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.     

Alternate use of divergent forms of an ancient exon in the fructose-1,6-bisphosphate aldolase gene of Drosophila melanogaster.

The fructose-1,6-bisphosphate aldolase gene of Drosophila melanogaster contains three divergent copies of an evolutionarily conserved 3' exon. Two mRNAs encoding aldolase contain three exons and differ only in the poly(A) site. The first exon is small and noncoding. The second encodes the first 332 amino acids, which form the catalytic domain, and is homologous to exons 2 through 8 of vertebrates. The third exon encodes the last 29 amino acids, thought to control substrate specificity, and is homologous to vertebrate exon 9. A third mRNA substitutes a different 3' exon (4a) for exon 3 and encodes a protein very similar to aldolase. A fourth mRNA begins at a different promoter and shares the second exon with the aldolase messages. However, two exons, 3a and 4a, together substitute for exon 3. Like exon 4a, exon 3a is homologous to terminal aldolase exons. The exon 3a-4a junction is such that exon 4a would be translated in a frame different from that which would produce a protein with similarity to aldolase. The putative proteins encoded by the third and fourth mRNAs are likely to be aldolases with altered substrate specificities, illustrating alternate use of duplicated and diverged exons as an evolutionary mechanism for adaptation of enzymatic activities.     

The novel exon, exon T, of the human progesterone receptor gene and the genomic organization of the gene

Recently, we have cloned the novel isoform of the progesterone receptor (PR) cDNA (PR isoform S cDNA) from the human testicular cDNA library. The isoform S cDNA consists of the novel exon (termed the exon S of the PR gene) and the exons 4-8 of the PR gene. In order to investigate the existence of the other isoform of the human PR cDNA, the human testicular cDNA library was screened by the exons 4-8 corresponding sequence of the human PR cDNA in the present study. As a result, we have identified a novel isoform of the PR cDNA (termed the PR isoform T cDNA (PR-T cDNA)), which consisted of a previously unidentified 5'-sequence and the exons 4-8 of the PR gene. The structure of this isoform T cDNA is essentially similar to that of the isoform S cDNA. By the genomic cloning, the 5'-sequence of the PR isoform T mRNA was demonstrated to originate from a novel independent exon, exon T, which was located in the 5'-upstream region of the exon S.     

Characterization of the human gene for a polypeptide that acts both as the beta subunit of prolyl 4-hydroxylase and as protein disulfide isomerase

A single polypeptide acts as the beta subunit of prolyl 4-hydroxylase and the enzyme protein disulfide isomerase and may also function as a cellular thyroid hormone binding protein. We report here that the human gene for this polypeptide is about 18 kilobase pairs and consists of 11 exons. The two thioredoxin-like regions are coded by exons 1-2 and 8-9, respectively. The codons for the two presumed active sites of protein disulfide isomerase, each a Cys-Gly-His-Cys sequence, are located 12 base pairs from the beginning of exons 2 and 9. The last 3 amino acids coded by exons 1 and 8 and the first 9 amino acids coded by exons 2 and 9, including a broken codon for Tyr, are identical in the respective exon-intron junctions. These regions are also highly homologous to the active sites of bacterial thioredoxins. The data suggest that evolution of this gene has involved exon shuffling and duplication of a two-exon unit, in which the internal exon-intron junctions have been entirely conserved. The region between exons 1-2 and 8-9 appears to contain other duplications. The 5' flanking sequences contain a TATA box, six CCAAT boxes, and other elements which may be involved in regulation of the cellular amounts of this polypeptide.     

Cloning of the novel isoform of the estrogen receptor beta cDNA (ERbeta isoform M cDNA) from the human testicular cDNA library

Our recent report has revealed the existence of the progesterone receptor (PR) isoform S, which consists of the novel PR exon S and exons 4-8 of the PR gene in the human testicular cDNA library. More recently, we have cloned the human estrogen receptor alpha (ERalpha) isoform S cDNA from the library. The ERalpha isoform S cDNA also contains the novel ERalpha exon S and exons 4-8 of the ERalpha cDNA. Based on these findings, we assumed that the novel isoform of cDNA like the PR- and ERalpha isoforms might exist in the human ER beta (ERbeta). In order to investigate this possibility, we have screened the human testicular cDNA library using the exons 4-8 corresponding sequence of the human ERbeta cDNA. Consequently, we have cloned a novel isoform of the ERbeta cDNA that consists of a previously unidentified 5'-sequence and the exons 5-8 of the ERbeta gene. We termed this isoform cDNA the "ERbeta isoform M cDNA". The 5'-sequence of the ERbeta isoform M cDNA was confirmed to be derived from a novel exon (termed the "exon M") by analysis of the genomic DNA. Moreover, we have analyzed the molecular size of the ERbeta isoform M encoded by the ERbeta isoform M mRNA by transient expression of the ERbeta isoform M cDNA in the 293T cell. The approximately 28 kDa protein, which was recognized by the anti-rat ERbeta antibody against the carboxyl-terminal region, was synthesized in the cells. Thus, we concluded that the ATG in the exon M could be used as the translation initiation codon. This report revealed for the first time the existence of the ERbeta mRNA isoform that is not caused by the skipping of one or more exons, by the alternative usage of the multiple exon 8s, nor by the alternative utilization of the untranslated 5'-exons located on the upstream region of the exon 1.     

The structure of the rat ameloblastin gene and its expression in amelogenesis

Ameloblastin (also designated amelin and sheathlin) is an enamel matrix protein expressed within the ameloblast lineage. In this study we analyzed the structure of the rat ameloblastin gene and characterized its subtypes. The promoter sequence contains several E-box-like elements, and consensus sequences for AP1 and SP1. The gene is about 6 kb in length and contains 12 exons. Exon 1 was mapped by primer extension and encodes 90 bp of 5' untranslated leader sequence, followed by the coding sequences of exon 2 (309 bp), alternatively spliced exon 3a (45 bp), exon 3b (198 bp), exon 4 (36 bp), exon 5 (60 bp), exon 6 (45 bp), exon 7 (150 bp), and exon 8 (448 bp) containing coding sequence (426 bp) and 3' untranslated sequence (22 bp), followed by exon 9 (39 bp); exon 10 (143 bp); exon 11 (342 bp); and exon 12. Exon 3a, encoding YEYSLPVHPPPLPSQ, has a potential SH3 binding domain. Analysis of ameloblastin subclones showed that exon 3a and 11 were potential alternative splicing sites, producing 4 types of ameloblastin mRNA, from which ameloblastin I and II could be translated. Using in situ hybridization, immunohistochemistry, Western blot and RT-PCR methods we found that ameloblastin II, containing exon 3a, was more strongly expressed at the late maturation stage of ameloblasts than at the secretory stage, while a common probe for both ameloblastin subtypes showed wide expression throughout the presecretory, secretory and postsecretory stages. From the above results we propose that ameloblastin II plays an important role in the mineralization of ameloblasts during the maturation stages.