was extracted from the epididymal tissues of normal and castrated mice and those castrated but supplemented with testosterone propionate, and the expression of Caveolin-1 mRNA was detected by RT-PCR and RT-qPCR. ChIP was performed with AR antibodies, and ChIP-PCR and ChIP-qPCR were used to determine the in vivo AR occupancies on the two sites associated with Caveolin-1. RESULTS: Two AR binding sites associated with Caveolin-1 were found in the database, both located in the second intron region. After castration, the expression of Caveolin-1 was significantly increased, 1.8 +/- 0.17 times that of the control group (P < 0.05), and the fold enrichments of the two AR binding sites were dramatically reduced from 13.5 +/- 1.47 and 10.5 +/- 1.03 to 1.05 +/- 0.17 and 1.4 +/- 0.14, respectively (P < 0.01). After androgen supplement, however, the expression of Caveolin-1 was decreased to normal (P < 0.05), and the fold enrichments of the two AR binding sites significantly increased to 16.4 +/- 2.6 and 10 +/- 0.92, respectively (P < 0.01). CONCLUSION: Caveolin-1 is a bona fide AR direct target gene in the mouse epididymis, and its expression is negatively regulated by androgen. These findings have provided a new insight into the androgen/AR regulatory network in mouse epididymides.

Different effects of androgen on the expression of Fut1, Fut2, Fut4 and Fut9 in male mouse reproductive tract.

The α-(1,2) fucosyltransferases (Fut1 and Fut2) and α-(1,3) fucosyltransferases (Fut4, Fut9) are responsible for the synthesis of Lewis X (LeX) and Lewis Y (LeY) conjugated to glycoproteins. We recently reported that these fucosyltransferases were differentially expressed in the reproductive tract of male mouse. Here, we studied the effect of androgen on fucosyltransferase expression through the use of mouse castration models. We found that Fut1 mRNA and Fut4 mRNA were upregulated, while Fut2 mRNA and Fut9 mRNA were downregulated by androgen in the caput epididymis. However, in the vas deferens and prostate, only Fut4 mRNA and Fut2 mRNA were respectively upregulated following exposure to androgen. In the seminal vesicle, all fucosyltransferases, with the exception of Fut9, were upregulated. We identified the androgen receptor binding sites (ARBSs) of Fut2, Fut4 and Fut9 in the caput epididymis. Luciferase assay for these ARBSs is able to provide an indication as to why Fut4 and Fut9 are differently expressed and regulated by androgen, although they catalyze the same α-(1,3) fucose linkage. Our study showed that androgen could differentially regulate the expression of these fucosyltransferases and provided an insight into the characteristic distribution of each fucosyltransferase responsible for LeX/LeY biosynthesis in the male reproductive tract.

Molecular cloning and identification of mouse epididymis-specific gene mHong1, the homologue of rat HongrES1.

Previous studies have shown that rat epididymis-specific gene HongrES1 plays important roles in sperm capacitation and fertility. In this study, we cloned the mouse homologue gene by sequence alignment and RT-PCR methods and designated it as mHong1. The mHong1 gene is located on chromosome 12p14, spanning five exons. The cDNA sequence consists of 1257 nucleotides and encodes a 419 amino-acid protein with a predicted N-terminal signal peptide of 20 amino acids. The mHong1 mRNA shows similarity with HongrES1 in the expression patterns: (i) specific expression in epididymal tissue, especially in the cauda region; and (ii) androgen-dependence but testicular fluid factor independence. Its protein product shows 71% similarity with HongrES1 and contains a classical serpin domain as does HongrES1. A polyclonal antibody against mHong1 with high specificity and sensitivity was raised. Like HongrES1, the mHong1 protein shows a checker-board expression pattern in the epididymal epithelium and is secreted into the epididymal lumen. The mHong1 protein shows higher glycosylation than HongrES1. Although both of them are deposited onto the sperm head surface, mHong1 is localized to the equatorial segment, which is different from that of HongrES1. The mHong1 protein can be removed from the sperm membrane by high ionic strength and therefore can be classed as an extrinsic membrane protein. Collectively, we conclude that mHong1 is the homologue of HongrES1 and the present work paves the way for establishing animal models to elucidate the precise functions of HongrES1 and mHong1.