Structural organization of the gene for the alpha 1 chain of human type IV collagen

The complete exon size and distribution pattern in the gene for the alpha 1 chain of human type IV collagen was determined. Clones covering 145 kilobases (kb) of genomic DNA including 100 kb of the gene itself as well as 25 kb upstream and 20 kb downstream of the gene sequences, respectively, were isolated from lambda phage and cosmid libraries. The overall gene structure was determined by endonuclease restriction mapping and R-loop analyses and all exon sizes by nucleotide sequencing. The characterized clones contained all the coding sequences except for exon 2 whose sequence was determined after its amplification by the polymerase chain reaction. There were four gaps in the intron sequences; the exact size of the gene is unknown. The entire gene is at least 100 kb in size and contains 52 exons whose size distribution is completely different from that of the genes for fibrillar collagens. In the -Gly-X-Y- coding region there are three exons of 99, 90, and 45 base pairs (bp) each and two exons of 27, 36, 42, 51, 54, 63, and 84 bp each. The rest of the exons have sizes between 71 and 192 bp in the collagenous region. About one-half of the -Gly-X-Y- repeat coding exons start with the second base for the codon of glycine, whereas the other half starts (with two exceptions) with a complete glycine codon. The distribution of split versus unsplit codons is uneven in that the first 19 exons of the gene start with a complete codon. The gene contains repetitive sequences in several regions. A 185-nucleotide segment containing 40 copies of CCT flanked by poly(C) and poly(T) sequences was shown to be located adjacent to an exon. The gene has previously been shown to be located head-to-head to the alpha 2(IV) collagen gene at the distal end of the long arm of chromosome 13, such that the first exons of the two genes are separated by as little as 42 bp (P?schl, E., Pollner, R., and Kühn, K. (1988) EMBOJ. 7,2687-2695; Soininen, R., Huotari, M., Hostikka, S. L., Prockop, D. J., and Tryggvason, K. (1988) J. Biol. Chem. 263, 17217-17220). The results demonstrate that the human alpha 1(IV) collagen gene has a structure distinctly different from the genes for fibrillar collagens and also that it is considerably larger than any collagen gene characterized to date.     

Identification of novel splice variants of the human CD44 gene

The CD44 gene contains 10 variable exons (v1-v10) that can be alternatively spliced to generate hundreds of different CD44 protein isoforms, several of which have been implicated in the metastatic spread of tumour cells. Here, we describe a cryptic splice site, in intron 6 of the human CD44 gene, used during mRNA processing. This cryptic splice site is used in conjunction with variable exon 3, or independently from it in the form of a pseudo-exon of 49 bp, which generates a stop codon by frame shift in the contiguous variable exon downstream. This pseudo-exon has been found inserted immediately 3' to any other variable exon from v4 to v10, in the final CD44 mRNA. The implication of this cryptic splice site in haltering CD44 protein translation is questioned in the context of Nonsense Mediated Decay and the overall regulation of CD44 expression.     

The divergent 5' ends of DPM2 mRNAs originate from the alternative splicing of two adjacent introns: characterization of the hamster DPM2 gene

Mammalian dolichol-phosphate-mannose (DPM) synthase has three subunits, DPM1, DPM2, and DPM3. In this report, an analysis of the gene and cDNAs of hamster DPM2 is presented. The CHO DPM2 gene has two special features. First, the initiation codon ATG is separated from the remainder of the coding region by intron sequences. Second, within these intron sequences the DPM2 gene contains an adjacent 3' splice site (acceptor) and a 5' splice site (donor), suggestive of a deleted exon between the first and second codons. In fact, these sites overlap by four nucleotides (nt) of AGGT. Splicing intermediates using both of these alternative splice sites were observed. This latter feature appears unique and is particularly unusual considering the relatively small size of the gene (2.7 kb) and of introns a (123 bp) and b (152 bp).     

Genomic Structure of the Human Gene for Spinocerebellar Ataxia Type 2 (SCA2) on Chromosome 12q24.1

Spinocerebellar ataxia type 2 (SCA2) is a member of a group of neurodegenerative diseases that are caused by instability of a DNA CAG repeat. We report the genomic structure of theSCA2gene. Its 25 exons, encompassing approximately 130 kb of genomic DNA, were mapped onto the physical map of the region. Exonic sizes varied from 37 to 890 bp, and intronic sizes ranged from 323 bp to more than 15 kb. The CAG repeat was contained in the 5′ coding region of the gene in exon 1. Determination of the splice junction sequences indicated the presence of only one deviation from the GT-AG rule at the donor splice site of intron 9, which contained a GC instead of a GT dinucleotide. Exon 10, immediately downstream from this rare splice donor site, was alternatively spliced. Alternative splicing does not affect the reading frame and is predicted to encode an isoform containing 70 amino acids less.     

Evolution of collagen IV genes from a 54-base pair exon: A role for introns in gene evolution

The exon structure of the collagen IV gene provides a striking example for collagen evolution and the role of introns in gene evolution. Collagen IV, a major component of basement membranes, differs from the fibrillar collagens in that it contains numerous interruptions in the triple helical Gly-X-Y repeat domain. We have characterized all 47 exons in the mouse alpha 2(IV) collagen gene and find two 36-, two 45-, and one 54-bp exons as well as one 99- and three 108-bp exons encoding the Gly-X-Y repeat sequence. All these exons sizes are also found in the fibrillar collagen genes. Strikingly, of the 24 interruption sequences present in the alpha 2-chain of mouse collagen IV, 11 are encoded at the exon/intron borders of the gene, part of one interruption sequence is encoded by an exon of its own, and the remaining interruptions are encoded within the body of exons. In such "fusion exons" the Gly-X-Y encoding domain is also derived from 36-, 45-, or 54-bp sequence elements. These data support the idea that collagen IV genes evolved from a primordial 54-bp coding unit. We furthermore interpret these data to suggest that the interruption sequences in collagen IV may have evolved from introns, presumably by inactivation of splice site signals, following which intronic sequences could have been recruited into exons. We speculated that this mechanism could provide a role for introns in gene evolution in general.     

Human cystathionine β-synthase: gene organization and expression of different 5′ alternative splicing

The human cystathionine β-synthase (CBS) gene spans in excess of 30 kb and consists of 19 exons, with three different 5′ untranslated regions including three different exons 1 (exons 1 a, b, and c). Exon la and 1b are 390 bp apart from each other and are linked to exon 2 in cDNA « a » and cDNA « b ». Exon 1c, which linked to exon 5 in cDNA « c », is 7 kb apart from exon 1b. All splice sites conform to the GT/AG rule, including those from exon la or 1b to exon 2 and from exon 1c to exon 5. Upstream of exons la and 1b, we found two putative promoter sequences with high C + G nucleotide content, one CAAT box at —70 nucleotides (for exon lb), no TATA box, several Sp1 binding regulatory consensus sequences, and some other regulatory sequences. Human adult and fetal Northern blots hybridized with total cDNA containing exon 1b, or specific probes from exons 1 (b and c) showed mRNAs of 2.5 kb, 2.7 kb, and 3.7 kb. These results suggest that the mRNAs containing the different exons 1 are under the control of different promoters.     

The triple-helical domain of alpha 2(VI) collagen is encoded by 19 short exons that are multiples of 9 base pairs

We have analyzed the structure of the gene coding for the alpha 2(VI) subunit of chicken type VI collagen. The triple-helical domain of this polypeptide is encoded by 19 short exons distributed over 10 kilobase pairs of genomic DNA. These exons begin with the codon for glycine and end with the codon for the Y amino acid of the collagenous triplet Gly-X-Y. The sizes of the exons are integral multiples of 9 base pairs (bp) (27, 36, 45, 54, 63, and 90 bp), the predominant one being 63 bp. The organization of this type VI collagen gene is therefore quite different from that of the fibrillar collagen genes which have evolved by duplication of a primordial 54-bp unit. It also differs from that of the basement membrane collagen genes whose exon/intron boundaries often split the codons for amino acids.     

Genomic organization and tissue-specific expression of splice variants of mouse organic anion transporting polypeptide 2

cDNAs that code for mouse organic anion transporting polypeptide 2 (oatp2) have been cloned. At least three forms of mouse oatp2 cDNAs containing the same coding sequence were isolated. The common coding sequence is for a protein of 670 amino acids with 12 putative transmembrane domains. The deduced amino acid sequence of the mouse oatp2 shares 89% identity with the reported rat oatp2. Cloning and analysis of mouse oatp2 gene indicates that these isoforms are alternatively spliced products from the same gene. Heterogeneity was observed in the 5'-untranslated region of the cDNAs. Two of the three isoforms lacked the noncoding exon 3 sequence. Northern-blot hybridization analysis using the exon 3-specific probes demonstrated that mouse oatp2 mRNA containing exon 3 sequence is expressed in heart and lung, whereas exon 1-, 2-, and 17-specific probes detected mRNA only in brain and liver. The mouse oatp2 gene consists of 17 exons, including three noncoding exons, and 16 introns. All of the introns are flanked by GT-AG splice sequences except for intron 10 that is flanked by GC-AG splice sequence.     

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.     

Possible role of nucleotide correlations between human exon junctions

There is ample evidence that prediction of human splice sites can be refined by analyzing the nucleotides surrounding splice sites. This could mean that exon nucleotides over splice sites harbour information for the splicing process in addition to the coding information to specify aminoacids. We analyzed the correlations among the nucleotides lying at the end and at the beginning of all the consecutive human exons to seek relationships among the nucleotides. We have divided the sequences taking into account the phase of interruption. Even though exon sequences are involved in the coding function, we found phase-dependent, specific correlations in the area of exon junctions. These regularities do not give rise to specific motifs, but rather to a phase-specific nucleotide context that could contribute to define the splice site or aid the splicing machinery to join the exon ends. Results provide further evidence that accurate selection of human splice sites likely requires the contribution of exon regulatory sequences.