Organization of the murine Ig-related lambda 5 gene transcribed selectively in pre-B lymphocytes.

lambda 5 is an immunoglobulin lambda light chain-related gene which is selectively transcribed in murine pre-B lymphocytes to yield a 1.2 kb poly(A)+ mRNA. Comparison of the nucleotide sequence of a 1 kb cDNA clone with the sequence of a genomic clone isolated from 70Z/3 murine pre-B lymphoma cells shows lambda 5 is composed of three exons spanning a 3.75 kb DNA segment. Conserved splice signal sequences at all exon/intron boundaries and the presence of a long open reading frame indicate that a functional mRNA molecule can be made. Exon I contains a cap-site and a potential ATG start codon as well as sequences encoding a signal peptide. This gene could encode a lambda 5 protein of 209 amino acids which has, however, not yet been identified. The 3' portion of exon II and all of exon III shows strong sequence homologies to J lambda L and C lambda L exons. Homology to the lambda L chain genes is lost in the 5' portion of exon II and throughout exon I. In exon I short homologies to leader sequences and to VH framework 1 sequences are seen.     

Myosin heavy chain isoform diversity in smooth muscle is produced by differential RNA processing

We have isolated and characterized two distinct myosin heavy chain cDNA clones from a neonatal rat aorta cDNA library. These clones encode part of the light meromyosin region and the carboxyl terminus of smooth muscle myosin heavy chain. The two rat aorta cDNA clones were identical in their 5' coding sequence but diverged at the 3' coding and in a portion of the 3' untranslated regions. One cDNA clone, RAMHC21, encoded 43 unique amino acids from the point of divergence of the two cDNAs. The second cDNA clone, RAMHC 15, encoded a shorter carboxyl terminus of nine unique amino acids and was the result of a 39 nucleotide insertion. This extra nucleotide sequence was not present in RAMHC21. The rest of the 3' untranslated sequences were common to both cDNA clones. Genomic cloning and DNA sequence analysis demonstrated that an exon specifying the 39 nucleotides unique to RAMHC15 mRNA was present, together with the 5' upstream common exons in the same contiguous stretch of genomic DNA. The 39 nucleotide exon is flanked on either side by two relatively large introns of approximately 2600 and 2700 bases in size. RNase protection analysis indicated that the two corresponding mRNAs were coexpressed in both vascular and non-vascular smooth muscle tissues. This is the first demonstration of alternative RNA processing in a vertebrate myosin heavy chain gene and provides a novel mechanism for generating myosin heavy chain protein diversity in smooth muscle tissues.     

Human gastric intrinsic factor: characterization of cDNA and genomic clones and localization to human chromosome 11

A human gastric intrinsic factor (IF) cDNA clone was isolated using a rat cDNA clone as a probe. Comparison of the predicted amino acid sequence revealed 80% identity of human IF with rat IF. These cDNA clones were used to isolate and map two overlapping clones encoding the human IF gene. The first exon of the cloned region (exon 2) contains 30 bp of the 5' untranslated region, the signal peptide, and the first 8 amino acids of the mature protein. Exons 3-10 encode the remainder of the coding and 3' noncoding regions. Southern analysis of genomic DNA indicated the presence of a single human IF gene and also revealed the presence of strong hybridizing sequences in genomic DNA from monkey, rat, mouse, cow, and human, suggesting that the IF gene is well conserved. The IF gene was localized to human chromosome 11 by concurrent cytogenetic and cDNA probe analysis of a panel of human X mouse somatic cell hybrids. Southern analysis of genomic DNA from patients with congenital pernicious anemia (lacking intrinsic factor) revealed normal restriction fragment patterns, suggesting that a sizable gene deletion was not responsible for the deficiency.     

Chicken vigilin gene organization and expression pattern. The domain structure of the protein is reflected by the exon structure.

Chicken vigilin was identified as a member of an evolutionary-conserved protein family with a unique repetitive domain structure. 14 tandemly repeated domains are found in chicken vigilin, all of which consist of a conserved sequence motif (subdomain A) and a potential alpha-helical region (subdomain B) [1]. We have established the physical structure of the chicken vigilin gene by restriction-fragment analysis and DNA sequencing of overlapping clones isolated from a phage lambda genomic DNA library. The chicken vigilin gene is a single-copy gene with a total of 27 exons which are distributed over a region of some 22 kbp. Exon 1 codes for a portion of the 5' untranslated region, exon 2 contains the translation start point and forms, along with exons 3 and 4, the N-terminal non-domain region. Exons 5-25 encode the vigilin domains 1-14 and the remaining exons 26 and 27 contain the non-domain C-terminal as well as the untranslated regions. The domain structure of the protein is reflected in the positioning of introns which demarcate individual domains. While domains 1-3 and 8-10 are each encoded by a single exon (5-7, 16-18); all other domains are contained in a set of two exons which are separated by introns interspersed at variable positions of the DNA segment coding for the conserved sequence motif. In conclusion, the data presented suggest that the chicken vigilin gene evolved by amplification of a primordial exon unit coding for the fundamental bipartite vigilin domain.     

Structure of the human hepatic triglyceride lipase gene

The structure of the human hepatic triglyceride lipase gene was determined from multiple cosmid clones. All the exons, exon-intron junctions, and 845 bp of the 5' and 254 bp of the 3' flanking DNA were sequenced. Comparison of the exon sequences to three previously published cDNA sequences revealed differences in the sequence of the codons for residues 133, 193, 202, and 234 that may represent sequence polymorphisms. By primer extension, hepatic lipase mRNA initiates at an adenine 77 bases upstream of the translation initiation site. The hepatic lipase gene spans over 60 kb containing 9 exons and 8 introns, the latter being all located within the region encoding the mature protein. The exons are all of average size (118-234 bp). Exon 1 encodes the signal peptide, exon 4, a region that binds to the lipoprotein substrate, and exon 5, an evolutionarily highly conserved region of potential catalytic function, and exons 6 and 9 encode sequences rich in basic amino acids thought to be important in anchoring the enzyme to the endothelial surface by interacting with acidic domains of the surface glycosaminoglycans. The human lipoprotein lipase gene has been recently reported to have an identical exon-intron organization containing the analogous structural domains [Deeb & Peng (1989) Biochemistry 28, 4131-4135]. Our observations strongly support the common evolutionary origin of these two lipolytic enzymes.     

The genomic organization of the rat AT1 angiotensin receptor.

The AT1 receptor subtype modulates all of the hemodynamic effects of the vasoactive peptide, angiotensin II. In this report, we investigate the genomic organization of this important receptor. A rat genomic library was screened with fragments from the 5' region of a previously cloned cDNA, pCa18b, encoding the rat AT1 receptor. Two lambda clones were isolated and the hybridizing restriction fragments were sequenced. Comparison of the genomic and cDNA sequences reveals that the rat AT1 receptor has three exons. Two of the exons encode 5' untranslated sequence while the third exon encompasses the entire coding region, a small portion of the 5' untranslated region and the entire 3' untranslated sequence. Further analysis of the genomic sequence 5' to the start site of pCa18b demonstrates typical sequence motifs found in many eukaryotic promoters including a TATA box, a cap site and a potential Sp1 binding site. Southern analysis of genomic DNA indicates that the AT1 receptor subtype represented by pCa18b is encoded by one gene within the rat genome.     

Inhibition of calpain by a synthetic oligopeptide corresponding to an exon of the human calpastatin gene

Calpastatin is a widely distributed endogenous inhibitor protein specifically acting on calpain (Ca2+-dependent cysteine endopeptidase). The inhibitor consists of four inhibitory domains (Domains 1-4) with mutually homologous sequences. NH2-terminal Domain L is non-homologous, and all domains have 120-140 residues each. A human calpastatin genomic DNA clone was isolated using a previously obtained human calpastatin cDNA probe. Sequence analysis has revealed that the clone contains Domain 1 and segments of neighboring domains (Domains L and 2). Each of three highly conserved, restricted regions within Domain 1 was located on separate exons, 1A, 1B, and 1C. Exon 2A, corresponding to the first exon of Domain 2, is homologous to Exon 1A and follows Exon 1D of Domain 1. A 27-residue peptide encoded by Exon 1B, including a 12-residue middle conserved sequence, was chemically synthesized and tested for protease inhibitory activities. The synthetic peptide showed strong inhibition against calpain I (low Ca2+-requiring form), and calpain II (high Ca2+-requiring form), but no inhibition against papain or trypsin. These results indicated that Exon 1B forms a self-sufficient functional subdomain of the calpastatin inhibitory domain.     

The bovine chromogranin A gene: structural basis for hormone regulation and generation of biologically active peptides.

The structure of the gene encoding bovine chromogranin-A has been determined by characterization of two isolated genomic clones. Chromogranin-A is encoded by eight exons, which organize the coding region into several distinct structural and functional domains. Exons 1-5 represent the highly conserved signal peptide and N-terminal domain, which are separated into regions corresponding to the signal peptide, N-terminal sequence, disulfide-bonded loop, and remainder of the conserved N-terminal domain. Exon 6 represents the variable domain and encodes a region that is identical to the novel chromogranin-A-derived peptide chromostatin. Exon 7 encodes the biologically active peptide pancreastatin as well as most of the conserved C-terminal domain, with the remainder found on exon 8. The mRNA sequence obtained from the gene contains five nucleotide differences from the consensus sequence of four reported bovine chromogranin-A cDNA clones. Two of the differences in the gene result in two amino acid changes in the region encoded by exon 6. The structural organization of the chromogranin-A gene resembles that of the chromogranin-B gene in the exons corresponding to the signal peptide, N-terminal sequence, disulfide loop, and C-terminal sequence.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization of the rat proenkephalin gene

The rat proenkephalin gene has been isolated by molecular cloning and characterized by DNA-sequence analysis. The gene exhibits a structural organization similar to that of the human gene. The nucleotide sequence encoding the biologically active opioid peptides which are generated from the proenkephalin precursor as well as the 3' untranslated region of the mRNA are found on a large exon at the 3' end of the gene (Exon III). The nucleotide sequence encoding the N terminus of the mature protein and its signal peptide are located on Exon II while Exon I encodes the 5' untranslated region of the mRNA. The nucleotide sequence of these exons and their flanking regions has been determined and compared to the human proenkephalin gene. Analysis of the nucleotide sequence homology between the human and rat proenkephalin gene reveals the presence of highly conserved regions within both the coding and noncoding portions of the genes. Enkephalin-coding sequences as well as 5' flanking sequences appear to be the most highly conserved. The importance and possible function of these sequences are discussed.     

Characterization of diverse forms of myosin heavy chain expressed in adult human skeletal muscle.

In an attempt to define myosin heavy chain (MHC) gene organization and expression in adult human skeletal muscle, we have isolated and characterized genomic sequences corresponding to different human sarcomeric MHC genes (1). In this report, we present the complete DNA sequence of two different adult human skeletal muscle MHC cDNA clones, one of which encodes the entire light meromyosin (LMM) segment of MHC and represents the longest described MHC cDNA sequence. Additionally, both clones provide new sequence data from a 228 amino acid segment of the MHC tail for which no protein or DNA sequence has been previously available. One clone encodes a "fast" form of skeletal muscle MHC while the other clone most closely resembles a MHC form described in rat cardiac ventricles. We show that the 3' untranslated region of skeletal MHC cDNAs are homologous from widely separated species as are cardiac MHC cDNAs. However, there is no homology between the 3' untranslated region of cardiac and skeletal muscle MHCs. Isotype-specific preservation of MHC 3' untranslated sequences during evolution suggests a functional role for these regions.