Both P1 and P2 protamine genes are expressed in mouse, hamster, and rat

To date, in mammals except for the mouse and human, only one protamine variant has been isolated from sperm. These mammalian protamines share amino acid sequence homology with mouse protamine 1 (mP1), the tyrosine-containing variant. Southern blot analysis of restriction enzyme digests of hamster and rat liver DNA reveals the presence of sequences homologous to mP1, and also to mouse protamine 2 (mP2) cDNAs. Northern blots of hamster and rat total testis RNA probed with mP2 cDNA confirm that the protamine 2 gene in these species is transcribed into two size classes of mRNA of approximately 830 and 700 nucleotides. However, the relative abundance of the rat and hamster protamine 2 mRNAs (rP2 and hP2) in total testis is approximately 50-fold lower and 2- to 5-fold lower, respectively, than the mouse protamine 2 mRNA. Northern blot analysis of hamster and rat testis polysome gradients demonstrates that although the amount of rP2 mRNA and hP2 mRNA is reduced, both are present on polysomes. The decreased expression of rat and hamster protamine 2 mRNA relative to their protamine 1 counterparts contrasts protamine expression in the mouse testis, where approximately equal amounts of mP1 and mP2 protamine mRNAs are present. These results suggest differential expression of the P1 and P2 protamine genes in three closely related mammals.     

Discovery in silico and characterization in vitro of novel genes exclusively expressed in the mouse epididymis

Epididymal proteins interact with sperm during their passage through the epididymis and thus contribute to the maturation and fertilizing capacity of the spermatozoa. In the present study we have discovered five novel epididymis-specific genes through in silico analysis of expressed sequence tags (ESTs) at the UniGene library collection. The strategy used is a powerful way to discover novel epididymis-specific genes. The full-length cDNA sequences were determined, and computational tools were used to characterize the genomic structures and to predict putative functions for the encoded proteins. In vitro analyses revealed that all five genes characterized were highly expressed in the defined areas of the epididymis, and they were not expressed at significant levels in any other tissue. Three of the genes were named on the basis of their putative functions: Spint4 (serine protease inhibitor, Kunitz type 4), and Rnase9 and Rnase10 (ribonuclease, Rnase A family 9 and 10), while for the ESTs AV381130 and AV381126 no putative functions could be predicted. The expression of Spint4, Rnase9, and AV381130 was found to be under a direct or indirect regulation by androgens, while the expression of Rnase10 is regulated by a testicular factor(s) other than androgen. None of the genes were expressed in the immature epididymis, while mRNAs were detected from d 17 onward, at the time of maturation of epididymal epithelium. However, the expression of AV381130 was not detected until d 30 after birth, indicating a close connection between gene expression and puberty.     

Tumor promoter-inducible genes are differentially expressed in the developing mouse.

TIS genes are rapidly and transiently induced by tetradecanoyl phorbol acetate in 3T3 cells. We analyzed the developmental appearance of a number of the TIS genes to determine whether, in a normal physiological context, these genes have common or distinct mechanisms of regulation. Each TIS gene has a distinct tissue specificity and/or developmental profile.     

Characterization of Solt, a novel SoxLZ/Sox6 binding protein expressed in adult mouse testis

SoxLZ/Sox6, a member of the Sox protein family, contains a leucine zipper motif in addition to an HMG box, which is its DNA binding domain. Here we have identified a novel SoxLZ/Sox6 binding protein, termed Solt, which we obtained independently using both a far-Western blot and a yeast two-hybrid screen. Like SoxLZ/Sox6 mRNA, Solt mRNA was exclusively expressed in the testis in mouse. Solt contains an unusual leucine zipper, which bound to the leucine zipper region of SoxLZ/Sox6 in vitro. In transient transfection assays in CHO cells with SoxLZ/Sox6 containing the transactivational region of herpes simplex virus VP16, expression of a reporter gene that carries a cis binding region for Sox proteins was significantly enhanced by the co-expression of Solt and Ca(2+)/calmodulin-dependent protein kinase IV.     

Albumin binding proteins are highly expressed in actively proliferating fetal and adult tissues

The expression of albumin binding proteins (ABP, 31 and 18 kDa peptides) in various organs as a function of their ontogenic development was investigated in fetuses (20 days old), neonates (1 day old) and adult rabbits. At each of these stages, tissue extracts of brain, lung, thymus, heart, skeletal muscle and liver as well as whole embryos (11 days old) were examined by ligand blotting and quantitative immunoblot assays. Blots were either incubated with [125I]albumin followed by autoradiography and radioassay or exposed to a radioiodinated antibody raised against affinity-isolated 31 kDa peptide. Anti-31 kDa IgG cross-reacted with both 31 and 18 kDa peptides. Both methods used revealed that ABP are well expressed in embryos and in all fetal organs investigated. By comparison, in neonates, the ABP expression was diminished (by approximately 2-fold) in brain, heart and skeletal muscle. These changes were even more pronounced in the adult rabbit brain, heart, skeletal muscle and liver; no significant modification was detected in the lung. Prompted by these results, which inferred a high level of ABP in actively proliferating/differentiating tissues, we checked for the presence of ABP in other adult cells and tissues. In bone marrow cells, thymocytes and splenocytes, the 31 and 18 kDa peptides represented the major sodium dodecyl sulfate-urea extracted proteins, whereas in mature circulating white blood cells they were moderately expressed. The results indicate that ABP 1) are present early in embryogenesis, 2) are particularly well expressed in organs (fetal or adult) and cells characterized by active proliferation and differentiation, and 3) are not tissue specific.(ABSTRACT TRUNCATED AT 250 WORDS)     

Paralog group 1 hox genes regulate rhombomere 5/6 expression of vhnf1, a repressor of rostral hindbrain fates, in a meis-dependent manner

The vertebrate hindbrain is segmented into an array of rhombomeres (r), but it remains to be fully understood how segmentation is achieved. Here we report that reducing meis function transforms the caudal hindbrain to an r4-like fate, and we exploit this experimental state to explore how r4 versus r5-r6 segments are set aside. We demonstrate that r4 transformation of the caudal hindbrain is mediated by paralog group 1 (PG1) hox genes and can be repressed by vhnf1, a gene expressed in r5-r6. We further find that vhnf1 expression is regulated by PG1 hox genes in a meis-dependent manner. This implies that PG1 hox genes not only induce r4 fates throughout the caudal hindbrain, but also induce expression of vhnf1, which then represses r4 fates in the future r5-r6. Our results further indicate that r4 transformation of the caudal hindbrain occurs at intermediate levels of meis function, while extensive removal of meis function produces a hindbrain completely devoid of segments, suggesting that different hox-dependent processes may have distinct meis requirements. Notably, reductions in the function of another Hox cofactor, pbx, have not been reported to transform the caudal hindbrain, suggesting that Meis and Pbx proteins may also function differently in their roles as Hox cofactors.     

Two 5S genes are expressed in chicken somatic cells.

Two 5S RNA species were detected in chicken cells. 5S I RNA has the nucleotide sequence of chicken 5S RNA previously published by Brownlee et al. (1) and 5S II RNA differs from it by 10 mutations. The secondary structure of both species is compatible with that proposed for other eukaryotic 5S RNAs. 5S II RNA represents 50-60% of 5S I RNA. Both species were found in total chicken liver and brain and were present in polysomes in the same relative proportions. Only one 5S RNA species could be detected in rat liver and HeLa cells. Chicken is the first vertebrate described so far in which two 5S RNA genes are expressed in somatic cells.     

Multiple non-allelic genes encoding pancreatic alpha-amylase of mouse are expressed in a strain-specific fashion.

The number of active Amy-2 genes has been estimated in strain CE/J mice which produce four distinct electrophoretic forms of alpha-amylase in their pancreas. cDNA cloning and DNA sequence analysis discloses five distinct mRNA sequences which differ by approximately 1% of their nucleotides. Two of these mRNAs specify the same protein. Changes in the nucleotide sequences result in amino acid replacements that alter the net charges of the deduced proteins. This has allowed a tentative assignment of individual mRNAs to isozymes detected by electrophoresis. Quantitative Southern blot hybridization using a DNA probe specific for the first exon of Amy-2 reveals the presence of greater than 10 Amy-2 related sequences per haploid CE/J genome. Models which could account for the mouse strain-specific differences with respect to the number of pancreatic alpha-amylase isozymes and their variable but genetically determined quantitative ratios are discussed.     

The ADAM1a and ADAM1b genes,instead of the ADAM1 (fertilin alpha) gene,are localized on mouse chromosome 5

Fertilin is reported to be a heterodimeric protein composed of A Disintegrin And Metalloprotease 1 (ADAM1, fertilin alpha) and ADAM2 (fertilin beta) located on the sperm surface. In the process of clarifying the molecular basis of mouse ADAM1, we have identified two intron-less mouse genes encoding different isoforms of ADAM1, termed ADAM1a and ADAM1b. The amino acid sequences of ADAM1a and ADAM1b deduced from the DNA sequences were homologous to each other (99% identity) in the pro- and metalloprotease domains, whereas the C-terminal half region of ADAM1a, including the disintegrin and Cys-rich domains, shared only a low degree of identity (37%) with that of ADAM1b. These two genes were both localized on mouse chromosome 5 as a single copy gene, and were expressed specifically in the testis. These data demonstrate the presence of the ADAM1a (Adam1a) and ADAM1b (Adam1b) genes in mouse, instead of the ADAM1 gene, and may imply different roles of ADAM1a and ADAM1b in spermatogenesis, sperm maturation, and/or fertilization.