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.     

Cloning of cDNA encoding rat TCP-1.

We have isolated and sequenced a cDNA encoding a rat homolog of the mouse t-complex polypeptide 1 (TCP-1). Its deduced gene product is a polypeptide of 556 amino acids, with a predicted Mr of 60,341. The similarity between mouse Tcp-1 and the rat homolog is about 94.0% at the nucleotide level and 97.1% at the amino acid level showing the evolutionary conservation of this protein. The similarity of the amino acid sequence of the rat TCP-1 is not significantly biased to any of those from wild (TCP-1B) or from t-haplotype mice (TCP-1A). From a comparison of deduced amino acid sequences of eukaryotic TCP-1 proteins, we found highly conserved domains. Southern blot analysis revealed that there are at least two similar sequences to Tcp-1 in the rat, one is a structural gene and the other seems to be a processed pseudogene.     

A Drosophila melanogaster gene encodes a protein homologous to the mouse t complex polypeptide 1

We have isolated and sequenced a cDNA from Drosophila melanogaster that is homologous to the mouse Tcp-1 gene encoding the t complex polypeptide 1, TCP-1. The Drosophila gene maps by in situ hybridization to bands 94B1-2 of the polytene chromosomes. It shares 66% nucleotide sequence identity with the mouse gene. The predicted Drosophila protein consists of 557 amino acids and shares 72% identity with the mouse polypeptide. The TCP-1 polypeptide appears to be highly conserved in evolution from mammals to simple eukaryotes because the Drosophila gene probe also detects related sequences in DNA from the yeast, Saccharomyces cerevisiae. The presence of TCP-1-related polypeptides in organisms such as Drosophila and yeast should facilitate biochemical and genetic analysis of its function.     

Nucleotide sequence analysis of the C.AKR Lyt-2 agene: structural polymorphism in alleles encoding the Lyt-2.1 T-cell surface alloantigen

The Lyt-2 ^aallele of the C.AKR strain of mice (genotype Lyt-2 ^a, Lyt-3 ^a) was cloned, and its complete nucleotide sequence as well as that of 2 kb of 5 flanking DNA was determined. The sequence was comapred with the partial sequence of the Lyt-2 ^aallele of DBA/2 (genotype Lyt-2 ^a, Lyt-3 ^b) and the nearly complete sequence of the B10.CAS2 Lyt-2 ^ballele reported by Liaw and coworkers (1986). The coding regions of the two Lyt-2 ^aalleles differ from each other by two nucleotide substitutions in the three exons over which they could be compared, resulting in two amino acid substitutions in the leader and transmembrane segments. The coding region of the C.AKR Lyt-2 ^aallele differs from the Lyt-2 ^ballele by two nucleotide substitutions in the extracellular V-like domain, one of which is silent and the second of which leads to substitution of valine for methionine at amino acid position 78 giving rise to the Lyt-2.1 allotypic specificity. The coding region of the DBA/2 Lyt-2 ^aallele shares with C.AKR the allotypic substitution at position 78 and differs from Lyt-2 ^bby three additional nucleotide substitutions in the coding regions, two of which lead to amino acid substitutions in the leader and transmembrane segments. It would therefore appear that the Lyt-2 alleles of the three strains analyzed are distinct, and the nomenclature Lyt-2 ^a1 and Lyt-2 ^a2 is suggested to distinguish the alleles of C.AKR and DBA/2, respectively. These alleles share a common difference from the Lyt-2 ^bgene product at position 78, and since the amino acid substitutions which distinguish them from each other are in the leader and transmembrane segments, their mature Lyt-2 gene products appear antigenically identical.     

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.     

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.     

Identification and molecular characterization of a novel y-type Glu-Dt 1 glutenin gene of Aegilops tauschii

A novel y-type high-molecular-weight glutenin subunit possessing a slightly faster mobility than that of subunit 1Dy12 in SDS-PAGE, designated 1Dy12.1^t in Aegilops tauschi, was identified by one- and two-dimensional gel and capillary electrophoresis. Its coding gene at the Glu-D ^t 1 locus was amplified with allele-specific-PCR primers, and the amplified products were cloned and sequenced. The complete nucleotide sequence of 2,807 bp containing an open reading frame of 1,950 bp and 857 bp of upstream sequence was obtained. A perfectly conserved enhancer sequence and the –300 element were present at positions of 209–246 bp and 424–447 bp upstream of the ATG start codon, respectively. The deduced mature protein of 1 Dy12.1^t subunit comprised 648 amino acid residues and had a Mr of 67,518 Da, which is slightly smaller than the 1Dy12 (68,695 Da) but larger than the 1Dy10 (67,495 Da) subunits of bread wheat, respectively, and corresponds well with their relative mobilities when separated by acid-PAGE. The deduced amino acid sequence indicated that the 1Dy12.1^t subunit displayed a greater similarity to the 1Dy10 subunit, with only seven amino acid substitutions, suggesting that this novel gene could have positive effect on bread-making quality. A phenetic tree produced by nucleotide sequences showed that the x- and y-type subunit genes were respectively clustered together and that the Glu-D ^t 1y12.1 gene of Ae. tauschii is closely related to other y-type subunit genes from the B and D genomes of hexaploid bread wheat.Communicated by H.F. Linskens     

Molecular evolution of mammalian lactate dehydrogenase-A genes and pseudogenes: association of a mouse processed pseudogene with a B1 repetitive sequence

A mouse genomic clone containing a lactate dehydrogenase-A (LDH-A) processed pseudogene and a B1 repetitive element was isolated, and a nucleotide sequence of approximately 3 kb was determined. The pseudogene and B1 element are flanked by perfect 13-bp repeats, and the B1 sequence starts at 14 nucleotides 3' to the presumptive polyadenylation signal of the pseudogene. The nucleotide sequences of the LDH-A genes and processed pseudogenes from mouse, rat, and human were compared, and a phylogenetic tree was constructed. The rate and pattern of nucleotide substitutions in the LDH-A pseudogenes are similar to previously reported results (Li et al. 1984). The average rate of nucleotide substitutions in the LDH-A pseudogenes is 4.3 X 10(- 9)/site/year. The substitutions of C----T and G----A are most frequent, and A----G substitutions are relatively high. The rate of synonymous substitutions in the LDH-A genes is 5.3 X 10(-9), which is not significantly higher than the average rate of 4.7 X 10(-9) for 35 mammalian genes. The rate of nonsynonymous substitutions in the LDH-A genes is 0.20 X 10(-9), which is considerably lower than the average rate of 0.88 X 10(-9) for 35 mammalian genes. Thus, the mammalian LDH-A gene appears to be highly conserved in evolution.      

Sequence characterization of alleles Gpi1-s a and Gpi1-s b at the glucose phosphate isomerase structural locus

The sequences of alleles Gpil-s ^a and Gpi1-s ^b at the glucose phosphate isomerase structural locus have been determined from cDNA of the mouse inbred strains 101/H Gpi1-s ^a and C3H/HeH Gpi1-s ^b by TR PCR and direct sequencing of the amplified products. Four individual nucleotide differences were observed between the two alleles. The difference at amino acid residue 94, (Gpi1-s ^a GAT Asp, Gpi1-s ^b AAT Asn) may account for the differing electrophoretic migration, isoelectric point, and thermostability of the two alleles. Two of the other observed differences in the coding region (amino acid residue 12 Leu, Gpi1-s ^a CTC, Gpi1-s ^b CTG and amino acid residue 17 Arg, Gpi1-s ^a CGC, Gpi1-s ^b CGT) are silent and do not affect the predicted amino acid residues on translation. The fourth observed difference is located within the 3 noncoding sequences of the cDNA. The change at amino acid residue 94 is associated with the presence of a Hinf1 restriction site in Gpi1-s ^b, which is absent in Gpi1-s ^a, and may be a useful method for determining this marker.     

Chromosome 14 in B10.A(18R) mice is recombinant and includes Tcra-V a alleles

Analysis of mouse Tcr genes has previously defined at least five different Tcra-V haplotypes among inbred strains of mice. For mice of the Tcra-V ^b haplotype, including C57BL/10 (B10), T-cell expression of the Tcra-V11 gene subfamily can be detected with a monoclonal antibody, 1.F2. In the course of further characterizing the specificity of 1.F2, we found that it fails to recognize Tcra-V11-expressing T-cell hybrids derived from the B10 congenic strain, B10.A(18R)/SgIcr. Moreover, staining analysis indicated that the Va11 epitope recognized by 1.F2 is not expressed by peripheral T cells from several different B10.A(18R) colonies with the exception of that at the Research Institute of Scripps Clinic. Nucleotide sequences were determined for cDNA representing rearranged Tcra-V11 genes from two independent, B10.A(18R)/SgIcr derived T-cell hybrids. The two Tcra-V11 gene segments were identical and the predicted amino acid sequence differed by at least five residues from Tcra-V11 sequences previously obtained from B10.A mice. Southern blot analysis of restriction fragment length polymorphisms (RFLP) associated with Tcra-V11, as well as Tcra-V ₁ , subfamily genes revealed that the B10.A(18R) mouse has inherited Tcra-V ^a alleles rather than the expected Tcra-V ^b alleles from the B10 strain. RFLP analysis of the Rib-1 locus, located in close proximity to the Tcra locus on chromosome 14, showed that B10.A(18R) carries the Rib-1 ^b allele from B10. These results indicate that the B10.A(18R) mouse has inherited a recombinant chromosome 14 with a recombination event having occured between the Rib-1 locus and the Tcra-V ^a gene subfamilies examined. Inheritance of Tcra-V ^a alleles in B10.A(18R) probably originated from strain 129/J which breeding records show was used in the first cross with B10.A in the production of B10.A(18R) and which we found exhibits Tcra-V11 ^a RFLPs.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M55634 and M55635. Address correspondence and offprint requests to: P. B. Nakajima.     

A gene product of the mouse t complex with chemical properties of a cell surface-associated component of the extracellular matrix

p63/6.9 is a major testicular cell protein coded for by a gene, called Tcp-1, within the mouse t complex. All wild-type chromosomes carry the Tcp-1^b allele which codes for a basic form of this protein, while all complete mutant t haplotypes carry the Tcp-1^a allele which codes for an acidic form of this protein. Genetic studies have demonstrated a correlation between the Tcp-1 gene and certain t haplotype effects on sperm differentiation and maturation. In this report, an initial biochemical analysis of the p63/6.9 protein is presented. The data provide evidence that p63/6.9 is closely associated with the external surface of testicular cells but not as an integral membrane component. Some properties of the testicular form of this t complex gene product are similar to those reported for the matrix proteins fibronectin and laminin. The possibility is suggested that primary effects of t haplotypes on sperm differentiation could be exerted through the extracellular matrix. p63/6.9 is also present at a lower level within the cytoplasm and membranes of F9 teratocarcinoma cells. It appears that the level of p63/6.9 synthesis and the exact nature of p63/6.9 intra- and/or intermolecular interactions are under tissue-specific control.     

Two distinct subtypes of theHLA-DRw12 haplotypes in the Japanese population detected by nucleotide sequence analysis and oligonucleotide genotyping

We determined the DNA sequence of the enzymatically amplified second exon of theDRB1 gene of theDRw12 haplotypes derived from three Japanese donors and found two distinct subtypes of theDRw12 haplotype. The two subtypes, designatedDRw12a andDrw12b, had single-base substitutions that predicted one amino acid change at residue number 67. The sequence of theDrw12a andDRw12b subtypes differed from those of the otherDR haplotypes, but in the first hypervariable region of theDRB1 gene the sequences were identical to those of theDRw8(Dw8.1) andDRw8(Dw8.3) haplotypes. TheDRw12a andDRw12b subtypes were detected in a wide range of Japanse donors by genotyping with sequence-specific oligonucleotide probes synthesized according to the DNA sequence of the two subtypes. Results of this study demonstrated that theDRw12 haplotypes in the Japanese population are genetically diverse, as many otherDR haplotypes are. The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M27509, M27510, M27511.     

Cloning of large-conductance Ca-activated K channel α-subunits in mouse cardiomyocytes

Large-conductance Ca²⁺-activated K⁺ (BK_Ca) channels are widely distributed in cellular membranes of various tissues, but have not previously been found in cardiomyocytes. In this study, we cloned a gene encoding the mouse cardiac BK_Ca channel α-subunit (mCardBKa). Sequence analysis of the cDNA revealed an open reading frame encoding 1154 amino acids. Another cDNA variant, identical in amino acid sequence, was also identified by sequence analysis. The nucleotide sequences of the two mCardBKa cDNAs, type 1 (mCardBKa1) and type 2 (mCardBKa2), differed by three nucleotide insertions and one nucleotide substitution in the N-terminal sequence. The amino acid sequence demonstrated that mCardBKa was a unique BK_Ca channel α-subunit in mouse cardiomyocytes, with amino acids 41-1153 being identical to calcium-activated potassium channel SLO1 and amino acids 1-40 corresponding to BK_Ca channel subfamily M alpha member 1. These findings suggest that a unique BK_Ca channel α-subunit is expressed in mouse cardiomyocytes.     

Structural and evolutionary comparisons of four alleles of the mouse Igk-J locus which encodes immunoglobulin kappa light chain joining (J K ) segments

The Igk-J locus of the mouse encodes the immunoglobulin light chain joining (J) segments. Four Igk-J alleles have been described on the basis of restriction enzyme length polymorphisms. The nucleotide sequences of the Igk-J ^a allele (type strain, C.C58), Igk-J ^c allele (type strain, SJL/J), and Igk-J ^d allele (type strain, SK/CamRk) have been determined and are compared with the previously reported Igk-J ^b allele sequence (type strain, BALB/c). The mouse sequences are also compared with published sequences for rat and human J _k sequences. Far more differences were found between the Igk-J ^a allele and the other mouse alleles than between any two of the latter. These result in two amino acid substitutions which distinguish the J2 and J3 ¹ segments of the Igk-J ^a allele from the other three alleles. Use of the Phylogenetic Analysis Using Parsimony program to generate a phylogenetic tree strongly indicates that after divergence from the rat ancestor, there appears to have been an early split between the Igk-J ^a allele and the evolutionary precursor of the other mouse alleles. There also appears to have been far less divergence from the ancestral condition in the Igk-J ^a allele than in the other alleles. Also, the presence of only one convergent mutation among the four mouse alleles provides strong evidence against any crossing over within the Igk-J locus during the history of these alleles. Finally, the differences in rates of evolution of the Igk-J alleles are in marked contrast to the relatively uniform rates of divergence of four alleles of a mouse V _k gene, Igk-VSer.     

Functional analysis of a t complex responder locus transgene in mice

Transmission ratio distortion (TRD) of mouse t haplotypes occurs through the interaction of multiple distorter loci with the t complex responder (Tcr) locus. Males heterozygous for a t haplotype will transmit the t-bearing chromosome to nearly all of their offspring. This process is mediated by the production of functionally inequivalent gametes: wildtype meiotic partners of t spermatozoa are rendered functionally inactive. The Tcr locus, which is required for TRD to occur, is thought to somehow protect its host spermatid from the sperm-inactivating effects of linked distorter genes (Lyon 1984). In previous work, Tcr was mapped to a small genetic interval in t haplotypes, and a candidate gene from this region was isolated (Tcp-10b ^t). In this work, we further localize Tcr to a 40-kb region that contains the 21-kb Tcp-10b ^t gene. A cloned genomic copy of Tcp-10b ^t was used to generate transgenic mice. The transgene was bred into a variety of genetic backgrounds to test for non-Mendelian segregation. Abberrant segregation was observed in some mice carrying either a complete t haplotype or a combination of certain partial t haplotypes. These observations, coupled with those of Snyder and colleagues (in this issue), provide genetic and functional evidence that the Tcp-10b ^t gene is Tcr. However, other genotypes that were predicted to produce distortion did not. The unexpected data from a variety of crosses in this work and those of our colleagues suggest that elements to the TRD system and the Tcr locus remain to be identified.     

Mouse eosinophil-associated ribonucleases: a unique subfamily expressed during hematopoiesis

A unique family of ribonucleases was identified by exhaustive screening of genomic and cDNA libraries using a probe derived from a gene encoding a ribonuclease stored in the mouse eosinophil secondary granule. This family contains at least 13 genes, which encode ribonucleases, and two potential pseudogenes. The conserved sequence identity among these genes (∼70%), as well as the isolation/purification of these ribonucleases from eosinophil secondary granules, has led us to conclude that these genes form a unique clade in the mouse that we have identified as the Ear (Eosinophil-associated ribonuclease) gene family. Analyses of the nucleotide substitutions that have occurred among these ribonuclease genes reveal that duplication events within this family have been episodic, occurring within three unique periods during the past 18 × 10⁶ years. Moreover, comparisons of non-synonymous (K_a) vs. synonymous (K_s) rates of nucleotide substitution show that although these genes conserve residues necessary for RNase activity, selective evolutionary pressure(s) exist such that acquired amino acid changes appear to be advantageous. The selective advantage of these amino acid changes is currently unclear, but the occurrence of this phenomenon in both the mouse and the human highlights the importance of these changes for Ear and, therefore, eosinophil effector function(s). Received: 25 October 2000 / Accepted: 18 December 2000