Structure and expression of the rat epididymal secretory protein I gene. An androgen-regulated member of the lipocalin superfamily with a rare splice donor site

Distinct actions of testicular endocrine and lumicrine signaling on the proximal epididymal transcriptome

The epididymal function and gene expression in mammals are under the control of the testis. Sex steroids are secreted from the testis and act on the epididymis in an endocrine manner. There is another, non-sex steroidal secreted signaling, named lumicrine signaling, in which testis-derived secreted proteins go through the male reproductive tract and act on the epididymis. The effects of such multiple regulations on the epididymis by the testis have been investigated for many genes. The recent development of high-throughput next-generation sequencing now enables us a further comparative survey of endocrine and lumicrine action-dependent gene expression. In the present study, testis-derived endocrine and lumicrine actions on epididymal gene expression were comparatively investigated by RNA-seq transcriptomic analyses. This investigation utilized experimental animal models in which testis-derived endocrine and/or lumicrine actions were interfered with, such as unilateral or bilateral orchidectomy. By bilateral orchidectomy, which interferes with both endocrine and lumicrine actions, 431 genes were downregulated. By unilateral orchidectomy, which also interferes with endocrine and lumicrine actions by the unilateral testis, but the endocrine action was compensated by the contralateral testis, 283 genes were downregulated. The content of such genes downregulated by unilateral orchidectomy was like those of lumicrine action-interfered efferent duct-ligation, W/Wv, and Nell2-/- mice. When genes affected by unilateral and bilateral orchidectomy were compared, 154 genes were commonly downregulated, whereas 217 genes were specifically downregulated only by bilateral orchidectomy, indicating the distinction between endocrine and lumicrine actions on the proximal epididymal transcriptome. Comparative transcriptome analyses also showed that the expressions of genes emerging since Amniota were notably impacted by bilateral orchidectomy, unilateral orchidectomy, and lumicrine action-interfering treatments; the degree of influence from these treatments varied based on the evolutionary stage beyond Amniota. These findings unveil an evolutional transition of regulated gene expression in the proximal epididymis by two different testis-derived signaling mechanisms.

Busulfan administration replicated the characteristics of the epididymal initial segment observed in mice lacking testis-epididymis lumicrine signaling

The physiological functions of the mammalian epididymis are typically regulated by the testes. In addition to sex steroids secreted by testicular Leydig cells, which act on the epididymis in an endocrine manner, there is a non-sex-steroidal signaling pathway known as the lumicrine pathway. This lumicrine signaling pathway involves ligand proteins secreted from germ cells within the testicular seminiferous tubules traversing the male reproductive tract, which induce epithelial differentiation in the epididymis. These findings prompted an inquiry into whether treatments influencing testis physiology can disrupt epididymal function by interfering with testis-epididymis communication. Busulfan, an alkylating agent commonly used to deplete testicular germ cells in reproductive biology, has not been sufficiently explored because of its effects on the epididymis. This study investigated the effects of busulfan administration on the proximal epididymis using histological and transcriptomic analyses. Notably, busulfan, as opposed to the vehicle dimethyl sulfoxide (DMSO), altered the morphology of the initial segment of the epididymis, leading to a reduction in the cell height of the luminal epithelium. RNA sequencing identified 185 significantly downregulated genes in the proximal epididymis of busulfan-administered mice compared to DMSO-administered mice. Comparative transcriptome analyses revealed similarities between the epididymal transcriptome of busulfan-administered mice and lumicrine-deficient mice, such as efferent-duct-ligated W/Wv and Nell2-/- mice. However, this differed from that of bilaterally orchidectomized mice, in which both the endocrine and lumicrine signaling pathways were simultaneously ablated. Collectively, these results suggested that the harmful effects of busulfan on the proximal epididymis are secondary consequences of the ablation of testis-epididymis lumicrine signaling.

The epididymal influence on sperm maturation

Consideration of the function of the epididymis has undergone profound changes over the last century during which it has moved from a largely neglected male reproductive organ to one that is an increasingly exploited source of sperm for assisted reproduction strategies. From histological studies in the lizard1 it was considered that, ‘…the cells lining the epididymal canal produce a material necessary for the spermatozoa during their passage through the organ …’ whereas a fertility study with guinea-pigs stated boldly that, ‘… changes undergone [by spermatozoa in the epididymis] are not conditioned by some specific action of epididymal secretion …’. The former view found favour in a review of the literature which concluded that, ‘… there are specific epididymal secretions necessary for sperm maturation and survival …’, although the nature of the secretions were not then known. However, this concept, currently held by most of those studying the epididymis of animals, was again contradicted on the basis of clinical work: ‘… it certainly is possible for sperm that have never passed through any length of the epididymis at all to mature on their own …’.

Epididymis-specific lipocalin promoters

Our goal is to decipher which DNA sequences are required for tissue-specific expression of epididymal genes. At least 6 epididymis-specific lipocalin genes are known. These are differently regulated and regionalized in the epididymis. Lipocalin 5 (Lcn5 or mE-RABP) and Lipocalin 8 (Lcn8 or mEP17) are homologous genes belonging to the epididymis-specific lipocalin gene cluster. Both the 5 kb promoter fragment of the Lcn5 gene and the 5.3 kb promoter fragment of the Lcn8 gene can direct transgene expression in the epididymis (Lcn5 to the distal caput and Lcn8 to the initial segment), indicating that these promoter fragments contain important cis-regulatory element(s) for epididymis-specific gene expression. To define further the fragments regulating gene expression, the Lcn5 promoter was examined in transgenic mice and immortalized epididymal cell lines. After serial deletion, the 1.8 kb promoter fragment of the Lcn5 gene was sufficient for tissue-specific and region-specific gene expression in transgenic mice. Transient transfection analysis revealed that a transcription factor forkhead box A2 (Foxa2) interacts with androgen receptor and binds to the 100 bp fragment of the Lcn5 promoter between 1.2 kb and 1.3 kb and that Foxa2 expression inhibits androgen-dependent induction of the Lcn5 promoter activity. Immunohistochemistry indicated a restricted expression of Foxa2 in the epididymis where endogenous Lcn5 gene expression is suppressed and that the Foxa2 inhibition of the Lcn5 promoter is consistent with the lack of expression of Lcn5 in the corpus and cauda. Our approach provides a basic strategy for further analysis of the epididymal lipocalin gene regulation and flexible control of epididymal function.

Epididymis-specific promoter-driven gene targeting: a transcription factor which regulates epididymis-specific gene expression

Mammalian spermatozoa undergo several modification and finally acquire the ability to fertilize during epididymal transit. One of the distinct features of the epididymis is that it displays a highly regionalized pattern of gene expression. This tissue-, region-, and cell-specific pattern of gene expression is critical for the maintenance of a fully functional epididymis. One would hypothesize that disrupting this process provides an ideal approach to male contraception, since it would not interfere with testicular endocrine output or sperm production. To achieve this purpose, we studied a cluster of epididymis-specific lipocalin genes for understanding the specific mechanisms involved in the control of gene expression in the epididymis. We have identified six epididymis-specific lipocalin genes that are differently regulated and regionalized in the epididymis. Lipocalin 5 [Lcn5 or epididymal retinoic acid-binding protein (E-RABP)] is a member of this epididymis-specific lipocalin gene cluster, which binds hydrophobic molecules such as retinoic acid. We have previously shown that the 5kb promoter fragment of the Lcn5 gene confers both androgen-dependent regulation and epididymis-specific gene expression in transgenic mice whereas 0.6 kb promoter fragment does not. To further narrow down the important cis-regulatory elements that regulate gene expression in the epididymis, we studied the Lcn5 promoter in both transgenic mice and immortalized epididymal cells. We have found that 1.8kb promoter fragment of the Lcn5 gene was sufficient for tissue- and region-specific expression in transgenic mice, and that a transcription factor Forkhead box A2 (Foxa2) interacts with the androgen receptor and binds to the 100 bp fragment of the Lcn5 promoter between 1.2 and 1.3 kb. Our finding provides a framework for further analysis of the epididymal lipocalin gene regulation and modulated control of epididymis-specific expression.

Immunolocalization and Regulation of Cystatin 12 in Mouse Testis and Epididymis1

In previous studies, we identified a new member of the male reproductive tract subgroup within family 2 cystatins, termed cystatin 12 (Cst12, previously known as Cst TE-1 or Cres3). The mouse Cst12 mRNA was primarily localized to the Sertoli cells in the testis and to the epithelial cells of the proximal caput region of the epididymis. In this report, studies were carried out to characterize the cystatin 12 (CST12) protein in mouse testis and epididymis. A recombinant His-CST12 fusion protein was expressed in E. coli and purified to generate an anti-CST12 polyclonal antibody. Western blot analysis showed little or no cross-reaction between the anti-CST12 antibody and several other known male reproductive tract cystatins. Immunohistochemistry revealed that CST12 protein was predominantly localized to the cytoplasm of Sertoli cells in the seminiferous epithelium in a stage-dependent manner. All stages showed high levels of expression except stages VII and VIII, in which very limited expression of CST12 was observed. In the epididymis, CST12 was highly expressed in the cytoplasm of the epithelial cells in the proximal caput and secreted into the lumen. The mouse CST12 protein was also detected in other regions of the epididymis; however, the localization varied greatly along the epididymal tubules. Indirect immunofluorescence showed that CST12 protein was localized to the cytoplasmic droplets in both testicular and epididymal spermatozoa. These observations suggest that CST12 protein may play a specialized role during spermatogenesis and sperm maturation. Northern blot analyses demonstrated that Cst12 transcript levels in the epididymis decreased after castration, and testosterone propionate (T) treatment further repressed the expression of this gene. However, 17-beta estradiol (E) administration maintained the expression of Cst12 mRNA after castration, whereas treatment with both T and E failed to maintain Cst12 mRNA levels in epididymis. These results suggest that androgen and estrogen, probably with other testicular factors, are involved in the regulation of this gene.

Pem homeobox gene regulatory sequences that direct androgen-dependent developmentally regulated gene expression in different subregions of the epididymis

The epididymis is a useful model system to understand the mechanisms that govern region-specific gene expression, as many gene products display spatially restricted expression within this organ. However, surprisingly little is known about how this regulation is achieved. Here, we report regulatory sequences from the Pem homeobox gene that drive expression in different subregions of the mouse epididymis in vivo. We found that the 0.3-kb 5'-flanking sequence (region I) from the Pem proximal promoter (Pem Pp) was sufficient to confer androgen-dependent and developmentally regulated expression in the caput region of the epididymis. Expression was restricted to the normal regions of expression of Pem in the caput (segments 2-4), but there was also aberrant expression in the corpus region. This corpus misexpression was extinguished when 0.6 kb of Pem Pp 5'-flanking sequence was included in the transgene, indicating that one or more negative regulatory elements exist between 0.6 and 0.3 kb upstream of the Pem Pp start site (region II). When heterologous sequences were introduced upstream of the Pem Pp, expression was further restricted, mainly to caput segment 3, implying that the Pem Pp has segment-specific regulatory elements. To our knowledge, the regulatory regions we have identified are the shortest so far defined that dictate regionally localized expression in the epididymis in vivo. They may be useful for identifying the factors that regulate region-specific expression in the epididymis, for expressing and conditionally knocking out genes in different subregions of the epididymis, for treating male infertility, and for generating novel methods of male contraception.

The transfer of transthyretin and receptor-binding properties from the plasma retinol-binding protein to the epididymal retinoic acid-binding protein

Members of the lipocalin superfamily share a common structural fold, but differ from each other with respect to the molecules with which they interact. They all contain eight beta-strands (A-H) that fold to form a well-defined beta-barrel, which harbours a binding pocket for hydrophobic ligands. These strands are connected by loops that vary in size and structure and make up the closed and open ends of the pocket. In addition to binding ligands, some members of the family interact with other macromolecules, the specificity of which is thought to be associated with the variable loop regions. Here, we have investigated whether the macromolecular-recognition properties can be transferred from one member of the family to another. For this, we chose the prototypical lipocalin, the plasma retinol-binding protein (RBP) and its close structural homologue the epididymal retinoic acid-binding protein (ERABP). RBP exhibits three molecular-recognition properties: it binds to retinol, to transthyretin (TTR) and to a cell-surface receptor. ERABP binds retinoic acid, but whether it interacts with other macromolecules is not known. Here, we show that ERABP does not bind to TTR and the RBP receptor, but when the loops of RBP near the open end of the pocket (L-1, L-2 and L-3, connecting beta-strands A-B, C-D and E-F, respectively) were substituted into the corresponding regions of ERABP, the resulting chimaera acquired the ability to bind TTR and the receptor. L-2 and L-3 were found to be the major determinants of the receptor- and TTR-binding specificities respectively. Thus we demonstrate that lipocalins serve as excellent scaffolds for engineering novel biological functions.

Epididymal specificity and androgen regulation of rat EP2

In primates, expression of the EP2 gene is androgen-dependent and epididymis-specific. EP2 mRNA expression was investigated in caput, corpus, and cauda regions of rat epididymis and in 15 other rat tissues. Polymerase chain reaction and Northern analyses showed that rat EP2 is expressed predominantly in the proximal caput epididymidis. EP2 mRNA expression was determined in proximal epididymides from castrated, sham-operated, and efferent duct-ligated rats. In castrated rats, EP2 mRNA decreased to <10% of that in sham-operated rats between Days 3 and 4 postcastration, demonstrating the androgen dependence of EP2 expression. In epididymides ligated unilaterally at the efferent ducts, EP2 mRNA levels were approximately equal to those in the unligated contralateral epididymides or in sham-operated rats, indicating that EP2 expression does not depend on testicular factors. In bilaterally castrated rats, immediate and delayed testosterone replacement showed the dependence of EP2 expression on circulating androgens. Injection of testosterone propionate (TP) on Days 0, 1, 2, and 3 postcastration maintained EP2 mRNA levels approximately equal to those in sham-operated rats. Starting at Day 4 postcastration, daily injection of TP for 7 days restored EP2 mRNA to approximately normal levels. These data indicate for the rat that EP2 is expressed specifically in the proximal caput epididymidis and that its expression depends on circulating androgens but not on testicular factors.

Gene duplication gives rise to a new 17-kilodalton lipocalin that shows epididymal region-specific expression and testicular factor(s) regulation

Using transgenic mice, we have recently shown that 5 kb of the 5'-flanking region of the mouse epididymal retinoic acid-binding protein (mE-RABP) gene contains all of the information required for spatial and temporal gene expression in the epididymis. To identify the important cis-DNA regulatory element(s) involved in the tissue-, region-, and cell-specific expression of the mE-RABP gene, the 5-kb DNA fragment was sequenced. A computer analysis of the nucleotide sequence showed the presence of a new gene located 1.7 kb upstream from the mE-RABP gene transcription initiation site. The analysis of the open reading frame showed that the new gene encoded a putative 17-kDa lipocalin (named mEP17) related to mE-RABP. A 600-bp complementary DNA encoding mEP17 was cloned by rapid amplification of 3'-cDNA ends from epididymal total RNA. Two mEP17 RNA species (1 and 3.1 kb in size) were detected by Northern blot in the epididymis, but not in other tissues tested. In situ hybridization analyses showed that, unlike mE-RABP messenger RNA (mRNA), which is expressed in the distal caput epididymidis, mEP17 mRNA was detected only in the principal cells of the initial segment. The spatial expression and homology with mE-RABP suggest that mEP17 may act as a retinoid carrier protein within the epididymis. mEP17 mRNA expression disappeared 5 days postcastration. Four days after unilateral castration, mEP17 mRNA had nearly disappeared in the epididymis from the castrated side, but not from the intact side. In addition, testosterone replacement to bilaterally castrated mice failed to restore gene expression. We conclude that mEP17 gene expression is dependent on testicular factors circulating in the luminal fluid. Together our results suggest that mE-RABP and mEP17 genes were generated by duplication and that evolution led to a different region-specific gene expression and regulation in the epididymis.

Molecular cloning, expression, functional characterization, chromosomal localization, and gene structure of junctate, a novel integral calcium binding protein of sarco(endo)plasmic reticulum membrane

Screening a cDNA library from human skeletal muscle and cardiac muscle with a cDNA probe derived from junctin led to the isolation of two groups of cDNA clones. The first group displayed a deduced amino acid sequence that is 84% identical to that of dog heart junctin, whereas the second group had a single open reading frame that encoded a polypeptide with a predicted mass of 33 kDa, whose first 78 NH(2)-terminal residues are identical to junctin whereas its COOH terminus domain is identical to aspartyl beta-hydroxylase, a member of the alpha-ketoglutarate-dependent dioxygenase family. We named the latter amino acid sequence junctate. Northern blot analysis indicates that junctate is expressed in a variety of human tissues including heart, pancreas, brain, lung, liver, kidney, and skeletal muscle. Fluorescence in situ hybridization analysis revealed that the genetic loci of junctin and junctate map to the same cytogenetic band on human chromosome 8. Analysis of intron/exon boundaries of the genomic BAC clones demonstrate that junctin, junctate, and aspartyl beta-hydroxylase result from alternative splicing of the same gene. The predicted lumenal portion of junctate is enriched in negatively charged residues and is able to bind calcium. Scatchard analysis of equilibrium (45)Ca(2+) binding in the presence of a physiological concentration of KCl demonstrate that junctate binds 21.0 mol of Ca(2+)/mol protein with a k(D) of 217 +/- 20 microm (n = 5). Tagging recombinant junctate with green fluorescent protein and expressing the chimeric polypeptide in COS-7-transfected cells indicates that junctate is located in endoplasmic reticulum membranes and that its presence increases the peak amplitude and transient calcium released by activation of surface membrane receptors coupled to InsP(3) receptor activation. Our study shows that alternative splicing of the same gene generates the following functionally distinct proteins: an enzyme (aspartyl beta-hydroxylase), a structural protein of SR (junctin), and a membrane-bound calcium binding protein (junctate).

Characterization of an androgen-specific response region within the 5' flanking region of the murine epididymal retinoic acid binding protein gene

The epididymis provides the optimal milieu for sperm maturation and storage. Epididymal secretory proteins are believed to be involved in that process. Androgens are the major endocrine and paracrine regulatory signals that regulate gene expression in the epididymis. We have previously identified an androgen-dependent retinoic acid-binding protein (mE-RABP) that is secreted into the luminal fluid from the mouse mid/distal caput epididymidis. The mE-RABP protein belongs to the lipocalin superfamily and may be involved in the trafficking of retinoic acid within the epididymis. We have recently demonstrated that 5 kilobases of the 5' flanking region of the mE-RABP gene contained all the information for the hormonal regulation and the tissue-, region-, and cell-specific expression of the mE-RABP gene. In this study, we have identified a complex androgen-specific response region (ARR) within the first 600 base pairs of the mE-RABP gene promoter. Androgen (DHT) but not glucocorticoid (DEX) activates the ARR in HeLa and PC-3 cells. Two androgen receptor binding sites have been located at positions -445/-459 and -102/-88 and were named ARBS-1 and ARBS-0, respectively. Point mutations of ARBS-0 resulted in a slight decrease of the androgen response. However, mutations of ARBS-1 led to a total loss of the androgen responsiveness, suggesting that it was a major cis-acting element. When ARBS-1 is isolated from its promoter context, it serves as a weak androgen-responsive element that was activated by both androgens and glucocorticoids. Also, the -543/-88 DNA promoter fragment behaved as a poor androgen-responsive region, suggesting that regulatory elements located within the proximal mE-RABP promoter were required for a full androgen response. In conclusion, the mE-RABP ARR is a good model for the study of molecular mechanisms that lead to an androgen-specific responsiveness in vivo.

Chromosomal location, exon/intron organization and evolution of lipocalin genes

Lipocalins exhibit low sequence similarity that contrasts with a tightly conserved folding shared by all members of this superfamily. This conserved folding can be, at least partly, accounted for by a highly conserved gene structure. The array of lipocalin genes that have so far been studied mostly in mammals indicate a large conservation of a typical seven exon/six intron arrangement. Other conserved features include a partly coding exon 1 of variable size, fixed sizes of exons 2-5 that code for an array of lipocalin-specific beta-strands and a tendency of the last exons to either fuse or expand into further exons without major changes in the length of the resulting open reading frame. The conserved exon/intron arrangement as well as a clustering of most lipocalin genes in given chromosomes of human and mouse indicate that the lipocalin genes diverged from a shared ancestor by successive rounds of duplications followed by late changes in exon arrangements.

The novel epididymal secretory protein ESP13.2 in Macaca fascicularis

Newly synthesized mammalian spermatozoa undergo critical modifications as they pass along the epididymis. The modifications endow spermatozoa with fertilizing ability and occur largely as a consequence of epididymal gene expression. With this in mind, we here employed a cDNA cloning strategy designed to identify key epididymal gene products. We describe a novel cynomolgus monkey (Macaca fascicularis) epididymal transcript designated cy-ESP13.2, of 690 nucleotides. The putative human ortholog was cloned and is highly conserved. Both cDNA sequences predict small, secretory proteins with a disulfide-stabilized core. Anti-peptide polyclonal antibodies were raised to a predicted cy-ESP13.2 surface loop. Western blotting with these antibodies revealed high-level, epididymis-specific expression of cy-ESP13.2, consistent with the pattern of cy-ESP13.2 mRNA expression assessed by Northern blotting. cy-ESP13.2 protein was of 30 kDa and was readily detectable in epithelial cells lining the efferent ductules, initial segment, and cauda regions of the epididymis, but not on spermatozoa. Similarities to members of the four-disulfide-core family suggest clues to ESP13.2 function.

Gene expression in the epididymis

The epididymis is a tubular organ exhibiting vectorial functions of sperm concentration, maturation, transport, and storage. The molecular basis for these functions is poorly understood. However, it has become increasingly clear that regional differences along the length of the duct play a role in epididymal physiology and that region-specific gene expression is involved in the formation of these differences. Although not an overtly segmented organ, the epididymis consists of a series of highly coiled "zones," separated by connective tissue septulae and distinct by cell morphology and their pattern of gene expression. Thus, it constitutes an interesting mammalian model to study how pattern formation is achieved by differential gene activity. A large number of epididymis-expressed genes have been cloned and analyzed at the molecular level, most of them have been characterized by a distinct temporal and spatial expression pattern within the organ. Only recently have theories been developed about how and when during ontogenesis this pattern formation takes place and what its significance might be. This review summarizes the current knowledge on regionalized gene expression in the epididymis and presents hypotheses concerning its ontogenetic origin and regulation in the adult.

A 5-kilobase pair promoter fragment of the murine epididymal retinoic acid-binding protein gene drives the tissue-specific, cell-specific, and androgen-regulated expression of a foreign gene in the epididymis of transgenic mice

The murine epididymis synthesizes and secretes a retinoic acid-binding protein (mE-RABP) that belongs to the lipocalin superfamily. The gene encoding mE-RABP is specifically expressed in the mouse mid/distal caput epididymidis under androgen control. In transgenic mice, a 5-kilobase pair (kb) promoter fragment, but not a 0.6-kb fragment, of the mE-RABP gene driving the chloramphenicol acetyltransferase (CAT) reporter gene restricted high level of transgene expression to the caput epididymidis. No transgene expression was detected in any other male or female tissues. Immunolocalization of the CAT protein and in situ hybridization of the corresponding CAT mRNA indicated that transgene expression occurred in the principal cells of the mid/distal caput epididymidis, thereby mimicking the spatial endogenous mE-RABP gene expression. Transgene and mE-RABP gene expression was detected from 30 days and progressively increased until 60 days of age. Castration, efferent duct ligation, and hormone replacement studies demonstrated that transgene expression was specifically regulated by androgen but not by any other testicular factors. Altogether, our results demonstrate that the 5-kb promoter fragment of the mE-RABP gene contains all of the information required for the hormonal regulation and the spatial and temporal expression of the mE-RABP gene in the epididymis.

Expression, characterization and engineered specificity of rat epididymal retinoic acid-binding protein

Epididymal retinoic acid-binding protein (ERABP) is the major androgen-dependent protein present in the lumen of the epididymis and is thought to be involved in sperm maturation. It displays a high degree of three-dimensional structural similarity to serum retinol-binding protein (RBP). Although both proteins interact with retinoids, RBP exhibits a broad specificity, binding retinol, retinoic acid and retinaldehyde with roughly equal affinities, whereas ERABP is specific for all-trans- and 9-cis-retinoic acids. Consistent with this, the binding pockets of the two proteins are different: in RBP it is predominantly hydrophobic, whereas that for ERABP is amphipathic, with a network of charged residues at the open end of the binding pocket. In order to investigate the roles of these charged residues, Arg-80 and Glu-63 have been mutated to isoleucine. The resultant double mutant, Glu-63-->Ile/Arg-80-->Ile, as well as the wild-type protein, were subsequently expressed in Escherichia coli as fusion proteins, with the streptavidin recognition sequence (Strep) tagged to their C-termini. The expressed proteins were purified in a single step by streptavidin-affinity chromatography and their ligand-binding properties were examined using fluorimetric titrations. Whereas the wild-type ERABP binds only retinoic acid, the double mutant is capable of binding retinol, retinoic acid and retinaldehyde with similar affinities. These observations provide experimental support for the proposition that the charged residues near the open end of the binding pocket are responsible for restricting the specificity of ERABP for retinoic acid. These studies demonstrate that changes in specificity can be engineered into lipocalins.

Genomic organization and chromosomal localization of the murine epididymal retinoic acid-binding protein (mE-RABP) gene

The murine epididymal retinoic acid-binding protein (mE-RABP) is specifically synthesized in the mouse mid/distal caput epididymidis and secreted in the lumen. In this report, we have demonstrated by Southern blot analysis of genomic DNA that mE-RABP is encoded by a single-copy gene. A mouse 129/SvJ genomic bacterial artificial chromosome (BAC) library was screened using a cDNA encoding the minor form of mE-RABP. One positive BAC clone was characterized and sequenced to determine the nucleotide sequence of the entire mE-RABP gene. The molecular cloning of the mE-RABP gene completes the characterization of the 20.5-kDa-predicted preprotein leading to the minor and major forms of mE-RABP. Comparison of the DNA sequence of the promoter and coding regions with that of the rat epididymal secretory protein I (ESP I) gene showed that the mE-RABP gene is the orthologue of the ESP I gene that encodes a rat epididymal retinoic acid-binding protein. Several regulatory elements, including a putative androgen receptor binding site, "CACCC-boxes," NF-1, Oct-1, and SP-1 recognition sites, are conserved in the proximal promoter. Analysis of the nucleotide sequence of the mE-RABP gene revealed the presence of seven exons and showed that the genomic organization is highly related to other genes encoding lipocalins. The mE-RABP gene was mapped by fluorescent in situ hybridization to the [A3-B] region of the murine chromosome 2. Our data, combined with that of others, suggest that the proximal segment of the mouse chromosome 2 may be a rich region for genes encoding lipocalins with a genomic organization highly related to the mE-RABP gene.

Molecular cloning and hormonal regulation of a murine epididymal retinoic acid-binding protein messenger ribonucleic acid

A complementary DNA encoding the mouse epididymal secretory protein MEP 10 (mouse epididymal protein 10) was cloned and is now renamed murine epididymal retinoic acid binding protein (mE-RABP). The analysis of the predicted primary amino acid sequence showed that mE-RABP has a 75% identity with rat ESP I (epididymal secretory protein I), another epididymal retinoic acid-binding protein. The homology strongly suggests that mE-RABP is the mouse orthologue of rat ESP I. A computer analysis of the predicted three-dimensional structure confirmed that mE-RABP can accommodate retinoic acid as ligand. In the rat, ESP I messenger RNA (mRNA) is expressed in the efferent ducts and in the entire caput epididymidis. However, in the mouse, the expression of a 950-bp mE-RABP mRNA was detected only in principal cells of the mid/distal caput epididymidis, suggesting that the regulation of region-specific expression is different in rat and mouse. Northern blot analyses showed that mE-RABP gene expression is no longer detected 10 days after castration but progressively rebounds between days 15 and 60. However, mE-RABP protein could not be detected by Western blot 30 days after castration. Androgen replacement, begun 5 days after castration and continued for 4 days restored significant expression of mE-RABP mRNA. Efferent duct ligation for 10 days did not affect gene expression. Taken together, these results indicate that mE-RABP mRNA expression is regulated by androgens but not by testicular factors. The overall similarity in the primary amino acid sequence of mE-RABP with ESP I and other members of the lipocalin superfamily suggests that they are evolutionarily related.

Expression of phosphatidylethanolamine-binding protein in the male reproductive tract: immunolocalisation and expression in prepubertal and adult rat testes and epididymides

Phosphatidylethanolamine-binding protein (PBP) has been described previously in the male reproductive tract, where it has been implicated in the biogenesis and maintenance of antigen segregation of membranes. In the present study we have used a specific antiserum to PBP to determine its expression and localisation in the adult and prepubertal rat testis and epididymis by Western blotting and immunohistochemistry. In the adult rat testis, PBP was localised to step 17-19 elongating spermatids, residual bodies, and interstitial Leydig cells. In the adult epididymis, PBP was localised to epithelial cells of the caput, corpus, and cauda regions and to the cytoplasmic droplets of spermatozoa in the lumen of the initial segment, caput, and corpus epididymidis. In prepubertal animals, PBP was expressed in both testes and epididymides from day 1 and day 3 postpartum, respectively (day 3 being the earliest epididymal tissue taken). In prepubertal testes, PBP was localised to Leydig cells from day 1 postpartum and was not detected in any other cell type until the differentiation of elongate spermatids, when it was detected in step 17-19 elongating spermatids. These data suggest that PBP may be involved in the organisation of sperm membranes during spermiogenesis. The presence of PBP in Leydig cells, however, suggests diverse roles for this protein as a lipid carrier or binding protein.

Rat MDC family of proteins: sequence analysis, tissue distribution, and expression in prepubertal and adult rat testis

Increasing number of sequence-related cysteine-rich membrane proteins containing metalloproteinase-like and disintegrin-like domains (the MDC protein family) have been identified in mammalian tissues. Here, we report the cloning and sequence analysis of cDNAs encoding several rat orthologues of this protein family, some of which are found to be expressed exclusively in the male reproductive tract, others exhibiting a broader tissue distribution. We also examine their expression in prepubertal an adult rat testis, which, in conjunction with the data on tissue distribution, form a necessary prelude to further studies aimed at establishing their individual functions.

Puberty influences expression of phospholipid hydroperoxide glutathione peroxidase (GPX4) in rat testis: probable hypophysis regulation of the enzyme in male reproductive tract

Mammalian spermatozoa are unusually rich in polyunsaturated fatty acids, a property that predisposes them to the deleterious effects of oxygen free radicals. Mouse and human spermatozoa utilize glutathione peroxidase, (GPX), to inactivate oxygen free radicals. In the GPX super-family there is the enzyme phospholipid hydroperoxide glutathione peroxidase (GPX4) that specifically protects membrane phospholipids against peroxidation. GPX4 is present, primarily, in testis where its enzymatic activity seems to be present only after puberty. In order to clarify this question we utilized total RNA from rat testis, liver and lung to carry out cDNA synthesis and the following RT-PCR amplification of cDNA products by using specific primers of rat liver sequence. RT-PCR products of the expected size for GPX4 (525 bp) were obtained from the three tissues. At last, these fragments were submitted to sequencing analysis. Here we demonstrate that the sequence analysis of rat testis GPX4 coding region is identical to that of rat liver and lung; however puberty influences the expression pattern of rat testis GPX4. In fact Northern blot analysis of total RNA from normal and pre-puberal hypophysectomized rats demonstrates the absence of a specific GPX4 mRNA in total RNA from pre-puberal hypophysectomized rat testis; on the other hand this specific transcript is present in both normal rat testis and liver and in pre-puberal hypophysectomized rat liver. Expression pattern of GPX4 is very low in lung both in post-puberal and pre-puberal hypophysectomized rats. Therefore hypophysis could regulate GPX4 transcript in rat testis.

The human fertilin alpha gene is non-functional: implications for its proposed role in fertilization

In the guinea-pig, the alpha subunit of the fertilin complex, a heterodimeric surface membrane glycoprotein found on the head region of spermatozoa, has previously been proposed to mediate membrane fusion with the oolemma plasma membrane during fertilization. Here we describe experiments which indicate that the only fertilin alpha-like gene in humans is an expressed, but nonfunctional, pseudogene, possibly derived by genetic recombination between the two fertilin alpha genes found in some primates. This finding clearly raises questions about the importance and/or role of fertilin alpha in mammalian fertilization.

Primate homologues of rat TGN38: primary structure, expression and functional implications

cDNAs encoding the human and macaque homologues of rat TGN38 have been cloned and sequenced. The proteins have a highly conserved N terminus (comprising the signal peptide) and C terminus (comprising part of the lumenal domain, the membrane spanning region and cytoplasmic tail) but vary in the other part of the lumenal domain, which contains the repeat region. Whereas rat TGN38 contains 6 tandem repeats of an 8mer, both primate proteins possess 14 tandem repeats of a 14mer sequence. The human protein, like rat TGN38, is localised primarily to the TGN but is present on the cell surface and returns via endosomes. This behaviour is consistent with conservation of the membrane spanning region and the cytoplasmic tail, which contain the retention and retrieval signals, respectively, for localisation in the TGN. The unexpected differences in the lumenal domain can best be rationalised by the fact that both types of repeat domains have most of the properties of mucins. We suggest that TGN38 homologues are mucin-like molecules that regulate membrane traffic to and from the TGN.

Mouse androgen-dependent epididymal glycoprotein CRISP-1 (DE/AEG): isolation, biochemical characterization, and expression in recombinant form

In the rat, the secretory glycoprotein DE/AEG is one of the main constituents of the epididymal fluid. We have recently reported the cloning of the cDNA for the related cysteine-rich secretory protein-1 (CRISP-1) from murine epididymis (Haendler et al., 1993; Endocrinology 133:192-198). The protein has now been isolated from the same organ and its N-terminal amino acid sequence has been determined. CRISP-1 exhibited an isoelectric point of approximately 6.8. High levels of CRISP-1 antigen were detected in the corpus and cauda of the epididymis, vas deferens, seminal vesicle, prostate, and in the salivary gland by immunohistochemistry. A quantitative analysis of the cauda epididymal fluid by sandwich ELISA revealed that CRISP-1 represented approximately 15% of the total protein. For heterologous expression, the CRISP-1 coding sequence was introduced into the pMPSV/CMV vector before transfection of baby hamster kidney (BHK) cells and selection with puromycin and neomycin. Expression in insect cells was achieved by co-transfection of Sf9 cells with a transfer vector and baculovirus DNA. Recombinant CRISP-1 was isolated in quantities sufficient for structural analysis. Ethyl maleimide treatment showed that all 16 cysteines were engaged in disulfide bonds. Proteolytic digestion demonstrated that the six cysteines localized in the N-terminal moiety formed three bonds with each other, suggesting the existence of two discrete domains in the protein.

Epididymal epithelium: its contribution to the formation of a luminal fluid microenvironment

To understand the process of sperm maturation, an understanding of interactions between the spermatozoa with the luminal fluid microenvironment and with the epididymal epithelium is necessary. The composition of epididymal luminal fluid of several species is well documented but the manner by which the epididymis contributes to the formation of this specialized milieu is not so well understood. A major role played by the epididymis is to finely regulate the movement of molecules into and out of the lumen. This ensures that as spermatozoa progress along the duct they are exposed to a continually changing, but optimal environment necessary for their maturation and survival. This review focusses on our current understanding of the contributions of the epididymal epithelium to the formation of a specialized luminal fluid microenvironment. The role of the blood-epididymis barrier, the composition of the epididymal luminal fluid, the permeability properties of the epididymal epithelium, and recent studies on a number of luminal fluid proteins and expression of the genes which encode these proteins are discussed.

Sequence analysis of a mammalian phospholipid-binding protein from testis and epididymis and its distribution between spermatozoa and extracellular secretions

The cellular origin of a soluble phospholipid-binding protein (PBP) in rat testicular and epididymal secretions has been investigated genetically and immunologically. PBP is ubiquitous in tissue cytosols but is not present in blood serum, lymph or milk. The relatively large amounts present in cauda epididymal plasma (CEP) and rete testis fluid suggested therefore that it may be secreted specifically by these tissues. However, when PBP cDNAs from testis and epididymis were cloned and sequenced, they did not contain a signal peptide and only one size of transcript was obtained on Northern blots of RNAs from liver, brain, placenta, testis and epididymis. Moreover, PBP could not be detected in sperm-free CEP from castrated, androgen-stimulated animals or in medium from Sertoli cell cultures. Spermatozoa, on the other hand, contained significant amounts of PBP that could be solubilized by washing cells in dissociating reagents or high-salt solutions. These results indicate that, contrary to previous interpretations, PBP is not secreted by classical pathways in either the testis or epididymis but that its presence in CEP and rete testis fluid is attributable largely to release from spermatozoa. Thus, spermatozoa have a significant influence on the composition of CEP as well as on the secretory and absorptive activity of the epididymal epithelium. A possible role for PBP in membrane biogenesis and maintenance of antigen segregation in spermatozoa is discussed.

Genomic structure of the human complement protein C8 gamma: homology to the lipocalin gene family

Human C8 is one of five complement components (C5b, C6, C7, C8, C9) that interact to form the cytolytic C5b-9 complex on target cells. It contains three subunits (C8 alpha, C8 beta, C8 gamma) which are encoded in separate genes. In relation to other proteins of the complement system, C8 gamma is unusual in that it is not structurally related to any other component nor does it have an obvious function. Based on weak but significant sequence similarity, it is proposed to be a member of the lipocalin family of widely distributed proteins that bind and transport small hydrophobic ligands. In this study, the human C8 gamma gene has been characterized and found to contain seven exons spanning approximately 1.8 kb. S1 nuclease and anchored PCR were used to identify the transcription initiation site. This site is preceded by putative regulatory elements that include two SP1 binding sites, several glucocorticoid response elements, and two SV40 enhancer core consensus sequences. A comparison to genes of other lipocalins reveals a remarkably close correlation in exon number, lengths, and phases. A close correspondence in exon boundaries is also observed and suggests that C8 gamma contains the same discrete structural elements that define the characteristic beta-barrel shape of the lipocalins. These results establish that C8 gamma is indeed ancestrally related to the lipocalin family and strengthens the likelihood that its role in the complement system is to bind an as yet unidentified ligand.

Structural organization of the gene encoding the human lipocalin tear prealbumin and synthesis of the recombinant protein in Escherichia coli

The genomic DNA fragment encoding the human lipocalin tear prealbumin (LCN1), a new member of the superfamily of hydrophobic molecule transporters, has been isolated and sequenced. The entire gene is approximately 6.2 kb in size and contains six protein-coding exons and a 3'-nontranslated exon. All exon/intron splice junctions exactly follow the GT/AG rule. The structure of the LCN1 gene is highly similar, in terms of numbers and sizes of exons and in intron phasing, to that of the genes encoding ovine beta-lactoglobulin, human placental protein P14, rat alpha 2-urinary globulin, rat prostaglandin D synthase and human alpha 1-microglobulin, thus supporting the close evolutionary relationship of these genes. The 5'-noncoding region of LCN1 contains, besides a TATA and CAAT box, several motifs that resemble regulatory elements of other eukaryotic genes, including potential metal-responsive elements (MRE) and a cAMP-responsive element (CRE). As a basis for further investigations concerning the structure-function relationship and to generate a source of recombinant protein for X-ray crystallography studies, LCN1 was produced in Escherichia coli as a fusion with maltose-binding protein.

Isolation and characterization of a rat cDNA clone encoding a secreted superoxide dismutase reveals the epididymis to be a major site of its expression

Superoxide dismutase (SOD) plays a key role in combating loss of fertility of spermatozoa due to lipid peroxidation. Here we report the sequence of a cDNA encoding a secreted form of SOD isolated from a rat epididymal library. Northern-blot analysis indicates that the corresponding transcript is expressed principally in the cauda region of the epididymis, consistent with the high levels of SOD enzyme activity found in cauda-epididymidal plasma. Much lower levels of an identically sized transcript exist in all tissues examined, including placenta. PCR and subsequent sequence analysis of rat placental SOD strongly suggest that it is identical in sequence with epididymal SOD.

Structure and expression of the excision repair gene ERCC6, involved in the human disorder Cockayne's syndrome group B

The human repair gene ERCC6--a presumed DNA (or RNA) helicase--has recently been found to function specifically in preferential nucleotide excision repair (NER). This NER subpathway is primarily directed towards repair of (the transcribed strand of) active genes. Mutations in the ERCC6 gene are responsible for the human hereditary repair disorder Cockayne's syndrome complementation group B, the most common form of the disease. In this report, the genomic organization and expression of this gene are described. It consists of at least 21 exons, together with the promoter covering a region of 82-90 kb on the genome. Postulated functional domains deduced from the predicted amino acid sequence, including 7 distinct helicase signatures, are--with one exception--encoded on separate exons. Consensus splice donor and acceptor sequences are present at all exon borders with the exception of the unusual splice donor at the end of exon VII. The 'invariable' GT dinucleotide in the consensus (C,A)AG/GTPuAGT is replaced by the exceptional GC. Based on 42 GC splice donor sequences identified by an extensive literature search we found a statistically highly significant better 'overall' match of the surrounding nucleotides to the consensus sequence compared to normal GT-sites. This confirms and extends the observation made recently by Jackson (Nucl. Acids Res., 19, 3795-3798 (1991)) derived from analysis of 26 cases. Analysis of ERCC6 cDNA clones revealed the occurrence of alternative polyadenylation, resulting in the (differential) expression of two mRNA molecules (which are barely detectable on Northern blots) of 5 and 7 kb in length.

Genetic evidence for an androgen-regulated epididymal secretory glutathione peroxidase whose transcript does not contain a selenocysteine codon

Epididymal glutathione peroxidase (GPX) has been suggested as a major factor in combating loss of fertility of spermatozoa due to lipid peroxidation. We report here the isolation and sequence of putative GPX cDNAs from rat (Rattus rattus) and cynomolgus-monkey (Macaca fascicularis) epididymis, which exhibit marked sequence identity with known GPXs. In both species the cDNAs encode predicted preproteins containing 221 amino acid residues. Unlike other characterized GPX sequences, epididymal GPX mRNA does not contain a selenocysteine codon (UGA). However, sequence comparison and molecular-modelling studies suggest a high degree of structural conservation between epididymal and other GPXs. Transcripts corresponding to epididymal GPX are not detected in a variety of other tissues (liver, spleen, kidney and testis) and appear to be androgen-regulated in the epididymis.