A rat homeobox gene, rNKx-2.5, is a homologue of the tinman gene in Drosophila and is mainly expressed during heart development

 We report the cloning of a rat homeobox-containing gene, rNkx-2.5, and investigation of its expression in adult tissues and during embryonic development. The rNkx-2.5 gene is a homologue of the tinman gene in Drosophila. Both genes share an identical TN domain (tinman-like amino-terminal decapeptide) and about 66.7% sequence identity within their homeodomain sequences. In vertebrates, the rNKx-2.5 gene is most closely related to the mouse NKx-2.5 (mNKx-2.5) gene. Coding sequences for both NKx-2.5 genes have 94.1% sequence identity, including three identical conserved domains, the TN, homeo and NK-2 domains (NK-2 specific domain, carboxy-terminal to the homeodomain in vertebrate tinman homologues). The rat NKx-2.5 gene is encoded by a 1.4-kb mRNA and in adult tissues is mainly expressed in heart, with weaker expression in testis, spleen and lung. During embryonic development, expression of rNKx-2.5 is strongly observed in developing heart, specifically in the myocardium of both atrial and ventricular chambers. In addition, rNKx-2.5 expression marks other developing tissues, including tongue, thyroid, stomach, spleen and pulmonary veins. These data show that rNKx-2.5 is expressed in a pattern similar but not identical to that previously observed for mNKx-2.5. Received: 24 February 1997 / Accepted: 23 June 1997     

A testis‐specific gene within a widely expressed gene: Contrasting evolutionary patterns of two differentially expressed mammalian proteins encoded by a single gene,CAMK4

Understanding the patterns of genetic variations within fertility‐related genes and the evolutionary forces that shape such variations is crucial in predicting the fitness landscapes of subsequent generations. This study reports distinct evolutionary features of two differentially expressed mammalian proteins [CaMKIV (Ca²⁺/calmodulin‐dependent protein kinase IV) and CaS (calspermin)] that are encoded by a single gene, CAMK4. The multifunctional CaMKIV, which is expressed in multiple tissues including testis and ovary, is evolving at a relatively low rate (0.46–0.64 × 10^?9 nucleotide substitutions/site/year), whereas the testis‐specific CaS gene, which is predominantly expressed in post‐meiotic cells, evolves at least three to four times faster (1.48–1.98 × 10^?9 substitutions/site/year). Concomitantly, maximum‐likelihood‐based selection analyses revealed that the ubiquitously expressed CaMKIV is constrained by intense purifying selection and, therefore, remained functionally highly conserved throughout the mammalian evolution, whereas the testis‐specific CaS gene is under strong positive selection. The substitution rates of different mammalian lineages within both genes are positively correlated with GC content, indicating the possible influence of GC‐biased gene conversion on the estimated substitution rates. The observation of such unusually high GC content of the CaS gene (≈74%), particularly in the lineage that comprises the bovine species, suggests the possible role of GC‐biased gene conversion in the evolution of CaS that mimics positive selection.     

The spalt-related gene of Drosophila melanogaster is a member of an ancient gene family,defined by the adjacent,region-specific homeotic gene spalt

 We report the full coding sequence of a new Drosophila gene, spalt-related, which is homologous and adjacent to the region-specific homeotic gene, spalt. Both genes have three widely spaced sets of C₂H₂ zinc finger motifs, but spalt-related encodes a fourth pair of C-terminal fingers resembling the Xenopus homologue, Xsal-1. The degrees of sequence divergence among all three members of this family are comparable, suggesting that the Drosophila genes originated from an ancient gene duplication. The spalt-related gene is expressed with quantitative variations from mid-embryogenesis (8–12 h) to the adult stage, but not in ovaries or early embryos. Expression is localized to limited parts of the body, including specific cell populations in the nervous system. In the wing disc, spalt and spalt-related are expressed in indistinguishable domains; in the nervous system and some other organs the expression patterns extensively overlap but are not identical, indicating that the genes have partially diverged in terms of developmental regulation. A characteristic central set of zinc fingers specifically binds to an A/T-rich consensus sequence, defining some DNA binding properties of this ancient family of nuclear factors. Received: 31 July 1996 / Accepted: 4 September 1996     

Cloning of a novel gene,<Emphasis Type="Italic">Cymg1</Emphasis>, related to family 2 cystatins and expressed at specific stages of mouse testis development

We have cloned a novel gene,Cymg1 (GenBank accession number AY600990), from a mouse testis cDNA library.Cymg1 is located in 2G3 of mouse chromosome 2. The cDNA includes an open reading frame that encodes 141 amino acid residues. The encoded polypeptide has a cysteine protease inhibitor domain found in the family 2 cystatins but lacks critical consensus sites important for cysteine protease inhibition. These characteristics are seen in the proteins of the CRES subfamily of the family 2 cystatins which are expressed specifically in the reproductive tract. CYMG1 protein shows 44% identity with mouse CRES and 30% identity with mouse cystatin C. Northern blot analysis showed that theCymg1 gene was specifically expressed in adult mouse testis. RT-PCR also showed thatCymg1 was expressed in testis and spermatogonial cells.Cymg1 expression level varied in the different developmental stages of mouse testis, and were coincidental with spermatogenesis and sex maturation. These results indicate thatCymg1 may play important roles in mouse spermatogenesis and sex maturation     

Characterization and expression of three novel differentiation-related genes belong to the human NDRG gene family

NDRG1(N-Myc downstream regulated) is upregulated during cell differentiation, repressed by N-myc and c-myc in embryonic cells, and suppressed in several tumor cells. A nonsense mutation in the NDRG1 gene has been reported to be causative for hereditary motor and sensory neuropathy-Lom (HMSNL), indicating that NDRG1 functions in the peripheral nervous system necessary for axonal survival. Here, we cloned three human cDNAs encoding NDRG2 (371aa), NDRG3 (375aa) and NDRG4 (339aa), which are homologous to NDRG1. These three genes, together with NDRG1, constitute the NDRG gene family. The phylogenetic analysis of the family demonstrated that human NDRG1 and NDRG3 belong to a subfamily, and NDRG2 and NDRG4 to another. At amino acid (aa) level, the four members share 53–65% identity. Each of the four proteins contains an / hydrolase fold as in human lysosomal acid lipase. Expression of the fusion proteins NDRG2/GFP, NDRG3/GFP and NDRG4/GFP in COS-7 cells showed that all of them are cytosolic proteins. Based on UniGene cluster analysis, the genes NDRG2, NDRG3 and NDRG4 are located at chromosome 14q11.1–11.2, 20q12–11.23 and 16q21–22.1, respectively. Northern and dot blot analysis shows that all of the three genes are highly expressed in adult brain and almost not detected in the eight human cancer lines. In addition, in contrast to the relatively ubiquitous expression of NDRG1, NDRG2 is highly expressed in adult skeletal muscle and brain, NDRG3 highly expressed in brain and testis, and NDRG4 specifically expressed in brain and heart, suggesting that they might display different specific functions in distinct tissues.     

Cloning and characterization of the gene encoding the bovine BOULE protein

The Deleted in Azoospermia (DAZ) genes encode potential RNA-binding proteins that are expressed exclusively in the germ-line. The bovine Deleted in Azoospermia-like gene is a strong candidate for male cattle-yak infertility. In this work, with the goe goal to further reveal the genetic cause of male cattle-yak sterility, another bovine DAZ family gene, b-boule, was isolated and characterized. The b-boule gene is predicted to encode a polypeptide of 295 amino acids with an RNP-type RNA recognition domain. Tertiary structure analysis shows that b-boule binds specifically to polypyrimidine RNAs and might act as a nuclear ribonucleoprotein particle auxiliary factor during germ cell formation and morphological changes of germ cells. RT-PCR assays revealed that b-boule was expressed specifically in the adult testis. However, an extremely low level of expression was detected in the testis of sterile male cattle-yaks. Microstructure of the testes from sterile males showed that type A spermatogonia were the only germ cells present and that few germ cells developed further than the stage of pachytene spermatocytes. These results suggest that b-boule may function in bovine spermatogenesis, and that low levels of b-boule expression might lead to male sterility in cattle-yaks.     

The SOX gene family: function and regulation in testis determination and male fertility maintenance

The Sox (Sry-type HMG box) genes encode a group of proteins characterized by the existence of an SRY (sex-determining region on Y chromosome) box, a 79 amino acid motif that encodes an HMG (high mobility group) domain which can bind and bend DNA, which is the only part in SRY that is conserved between species. The Sox gene family functions in many aspects in embryogenesis, including testis development, CNS neurogenesis, oligodendrocyte development, chondrogenesis, neural crest cell development and other respects. The Sox gene family was originally identified through homology with Sry. The Sry gene is the mammalian testis-determining gene. It functions to open the testis determination pathway directly and close the ovary pathway indirectly. Sry and Sox9 are the most important two genes expressed during testis determination. Besides, researchers have found that Sox8 and Sox9 have functions in the male fertility maintenance after birth. In this review, information was evaluated from mouse or from human if not mentioned otherwise.     

Genomic organization, tissue distribution and functional characterization of the rat Pate gene cluster

The cysteine rich prostate and testis expressed (Pate) proteins identified till date are thought to resemble the three fingered protein/urokinase-type plasminogen activator receptor proteins. In this study, for the first time, we report the identification, cloning and characterization of rat Pate gene cluster and also determine the expression pattern. The rat Pate genes are clustered on chromosome 8 and their predicted proteins retained the ten cysteine signature characteristic to TFP/Ly-6 protein family. PATE and PATE-F three dimensional protein structure was found to be similar to that of the toxin bucandin. Though Pate gene expression is thought to be prostate and testis specific, we observed that rat Pate genes are also expressed in seminal vesicle and epididymis and in tissues beyond the male reproductive tract. In the developing rats (20-60 day old), expression of Pate genes seem to be androgen dependent in the epididymis and testis. In the adult rat, androgen ablation resulted in down regulation of the majority of Pate genes in the epididymides. PATE and PATE-F proteins were found to be expressed abundantly in the male reproductive tract of rats and on the sperm. Recombinant PATE protein exhibited potent antibacterial activity, whereas PATE-F did not exhibit any antibacterial activity. Pate expression was induced in the epididymides when challenged with LPS. Based on our results, we conclude that rat PATE proteins may contribute to the reproductive and defense functions.     

New members of the neurexin superfamily: multiple rodent homologues of the human CASPR5 gene

Proteins of the Caspr family are involved in cell contacts and communication in the nervous system. We identified and, by in silico reconstruction, compiled three orthologues of the human CASPR5 gene from the mouse genome, four from the rat genome, and one each from the chimpanzee, dog, opossum, and chicken genomes. Obviously, Caspr5 gene duplications have taken place during evolution of the rodent lineage. In the rat, the four paralogues are located in one chromosome arm, Chr 13p. In the mouse, however, the three Caspr5 genes are located in two chromosomes, Chr 1 and Chr 17. RT-PCR shows that all three mouse paralogues are being expressed. Common expression is found in brain tissue but different expression patterns are seen in other organs during fetal development and in the adult stage. Tissue specificity of expression has diverged during evolution of this young rodent gene family.     

Cloning and characterization of a novel human TEKTIN1 gene

Tektins comprise a family of filament-forming proteins that are known to be coassembled with tubulins to form ciliary and flagellar microtubules. A new member of the tektin gene family was cloned from the human fetal brain cDNA library. We hence named it the human TEKTIN1 gene. TEKTIN1 cDNA consists of 1375 bp and has a putative open reading frame encoding 418 amino acids. The predicted protein is 48.3 kDa in size, and its amino acid sequence is 82% identical to that of the mouse, rat, and dog. One conserved peptide RPNVELCRD was observed at position number 323–331 of the amino acid sequence, which is a prominent feature of tektins and is likely to represent a functionally important protein domain. TEKTIN1 gene was mapped to the human chromosome 17 by BLAST search, and at least eight exons were found. Northern blot analysis indicated that TEKTIN1 was predominantly expressed in testis. By in-situ hybridization analysis, TEKTIN1 mRNA was localized to spermatocytes and round spermatids in the seminiferous tubules of the mouse testis, indicating that it may play a role in spermatogenesis.     

Tissue-specific developmental expression of the kallikrein gene family in the rat

Using a series of gene-specific oligonucleotide probes, we have explored the developmental pattern of expression of six members of the rat kallikrein gene family (PS, S1, S2, S3, K1, and P1) in the submandibular gland (SMG) and kidney of both sexes, the prostate and testis of the male, and the anterior pituitary gland (AP) of the female rat. PS (true kallikrein) mRNA was detected in early neonatal life in the SMG and kidney of both sexes. K1, a second kallikrein gene family member expressed in the adult kidney, had a developmental pattern similar to PS in the kidney. In contrast, tonin (S2), S3, K1, and P1, all of which are expressed in the adult SMG, did not reach detectable SMG mRNA levels until puberty in either the male or female rat. Both S3 and P1, which are expressed in the adult prostate, and the novel P1-like mRNA previously detected in the adult rat testis, first appeared in early puberty. In the female AP, PS mRNA levels were not detected until early puberty and thus exhibited a developmental profile different from that of prolactin. The demonstration that S1, S2, S3, P1, and K1 are not expressed in the SMG or prostate until puberty is consistent with the expression of these genes in these tissues being androgen-regulated; the first appearance of PS mRNA in the female AP in early puberty similarly reflects the estrogen dependence of PS gene expression in this tissue. The presence of PS mRNA levels in the SMG and kidney prior to sexual maturation reflects the androgen independence of PS gene expression and suggests that PS (true kallikrein) may play a constitutive and/or developmental role in SMG or renal physiology.     

Recent duplication and positive selection of the <Emphasis Type="Italic">GAGE</Emphasis> gene family

We report that the GAGE gene family of human Cancer/testis antigen (CTA) genes is likely to be in an early stage of its evolution. Members of this gene family are tandemly arranged on the X chromosome only in human, chimpanzee and macaque genomes and share a very high similarity. Phylogenetic trees show that the GAGE gene family began to duplicate after the split of human and chimpanzee. The estimated ages of the duplication events range from 4 million years ago to the present. The Ka/Ks values between the duplicates are significantly greater than 1, indicating that the mutation rate is higher in coding regions than non-coding regions of the genes, which suggests that the GAGE gene family is under positive selection. These findings indicate that the GAGE gene family may be a newly formed gene family undergoing rapid functional evolution. Yang Liu and Qiyun Zhu contributed equally to this work.     

Genomic structure and expression of a gene coding for a new fatty acid binding protein from Echinococcus granulosus

This work describes a new gene coding for a fatty acid binding protein (FABP) in the parasite Echinococcus granulosus, named EgFABP2. The complete gene structure, including the promoter sequence, is reported. The genomic coding domain organisation of the previously reported E. granulosus FABP gene (EgFABP1) has been also determined. The corresponding polypeptide chains share 76% of identical residues and an overall 96% of similarity. The two EgFABPs present the highest amino acid homologies with the mammalian FABP subfamily containing heart-FABPs (H-FABPs). The coding sequences of both genes are interrupted by a single intron located in the position of the third intron reported for vertebrate FABP genes. Both genes are expressed in the protoscolex stage of the parasite. The promoter region of EgFABP2 presents several consensus putative cis-acting elements found in other members of the family, suggesting interesting possible mechanisms involved in the host–parasite adaptation.     

Decreased keratinocyte motility in skin wound on mice lacking the epidermal fatty acid binding protein gene

Fatty acids are shown to be important in various skin functions. Fatty acid binding protein (FABP) is postulated to serve as a lipid shuttle, solubilizing hydrophobic fatty acids and delivering them to the appropriate metabolic system. Among the FABP family proteins, epidermal-type FABP (E-FABP) is solely expressed in keratinocyte but its specific role in skin is not yet fully established. We found an elevated expression of E-FABP in regenerative keratinocytes of healing wounds. However, E-FABP null mice showed no marked differences compared to wild type mice in the process of wound closure, in vivo. On the other hand, in keratinocyte culture, E-FABP gene disruption decreased the cell motility, but did not affect the cell proliferation. E-FABP deletion may be compensated for in vivo by the microenvironment comprised of various cells such as fibroblasts and endothelial cells around the wound. Our analyses suggest that the E-FABP elevation may be necessary for the activation of cell motility within regenerative epidermis during wound healing.