Phylogenetic conservation of immunoglobulin heavy chains: direct comparison of hamster and mouse Cmu genes.

We have analyzed the JH-Cmu locus of the Syrian hamster by DNA cloning and sequencing. The single Cmu gene is highly homologous to that of the mouse. The hamster equivalents of the JH and switch (S) recombination regions are arranged as in the mouse, but surprisingly are not highly conserved. Also unlike its close murine relative, the Smu regions among inbred hamster strains are not polymorphic. The complete nucleotide sequence of hamster and mouse Cmu genes have been compared to partial Cmu sequences of other species. Conservation within a portion of the 3' untranslated region may signify functional requirements for 3' end processing. Mutational frequencies within exons and introns of hamster and mouse do not support the theory that the rate of DNA transitions to transversions decreases with evolutionary distance.     

5' LTR complete nucleotide sequence of Chinese hamster intracisternal A-particle.

Retrovirus like sequences homologous to mouse IAP are present in Chinese hamster genome (Lueders K.K. and Kuff, E.L., 1981, 1983, Servenay et al., 1990). Murine IAP long terminal repeats (LTRs) can function as effective promoters in different cell types (Horowitz M. et al., 1984, Howe, C.C. et al., 1986). Thus CHO IAP sequences could act as retrotransposons in the cellular genome, and in this way affect the expression of other genes at the target sites. We had sequenced previously a Chinese hamster IAP genomic region corresponding mainly to the gag gene and including 57 nucleotides of U5 5' LTR (Servenay et al., 1988). In this paper, we present the 5' LTR complete nucleotide sequence of the Chinese hamster IAP element and its comparison with those of mouse and Syrian hamster.     

Mouse histone H2A and H2B genes: four functional genes and a pseudogene undergoing gene conversion with a closely linked functional gene.

The sequence of five mouse histone genes, two H2a and three H2b genes on chromosome 13 has been determined. The three H2b genes all code for different proteins, each differing in two amino acids from the others. The H2b specific elements present 5' to H2b genes from other species are present in all three mouse H2b genes. All three H2b genes are expressed in the same relative amounts in three different mouse cell lines and fetal mice. The H2b gene with the H2b specific sequence closest to the TATAA sequence is expressed in the highest amount. One of the H2a genes lacks the first 9 amino acids, the promoter region, the last 3 amino acids and contains an altered 3' end sequence. Despite these multiple defects, there is only one nucleotide change between the two H2a genes from codon 9 to 126. This indicates that a recent gene conversion has occurred between these two genes. The similarity of the nucleotide sequences in the coding regions of mouse histone genes is probably due to gene conversion events targeted precisely at the coding region.     

Clusters of genes encoding mouse transplantation antigens

We constructed a cosmid library from BALB/c mouse sperm DNA and isolated 64 cosmid clones with cDNA probes for transplantation antigens (class I molecules). Of these clones, 54 mapped into 13 gene clusters containing 36 distinct class I genes and encompassing 837 kilobases of DNA. One gene cluster mapped to the L region and a second cluster with seven genes to the Qa-2,3 region of the major histocompatibility complex. Restriction map and Southern blot analyses suggest that there are subgroups of class I genes. Using a 5' flanking sequence of the L gene as a hybridization probe, we show the L gene to be present in mouse strains expressing this antigen but deleted or mutated in strains failing to express it. Our data suggest that gene duplication and deletion presumably by homologous but unequal crossing-over has altered the size and organization of the class I clusters in different mouse strains and probably is an important mechanism for generating polymorphism in these genes. Analysis of the 36 class I genes with cDNA probes specific for the 5' and 3' ends shows that the exon encoding the third external domain is far more conserved than those encoding the first and second external domains of the transplantation antigen. These differences in variability have interesting functional implications.     

Comparison of the sequence organization of related retrovirus-like multigene families in three evolutionarily distant rodent genomes.

Sequences related to mouse intracisternal A-particle (IAP) genes have been isolated from rat and Syrian hamster gene libraries as recombinants in lambda phage. The sequences are moderately reiterated in both these genomes but their sequence organization in the hamster genome is different from that in the rat genome. Restriction analysis and electron microscopy indicate that the Syrian hamster IAP sequences represent a family of relatively homogeneous well-conserved units; in this, they resemble the mouse IAP genes. The rat sequences, in contrast, are heterogeneous. Both the hamster and rat IAP sequences contain regions homologous to mouse IAP genes interspersed with regions of apparent non-homology. The interspersed regions range in size from 0.5-1.0 kilobases (Kb). The regions of homology among the mouse, rat and Syrian hamster IAP sequences have been mapped to a 5-6 Kb internal region on the mouse IAP genes. Mouse IAP long terminal repeat (LTR) sequences were not detected in the rat and Syrian hamster genomes. We used the thermal stability of hybrids between cloned and genomic IAP sequences to measure family homogeneity. Mouse and Syrian hamster IAP sequences are homogeneous by this criterion, but the rat IAP sequences are heterogeneous with a Tm 6 degrees C below the self-hybrid. The contrasting organization of IAP-related elements in the genomes of these rodents indicates that amplification or homogenization of this sequence family has occurred independently and at different periods of time during their evolution.     

Human dihydrofolate reductase gene organization. Extensive conservation of the G + C-rich 5' non-coding sequence and strong intron size divergence from homologous mammalian genes

The complete human dihydrofolate reductase (DHFR) gene has been cloned from four recombinant lambda libraries constructed with the DNA from a methotrexate-resistant human cell line with amplified DHFR genes. The detailed organization of the gene has been determined by restriction mapping of the cloned fragments and DNA sequencing of all the protein coding regions and adjacent intron segments, and shown to correspond to that of the native human DHFR gene. The gene spans a length of approximately 29 X 10(3) bases from the ATG initiator codon to the end of the 3' untranslated region, and contains five introns that interrupt the protein coding sequence. The number and positions of introns are identical to those found in the mouse gene. By contrast, the size of the homologous introns (with the exception of the first one) varies greatly, up to several fold, in the genes from man, mouse and Chinese hamster; the intron sequences also exhibit a great divergence, except in the junction regions. A striking sequence homology, extending over several hundred nucleotides, exists between the human and mouse gene 5' non-coding regions. These regions are characterized by an unusually high G + C content, 72% and 66% in the human and mouse genes, respectively, which is maintained in the first coding segment and first intron, and is in sharp contrast to the relatively low G + C content (approximately 40%) of the remainder of the gene.     

Comparative structure of two duplicated T1a class I genes (T10c and 37) of the murine H-2d MHC. Implications on the evolution of the T1a region

The class I Ag encoded in the Qa/T1a regions of the murine MHC are much less polymorphic, and usually have a more restricted tissue distribution than the classical histocompatibility class I Ag, encoded by genes located in the H-2K, D, and L loci. The isolation of a quasi-ubiquitously expressed, poorly polymorphic class I gene of the T1a region of the H-2d mouse MHC, namely gene 37 (or T18d), has been recently reported. We describe the nucleotide sequence of a closely related gene, T10c gene, the counterpart of the gene 37 in the large duplicated parts of T1a region of the BALB/c (H-2d) MHC. The T10c gene structure and sequence are very similar to those of gene 37, but T10c gene is most likely a pseudogene. In A/J mouse strain, there appears to be a single gene related to 37, which is also found expressed in a variety of tissues. We show that this gene is likely to be a chimeric one derived from T10c for its 3' part, and from a gene closely related to gene 37 for its 5' part, which potentially encodes for an unusual class I molecule composed of the first two domains. Finally, Southern blot analysis of a number of wild mice and related animals suggests that a gene closely related to the present T10c gene may be the ancestor of this subfamily of class I genes characterized by the presence of an unusual second domain.     

Cloning and sequence comparison of the mouse, human, and chicken engrailed genes reveal potential functional domains and regulatory regions.

We have isolated and characterized genomic DNA clones for the human and chicken homologues of the mouse En-1 and En-2 genes and determined the genomic structure and predicted protein sequences of both En genes in all three species. Comparison of these vertebrate En sequences with the Xenopus En-2 [Hemmati-Brivanlou et al., 1991) and invertebrate engrailed-like genes showed that the two previously identified highly conserved regions within the En protein ]reviewed in Joyner and Hanks, 1991] can be divided into five distinct subregions, designated EH1 to EH5. Sequences 5' and 3' to the predicted coding regions of the vertebrate En genes were also analyzed in an attempt to identify cis-acting DNA sequences important for the regulation of En gene expression. Considerable sequence similarity was found between the mouse and human homologues both within the putative 5' and 3' untranslated as well as 5' flanking regions. Between the mouse and Xenopus En-2 genes, shorter stretches of sequence similarity were found within the 3' untranslated region. The 5' untranslated regions of the mouse, chicken and Xenopus En-2 genes, however, showed no similarly conserved stretches. In a preliminary analysis of the expression pattern of the human En genes, En-2 protein and RNA were detected in the embryonic and adult cerebellum respectively and not in other tissues tested. These patterns are analogous to those seen in other vertebrates. Taken together these results further strengthen the suggestion that En gene function and regulation has been conserved throughout vertebrate evolution and, along with the five highly conserved regions within the En protein, raise an interesting question about the presence of conserved genetic pathways.