Nucleotide sequence of a mouse Tcp-1 pseudogene: A nucleotide record for a t complex gene carried by an ancestor of the mouse

We have isolated clones of a processed pseudogene of mouse t complex polypeptide 1 (Tcp-1) and determined the nucleotide sequence of the pseudogene. The pseudogene was 1363 bp long and had no intron. The Tcp-1 pseudogene had 88.4% or 88.3% nucleotide identity to the mouse Tcp-1 cDNA of wild-type (Tcp-1)^bor t haplotype (Tcp-1)^a, and 87.5% identity to the rat Tcp-1 cDNA. On 12 nucleotide positions where the open reading frames (ORFs) of mouse Tcp-1 ^band Tcp-1 ^acDNAs have bp substitutions, the Tcp-1 pseudogene had 6 bp identical to Tcp-1 ^b, 5 bp identical to Tcp-1 ^aand 1 bp not identical to neither. On ten amino acid positions where TCP-1B and TCP-1A polypeptides have substitutions, deduced amino acids of the Tcp-1 pseudogene had four amino acids identical to TCP-1B, five amino acids identical to TCP-1A and one amino acid identical to neither. These results suggest that the ancestral mouse Tcp-1 gene would have had no significant difference between the resemblance to Tcp-1 ^band that to Tcp-1 ^abefore they were diverged and that amino acids of TCP-1B and TCP-1A would have been substituted in similar high rates.The nucleotide sequence data reported in this paper have been submitted to GenBank and have been assigned the accession number D00851.     

Molecular cloning and sequence analysis of a haploid expressed gene encoding t complex polypeptide 1

The mouse t haplotypes show defects in spermatogenesis attributed to multiple loci on chromosome 17. We have cloned the gene for an abundant testicular germ cell protein, t complex polypeptide 1, which has a variant form in t haplotypes, TCP-1A. A cDNA clone, pB1.4, which hybridizes to a 19S mRNA that is abundant in haploid cells during mouse spermatogenesis, derives from the 3' end of the mRNA encoding TCP-1B. The Tcp-1 gene appears to be a member of a novel gene family and shows multiple changes between the predicted amino acid sequences of TCP-1B and TCP-1A. An additional Taq1 site is created by a T to C transition in the predicted open reading frame of the Tcp-1a gene. The resultant RFLP has allowed typing of the Tcp-1 gene cluster in 54 complete and partial t haplotype chromosomes. DNA sequence comparison of the Tcp-1 genes suggests that the t haplotype chromosome arose within the genus Mus more than one million years ago.     

Nucleotide sequence of mouse Tcp-1a cDNA

We have isolated complete cDNA clones encoding the mouse t-complex polypeptides 1A and 1B (TCP-1A and TCP-1B) from t-haplotype and wild-type (wt) mice, respectively. The complete nucleotide (nt) sequence of the Tcp-1a cDNA was determined. The Tcp-1a cDNA has an open reading frame (ORF) encoding a 60-kDa protein of 556 amino acids (aa). A comparison of nt sequences between the Tcp-1a and Tcp-1b cDNAs revealed that the 1786-bp regions upstream from their polyadenylation signals differed by 17 substitutions and that Tcp-1a had different polyadenylation sites from Tcp-1b. In these ORFs, 15 bp were substituted between the two alleles, occurring in 14 codons and resulting in eleven single-aa substitutions. Among these 15 substitutions, twelve were nonsynonymous (aa change) and three were synonymous (no aa change). The aa substitution in TCP-1 has occurred at least 20 times faster between t-haplotype and wt than between mouse and human or mouse and Drosophila.     

Sequence of the t complex Tcp-10a t gene and examination of the Tcp-10 t gene family

Transmission ratio distortion (TRD) is a property of complete t haplotypes which results in the preferential transmission of the t haplotype chromosome from heterozygous t/+ males to the majority of the offspring. A candidate gene for one of the primary genetic elements in TRD, the t complex responder locus has recently been suggested to be Tcp-10b ^t. There are multiple, functional Tcp-10 ^t genes, but genetic data suggest the presence of the Tcp-10a ^t gene alone is compatible with normal transmission ratios. Here we present the complete sequence and genomic structure of the Tcp-10a ^t gene which is compared with sequence data from a number of cDNAs and genomic subclones representing all active Tcp-10 ^t family genes. A detailed table of all sequence variants discovered in the course of our investigation is presented, and we have clarified the extent of 5 untranslated alternative splicing patterns exhibited by this gene family. A 60 base pair (bp) in-frame deletion from the 5 end of exon 3 of the Tcp-10a ^t gene is also presented and compared with the equivalent region of Tcp-10b ^t and Tcp-10c ^t. A search of the University of Edinburgh database has revealed a significant homology between the Tcp-10b ^t open reading frame and several cytosolic filament proteins. Interestingly, the region of homology is involved in the deletion from the Tcp-10a ^t gene.     

Expression of galectin-1 mRNA in the mouse uterus is under the control of ovarian steroids during blastocyst implantation

Galectin-1 is a member of β-galactoside-binding lectins expressed in a variety of mammalian tissues. We report here that galectin-1 mRNA is abundantly expressed in the mouse reproductive organs such as the uterus and ovary. Uterine expression of galectin-1 mRNA is specifically regulated in the embryonic implantation process. Its expression increased at a high level on the fifth day post coitum (dpc 5) when embryos hatched into the endometrial epithelial cells. In the absence of embryos, however, galectin-1 expression in the mouse uterus decreased on dpc 5. In the delayed implantation mice, galectin-1 mRNA level was augmented by the termination of the delay of implantation. Ovarian steroids progesterone and estrogen differentially regulated galectin-1 mRNA level in uterine tissues. Treatment with RU486, a progesterone receptor antagonist, blocked progesterone-induced galectin-1 mRNA level in uterine tissues of ovariectomized mouse. ICI182780, a pure estrogen receptor antagonist, clearly blocked the estrogen effect. Taken together, galectin-1 gene expression in the uterine tissues was regulated by ovarian steroids and this regulation correlated with the implantation process. Mol. Reprod. Dev. 48:261–266, 1997. © 1997 Wiley-Liss, Inc.     

Ascorbic Acid Reverses Valproic Acid-Induced Inhibition of <Emphasis Type="Italic">Hoxa2</Emphasis> and Maintains Glutathione Homeostasis in Mouse Embryos in Culture

Valproic acid (VPA) has been shown to cause neural tube defects in humans and mice, but its mechanism of action has not been elucidated. We hypothesize that alterations in embryonic antioxidant status and Hoxa2 gene expression play an important role in VPA-induced teratogenesis. A whole embryo culture system was applied to explore the effects of VPA on total glutathione, on glutathione in its oxidized (GSSG) and reduced (GSH) forms [GSSG/GSH ratio] and on Hoxa2 expression in cultured CD-1 mouse embryos during their critical period of organogenesis. Our results show that VPA can (1) induce embryo malformations including neural tube defects, abnormal flexion, yolk sac circulation defects, somite defects, and craniofacial deformities such as fusion of the first and second arches, and (2) alter glutathione homeostasis of embryos through an increase in embryonic GSSG/GSH ratio and a decrease in total GSH content in embryos. Western blot analysis and quantitative real-time RT-PCR show that VPA can inhibit Hoxa2 expression in cultured embryos at both the protein and mRNA level, respectively. The presence of ascorbic acid in the culture media was effective in protecting embryos against oxidative stress induced by VPA and prevented VPA-induced inhibition of Hoxa2 gene expression. Hoxa2 null mutant embryos do not exhibit altered glutathione homeostasis, indicating that inhibition of Hoxa2 is downstream of VPA-induced oxidative stress. These results are first to suggest VPA may, in part, exert its teratogenicity through alteration of the embryonic antioxidant status and inhibition of Hoxa2 gene expression and that ascorbic acid can protect embryos from VPA-induced oxidative stress.     

A novel serine/threonine kinase gene,Gek1, is expressed in meiotic testicular germ cells and primordial germ cells

We have isolated a novel serine/threonine kinase gene designated Gek1 from mouse primordial germ cell-derived embryonic germ cell. Gek1 is preferentially expressed in meiotic testicular germ cells and primordial germ cells. Gek1 mRNA is also detected in several other tissues, including hematopoietic organs in adult mice and central nervous system in embryos. The Gek1 cDNA encodes a protein with the consensus sequence of the catalytic domain of protein kinases in its N-terminal region. The deduced amino acid sequence of Gek1 in the kinase domain is related to those encoded by the Saccharomyces cerevisiae STE20, CDC15, and Drosophila melanogaster ninaC. The patterns of expression and the structural features of Gek1 suggest that the gene product is involved in signal transduction or nuclear division of germ cells and other proliferating cells. We also show that Gek1 locates on chromosome 11, near the wr locus, showing neuronal and reproductive defects. © 1996 Wiley-Liss, Inc.