Nonmuscle and muscle tropomyosin isoforms are expressed from a single gene by alternative RNA splicing and polyadenylation.

The molecular basis for the expression of rat embryonic fibroblast tropomyosin 1 and skeletal muscle beta-tropomyosin was determined. cDNA clones encoding these tropomyosin isoforms exhibit complete identity except for two carboxy-proximal regions (amino acids 189 to 213 and 258 to 284) and different 3'-untranslated sequences. The isoform-specific regions delineate the troponin T-binding domains of skeletal muscle tropomyosin. Analysis of genomic clones indicates that there are two separate loci in the rat genome that contain sequences complementary to these mRNAs. One locus is a pseudogene. The other locus contains a single gene made up of 11 exons and spans approximately 10 kilobases. Sequences common to all mRNAs were found in exons 1 through 5 (amino acids 1 to 188) and exons 8 and 9 (amino acids 214 to 257). Exons 6 and 11 are specific for fibroblast mRNA (amino acids 189 to 213 and 258 to 284, respectively), while exons 7 and 10 are specific for skeletal muscle mRNA (amino acids 189 to 213 and 258 to 284, respectively). In addition, exons 10 and 11 each contain the entire 3'-untranslated sequences of the respective mRNAs including the polyadenylation site. Although the gene is also expressed in smooth muscle (stomach, uterus, and vas deferens), only the fibroblast-type splice products can be detected in these tissues. S1 and primer extension analyses indicate that all mRNAs expressed from this gene are transcribed from a single promoter. The promoter was found to contain G-C-rich sequences, a TATA-like sequence TTTTA, no identifiable CCAAT box, and two putative Sp1-binding sites.     

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.     

Alkaline-shifted pHo sensitivity of AE2c1-mediated anion exchange reveals novel regulatory determinants in the AE2 N-terminal cytoplasmic domain

The mouse anion exchanger AE2/SLC4A2 Cl(-)/HCO(-)(3) exchanger is essential to post-weaning life. AE2 polypeptides regulate pH(i), chloride concentration, cell volume, and transepithelial ion transport in many tissues. Although the AE2a isoform has been extensively studied, the function and regulation of the other AE2 N-terminal variant mRNAs of mouse (AE2b1, AE2b2, AE2c1, and AE2c2) have not been examined. We now present an extended analysis of AE2 variant mRNA tissue distribution and function. We show in Xenopus oocytes that all AE2 variant polypeptides except AE2c2 mediated Cl(-) transport are subject to inhibition by acidic pH(i) and to activation by hypertonicity and NH(+)(4). However, AE2c1 differs from AE2a, AE2b1, and AE2b2 in its alkaline-shifted pH(o)((50)) (7.70 +/- 0.11 versus 6.80 +/- 0.05), suggesting the presence of a novel AE2a pH-sensitive regulatory site between amino acids 99 and 198. Initial N-terminal deletion mutagenesis restricted this site to the region between amino acids 120 and 150. Further analysis identified AE2a residues 127-129, 130-134, and 145-149 as jointly responsible for the difference in pH(o)((50)) between AE2c1 and the longer AE2a, AE2b1, and AE2b2 polypeptides. Thus, AE2c1 exhibits a unique pH(o) sensitivity among the murine AE2 variant polypeptides, in addition to a unique tissue distribution. Physiological coexpression of AE2c1 with other AE2 variant polypeptides in the same cell should extend the range over which changing pH(o) can regulate AE2 transport activity.     

Structure of the rat plasma membrane Ca(2+)-ATPase isoform 3 gene and characterization of alternative splicing and transcription products. Skeletal muscle-specific splicing results in a plasma membrane Ca(2+)-ATPase with a novel calmodulin-binding domain.

We have isolated the rat gene encoding isoform 3 of the plasma membrane Ca(2+)-ATPase (PMCA3) and have determined its exon/intron organization. The PMCA3 gene contains 24 exons and spans approximately 70 kilobases. In addition, we have analyzed the splicing and polyadenylation patterns leading to the production of an alternative 4.5-kilobase (PMCA3) skeletal muscle mRNA that differs from the previously characterized 7.5-kilobase brain mRNA (Greeb, J., and Shull, G. E. (1989) J. Biol. Chem. 264, 18569-18576). cDNA cloning, Northern blot hybridization, and polymerase chain reaction analyses of the 4.5-kilobase mRNA demonstrate (i) the inclusion of a novel 68-nucleotide exon (exon 22) that is specific for skeletal muscle and significantly alters the calmodulin-binding domain and (ii) the utilization of an alternative polyadenylation site following exon 23 which eliminates the last coding exon (exon 24) and 3'-untranslated sequence of the 7.5-kilobase mRNA. We have also identified a 42-nucleotide exon (exon 8) that is included in the skeletal muscle PMCA3 mRNAs, but may be either included or excluded in the brain mRNAs. Exon 8 is inserted immediately before the sequence encoding a putative phospholipid binding domain and thus may alter regulatory interactions of the enzyme with acidic phospholipids.     

Complete murine cDNA sequence, genomic structure, and tissue expression of the high mobility group protein HMG-I(Y)

A cDNA coding for the non-histone chromosomal protein HMG-I, or its isoform HMG-Y, was isolated from a murine Friend cell library using synthetic oligonucleotide hybridization probes. Sequence analysis showed that the 1670-base pair full length cDNA insert consists of a 201-base pair, G/C-rich (74%), 5'-untranslated region, a 288-base pair amino acid coding sequence, and an unusually long 1182-base pair 3'-untranslated region. The deduced 96-residue amino acid coding sequence of the murine HMG-I(Y) cDNA is very similar to the reported amino acid sequence of human HMG-I, except that it lacks 11 internal amino acids reported in the human protein. Based on Southern blot hybridization analysis of genomic DNA, there appear to be fewer than five copies of HMG-I(Y) genes in the haploid murine genome. These murine HMG-I(Y) genes contain a large (at least 890 base pairs) exon that includes most, or all, of the 3'-untranslated region; whereas the much shorter 5'-untranslated region and amino acid coding sequences are interrupted by at least one intron. A single size class (approximately 1700 nucleotides in murine cells and 2000 nucleotides in human cells) of HMG-I(Y) mRNAs was detected at high levels in total RNA extracts from rapidly dividing, transformed cells, but to a lesser extent, or not at all, in extracts from slowly or non-dividing cells.     

Genes encoding proteins with homologous contiguous repeat sequences are highly expressed in the serous cells of the rat submandibular gland

An abundant class of secreted salivary polypeptides is characterized by the presence of identical and contiguous repeats of amino acid sequences within the polypeptide chains, and includes the proline-rich proteins. We discovered a new family of contiguous repeat polypeptides (CRPs) that is related to the proline-rich proteins but contains little proline. Analysis of salivary mRNAs and liver DNA by molecular cloning, DNA sequence determinations, and Northern and Southern blot hybridization revealed several closely related CRP mRNAs and at least 10 CRP-related genes. We further analyzed two CRP mRNAs of 850 and 920 nucleotides and the gene encoding the larger CRP mRNA. The two mRNAs contain the same 69-base repeats in their coding regions and are identical in their 5'- and 3'-untranslated tracts. However, they differ in the number of contiguous repeats (four versus five) and a segment at the 3' end of the coding region which encodes closely related but unique COOH termini of the CRPs. These structural features suggest a recent gene conversion. The CRP gene analyzed is divided into three exons that encode (i) 5'-untranslated tract and signal sequence, (ii) secreted polypeptide, and (iii) 3'-untranslated tract, respectively. CRP mRNA contains two open reading frames. The longer open reading frame encodes a CRP precursor with a signal sequence of 17 amino acids, four to five contiguous repeats of 23 amino acids, and a variable COOH region that begins with two segments related to the contiguous repeats. Immunochemical analysis of salivary gland slices with antisera raised against peptides corresponding to two regions of the larger open reading frame revealed intense staining only of the serous cells of the submandibular glands. 35S-Labeled oligonucleotides complementary to CRP mRNA specifically hybridized to the same cells.     

Characterization of distinct mRNAs coding for putative isozymes of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase

Three distinct clones encoding full-length 6-phosphofructo-2-kinase (PFK-2)/fructose-2,6-bisphosphatase (FBPase-2) were characterized from a rat liver cDNA library. Clone 22c was 1859 bp long and coded for the 470 amino acids of the bifunctional subunit of the liver homodimer. This polypeptide is phosphorylated on serine 32 by cyclic-AMP-dependent protein kinase. Clone 4c (2681 bp) had a coding region identical to that of clone 22c but it included a putative intron of 959 bp. In clone 5c (1750 bp), the sequence upstream from amino acid 33 differed from that in clone 22c and coded for a unique N-terminal portion of 10 amino acids. Poly(A)-rich RNA from rat tissues was hybridized with cDNA probes corresponding to the unique N-terminal portions of clones 22c and 5c. Dot and Northern blots showed signals indicative of three distinct PFK-2/FBPase-2 mRNAs. There were a 6.8-kb mRNA typical of cardiac tissue, a 2.1-kb mRNA typical of liver, corresponding to clone 22c, and a 1.9-kb mRNA typical of skeletal muscle, corresponding to clone 5c. Primer extension analysis showed that clones 22c and 5c were nearly complete since their respective 5'-untranslated sequences were at most 96/97 bp and 44 bp shorter than the corresponding mRNAs. These data provide a molecular basis for the existence of PFK-2/FBPase-2 isozymes.     

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.