Complete intron/exon organization of DNA encoding the alpha' chain of human C3

The third component of human complement (C3), a central molecule in both the classical and alternative pathways of complement, is comprised of two polypeptides, termed the alpha and beta chains. Activation of C3 cleaves the alpha chain into two fragments, C3a, an inflammatory peptide, and the alpha' chain which remains covalently linked to the beta chain. Proteolytic fragments derived from the alpha' chain during activation and regulation of complement play a significant role in host defense and regulation of the immune response. Two cosmid clones covering the alpha' chain region were used to characterize the structure of this portion of the C3 gene. The alpha' chain is encoded by 24 exons, which range in size from 52 to 213 base pairs (bp) with an average size of 115 bp. The splice donor sequence at the beginning of intron 12 has a rare sequence variant of GC instead of the usual GT sequence. Ten introns have been completely sequenced and were surprisingly short, ranging in size from 85 to 242 bp with an average of 140 bp. Other introns range in size from 250 bp to over 4 kilobases in length. The gene size for this portion of C3 is estimated to be 23-24 kilobases. Comparison of exon structure with protein domains and with peptide mapping studies demonstrates that several binding sites on C3 are encoded by single exons. These data support the hypothesis that individual exons can code for functional protein domains.     

Analysis of genomic clones of the murine U1RNA-associated 70-kDa protein reveals a high evolutionary conservation of the protein between human and mouse

We have isolated and characterised two overlapping lambda EMBL3 clones carrying sequences of the gene for the murine U1RNA-associated 70-kDa protein. The two clones cover around 23 kb of the 70-kDa protein gene including its 3' end. Southern blot hybridisation revealed the existence of a single copy of the 70-kDa protein gene in the mouse genome. The 23-kb-long portion of the 70-kDa protein gene is divided into eight exons. While most of the exons are quite small and are widely scattered throughout the DNA sequence, the last one consists of about 830 bp and encodes 226 amino acids of the 70-kDa protein, including the C-terminus. The predicted amino acid sequence of the region of the 70-kDa protein encoded by the genomic clones reveals high conservation of structure when it is compared with the sequence of the human 70-kDa protein. Interestingly, all deletions, additions and substitutions are localised exclusively within the C-terminus of the protein, accounting for a 5'-3' polarity with respect to protein conservation. Moreover, the analysis of the genomic sequences predicts the existence of multiple subclasses of mRNAs that may arise by alternative pre-mRNA splicing. A 72-bp alternative exon harboring an in-frame termination codon was also found in the mouse 70-kDa gene and shows, surprisingly, 100% nucleotide identity to its human counterpart.     

Structure of the gene for human complement protein decay accelerating factor.

Decay accelerating factor (DAF) is a glycophospholipid-anchored membrane protein that is part of the regulators of complement activation (RCA) gene family located on human chromosome 1, band q32. These proteins, beginning at their amino terminus, consist largely of multiple copies of an approximately 60 amino acid short consensus repeat (SCR). A DAF cDNA clone was used to identify overlapping bacteriophage genomic clones. The human DAF gene spans approximately 40 kb and consists of 11 exons. The length of these exons and introns varies considerably, with the exons ranging from 21 to 956 bp and the introns ranging from approximately 0.5 to 19.8 kb. SCR I, II, and IV are all encoded by single exons; however, SCR III is encoded by two separate exons, with the splice junction occurring after the second nucleotide of the codon for the glycine residue at position 34 of the consensus sequence. This feature has also been found in CR1, CR2, membrane cofactor protein, and murine factor H. Following the SCR in DAF is a 76 amino acid serine/threonine-rich domain encoded on three separate exons. Exon 10 encodes the Alu family sequence that has been found as an insert in a minor class of DAF cDNA, thus indicating that this mRNA arises by standard alternative splicing. The last DAF exon, which comes after the largest intron of 19.8 kb, encodes the hydrophobic carboxy terminus and the 3'UT region. The nature of the signal that directs posttranslational attachment of a glycophospholipid anchor to DAF is not known, but that signal is apparently spread over three exons and greater than 20 kb. An analysis of the DAF gene provides additional evidence for the common evolutionary heritage of the RCA gene family. The exon/intron structure of this gene will facilitate experiments aimed at understanding the functions of the various domains of DAF.     

Cloning and characterization of the non-catalytic heavy chain of mouse complement factor I gene: structure comparison with the human homologue

The gene sequence encoding the non-catalytic heavy chain of mouse complement factor I (mCFI) was cloned and its exon-intron organization and domain structure characterized. The genomic organization of mCFI differs in several aspects from its human homologue (hCFI). The intron sizes are remarkably different. Exons 2 and 4 in mCFI are larger than their counterparts in hCFI by 9 bp and 6 bp respectively. Whereas the diversity (D) region of hCFI is encoded by two exons (exon 7 or hD2 and exon 8 or hD4), this region in mCFI is encoded by three exons; exon 6A or mD1 (located at the 3'-end of the LDLr A2 domain), exon 7 or mD2 and exon 8, an extended exon (56 bp) composed of mD3, fused upstream of mD4. In contrast, hCFI lacks D1 and D3 subregions and exon 8 in hCFI consists of only hD4, 36 bp in length. Thus the heavy chain of mCFI is organized into 10 exons compared to 9 exons in hCFI.     

The exon organization of the triple-helical coding regions of the human alpha 1(VI) and alpha 2(VI) collagen genes is highly similar.

The alpha 1(VI) and alpha 2(VI) chains, two of the three constituent chains of type VI collagen, are highly similar in size and domain structure. They are encoded by single-copy genes residing in close proximity on human chromosome 21. To study the evolution of the type VI collagen genes, we have isolated and characterized genomic clones coding for the triple-helical domains of the human alpha 1(VI) and alpha 2(VI) chains, which consist of 336 and 335 amino acid residues, respectively. Nucleotide sequencing indicates that, in both genes, the exons are multiples of 9 bp in length (including 27, 36, 45, 54, 63, and 90 bp) except for those encoding for regions with triple-helical interruptions. In addition, the introns are positioned between complete codons. The most predominant exon size is 63 bp, instead of 54 bp as seen in the fibrillar collagen genes. Of particular interest is the finding that the exon structures of the alpha 1(VI) and alpha 2(VI) genes are almost identical. A significant deviation is that a segment of 30 amino acid residues is encoded by two exons of 54 and 36 bp in the alpha 1(VI) gene, but by a single exon of 90 bp in the alpha 2(VI) gene. The exon arrangement therefore provides further evidence that the two genes have evolved from tandem gene duplication. Furthermore, comparison with the previously reported gene structure of the chick alpha 2(VI) chain indicates that the exon structure for the triple-helical domain of the alpha 2(VI) collagen is strictly conserved between human and chicken.     

Genomic organization and polymorphisms of the human C3d/Epstein-Barr virus receptor

The human C3d/Epstein-Barr virus receptor (CR2/CD21) is a 145-kDa protein primarily expressed on mature B lymphocytes. CR2 is a member of the regulators of complement activation (RCA) gene family found on band q32 of chromosome 1. The RCA proteins are characterized by the presence of 60-70 amino acid short consensus repeats (SCR). A full length CR2 cDNA was cloned and used to identify overlapping cosmid genomic clones. Analysis of CR2 exon-intron junctions revealed the presence of three types of exons in the short consensus repeat region of CR2. First, four exons each of which encodes two SCR are present. Five exons encode a single SCR. Six exons encode SCRs which are split in identical positions. The order of these types of exons is in a repeated array of four SCRs, indicating that the contemporary CR2 gene likely evolved from a more primitive gene containing four SCRs. The CR2 full length cDNA clone was used to find restriction fragment length polymorphisms (RFLPs). Restriction enzyme TaqI generated 2.55- and 2.10-kilobase (kb) polymorphic bands. This RFLP was mapped near the exon containing the first two SCRs. HaeIII digestion generated polymorphic bands of 1.45, 1.55, and 1.75 kb. The HaeIII 1.45-kb RFLP band maps near the exon containing the 15th SCR. The TaqI and HaeIII RFLPs will provide tools for the genetic analysis of CR2. The organization of the CR2 gene provides insights into the evolution of human CR2 and the RCA gene family.