Multiple lobster tubulin isoforms are encoded by a simple gene family

Microtubule proteins isolated from pleopod tegumental gland (PTG) tissue of the American lobster, Homarus americanus, reveal a complex tubulin (Tub) profile. To determine whether Tub heterogeneity in PTG is due to expression of a large tub gene family or the result of post-translational modification, a PTG cDNA library was constructed. Clones coding for both α- and β-Tub were isolated, sequenced and found to contain open reading frames (ORFs) of 451 amino acids (aa). Alignments reveal phylogenetic clustering with other arthropods and identify unique changes in primary structure which may have functional significance. These clones, when used to probe restriction enzyme-digested lobster genomic DNA in transfer-hybridization experiments, revealed a simple banding pattern indicating a lobster tub gene family of limited complexity. Lobsters appear to make use of a small tub gene family and fulfill the varied functional requirements imposed upon cellular microtubules through post-translational modifications of relatively few gene products.     

Nuclear and mitochondrial forms of human uracil-DNA glycosylase are encoded by the same gene.

Recent cloning of a cDNA (UNG15) encoding human uracil-DNA glycosylase (UDG), indicated that the gene product of M(r) = 33,800 contains an N-terminal sequence of 77 amino acids not present in the presumed mature form of M(r) = 25,800. This led to the hypothesis that the N-terminal sequence might be involved in intracellular targeting. To examine this hypothesis, we analysed UDG from nuclei, mitochondria and cytosol by western blotting and high resolution gel filtration. An antibody that recognises a sequence in the mature form of the UNG protein detected all three forms, indicating that they are products of the same gene. The nuclear and mitochondrial form had an apparent M(r) = 27,500 and the cytosolic form an apparent M(r) = 38,000 by western blotting. Gel filtration gave essentially similar estimates. An antibody with specificity towards the presequence recognised the cytosolic form of M(r) = 38,000 only, indicating that the difference in size is due to the presequence. Immunofluorescence studies of HeLa cells clearly demonstrated that the major part of the UDG activity was localised in the nuclei. Transfection experiments with plasmids carrying full-length UNG15 cDNA or a truncated form of UNG15 encoding the presumed mature UNG protein demonstrated that the UNG presequence mediated sorting to the mitochondria, whereas UNG lacking the presequence was translocated to the nuclei. We conclude that the same gene encodes nuclear and mitochondrial uracil-DNA glycosylase and that the signals for mitochondrial translocation resides in the presequence, whereas signals for nuclear import are within the mature protein.     

Two major outer envelope glycoproteins of Epstein-Barr virus are encoded by the same gene.

Two major outer envelope glycoproteins of Epstein-Barr virus, gp350 and gp220, are known to be encoded by 3.2- and 2.5-kilobase RNAs which map to the same DNA fragment (M. Hummel, D. Thorley-Lawson, and E. Kieff, J. Virol. 49:413-417). These RNAs have the same 5' and 3' ends. The larger RNA is encoded by a 2,777-base DNA segment which is preceded by TATTAAA, has AATAAA near its 3' end, and contains a 2,721-base open reading frame. The smaller RNA has one internal splice which maintains the same open reading frame. Translation of the 3.2- and 2.5-kilobase RNAs yielded proteins of 135 and 100 kilodaltons (Hummel et al., J. Virol. 49:413-417). The discrepancy between the 907 codons of the open reading frame and the 135-kilodalton size of the gp350 precursor is due to anomalous behavior of the protein in gel electrophoresis, since a protein translated from most of the Epstein-Barr virus open reading frame in Escherichia coli had similar properties. Antisera raised in rabbits to the protein expressed in E. coli specifically immunoprecipitated gp350 and gp220, confirming the mapping and sequencing results and the translational reading frame. The rabbit antisera also reacted with the plasma membranes of cells that were replicating virus and neutralized virus, particularly after the addition of complement. This is the first demonstration that the primary amino acid sequence of gp350 and gp220 has epitopes which can induce neutralizing antibody. We propose a model for the gp350 protein based on the theoretical analysis of its primary sequence.     

Subunits of purified calcium channels. Alpha 2 and delta are encoded by the same gene

Polyacrylamide gel electrophoresis of purified rabbit skeletal muscle L-type calcium channel before and after reduction of disulfide bonds confirmed that 27- and 24-kDa forms of the delta subunit are disulfide-linked to the 143-kDa alpha 2 subunit. The amino acid sequences of three peptides obtained by tryptic digestion of the delta subunits corresponded to amino acid sequences predicted from the 3' region of the mRNA encoding alpha 2. One of these peptides had the same sequence as the N terminus of the 24- and 27-kDa forms of the delta subunit and corresponded to residues 935-946 of the predicted alpha 2 primary sequence. Anti-peptide antibodies directed to regions on the N-terminal side of this site recognized the 143-kDa alpha 2 subunit in immunoblots of purified calcium channels under reducing conditions, whereas an antipeptide antibody directed toward a sequence on the C-terminal side of this site recognized 24- and 27-kDa forms of the delta subunit. A similar result was obtained after immunoblotting using purified transverse tubules or crude microsomal membrane preparations indicating that alpha 2 and delta occur as distinct disulfide-linked polypeptides in skeletal muscle membranes. Thus, the delta subunits are encoded by the same gene as the alpha 2 subunit and are integral components of the skeletal muscle calcium channel.     

The beta-chains of DP4 molecules from different haplotypes are encoded by the same gene

The nucleotide sequence of a complete cDNA gene from a DP4-positive HLA-homozygous cell line, PGF, has been determined. This sequence is identical to the exon sequences in a genomic clone derived from another DP4-positive cell line, Priess. In contrast, our DP cDNA sequence shares only limited homology with partial cDNA sequences obtained from clones of three DP4-negative cell lines. On the basis of these results, we conclude that the phenotypic variation of DP alleles is directly attributable to the nucleotide sequence heterogeneity of DP-beta genes. That is, each phenotypic allelic form of DP antigen corresponds to a distinctly different DP-beta gene. Furthermore, this correspondence is found to be unaffected by the markers present at the DQ and DR loci, since the haplotypes of the PGF and Priess cell lines are, respectively, DR2,DQw1,DP4 and DR4,DQw3,DP4.     

Genetic evidence that the multiple apolipoprotein A-1 isoforms are encoded by a common structural gene

We have used a genetic structural variation of apolipoprotein A-I in mice to examine the origin of the multiple charge isoforms of the plasma protein. Apolipoprotein A-I translated in vitro from hepatic or enteric mRNA revealed that the genetic variation simultaneously alters the charge of the protein produced by both tissues. The variation also shifted the charge of the entire family of isoforms found in plasma or translated in vitro. These results indicate that the protein produced by different tissues as well as the multiple isoforms are all derived from a common structural gene by processing.     

The myosin alkali light chains of mouse ventricular and slow skeletal muscle are indistinguishable and are encoded by the same gene

We have isolated a cDNA recombinant plasmid (pA29) identified as encoding part of the ventricular muscle myosin light chain MLC1v. This cDNA contains a 300-base pair fragment which under conditions of moderate stringency shows specific hybridization to MLC1v mRNA with no detectable cross-hybridization with the mRNAs encoding the fast skeletal muscle isoforms MLC1F and MLC3F, or the atrial muscle isoform MLC1A. Under these conditions hybridization is seen with an abundant mRNA present in slow skeletal muscle (soleus) which is indistinguishable from ventricular MLC1V mRNA on the basis of size and of thermal stability of hybrids formed with plasmid pA29. The mouse MLC1V and MLC1S proteins are found to co-migrate on two-dimensional gels. We therefore conclude that these isoforms are the same and are encoded by the same mRNA. Analysis of mouse DNA has identified a single region of the genome which hybridizes to this same fragment of pA29. This region has been isolated in a recombinant phage and has been shown to contain a single gene showing homology with MLC1V mRNA by R-loop analysis. We therefore conclude that MLC1V and MLC1S are encoded by a single gene. The pattern of segregation of a restriction fragment length polymorphism identified for this gene between Mus musculus and Mus spretus has been followed in an F1 backcross between these two mouse species. The results show the MLC1V/MLC1S gene to be closely linked to a marker at the distal end of mouse chromosome 9.     

Multiple isoforms of porcine aromatase are encoded by three distinct genes

Cytochrome P450 aromatase, a product of the CYP 19 gene and the terminal enzyme in the estrogen biosynthetic pathway, is synthesized by the ovary, endometrium, placenta, and peri-implantation embryos in the pig and other mammals, albeit to varying levels, implying its functional role(s) in pregnancy events. The aromatase produced by the pig tissues exists as three distinct isoforms (type I - ovary, type II - placenta, and type III - embryo), with presumed differences in substrate specificities, expression levels, activity, and mode of regulation. In order to delineate the molecular mechanisms whereby estrogen synthesis is regulated in these diverse tissues, the present study examined if these aromatase isoforms represent products of multiple genes or of a single gene via complex splicing mechanisms. Porcine genomic DNA from a single animal was used as a template in the polymerase chain reaction (PCR) to amplify isoform-specific sequences corresponding to exons 4 and 7, respectively. Nucleotide sequence analysis of the generated fragments revealed the presence of only clones corresponding to the three known aromatase types. Screening a porcine Bacterial Artificial Chromosome (BAC) library for aromatase gene by PCR yielded a single clone approximately 80 kb in length. Southern blot analysis, using probes specific for exons 1A-1B, 2-3, 4-9, and 10 sequences indicated that the BAC genomic clone contains the entirety of the coding exons as well as the proximal promoter region. Sequence analysis of the fragment generated with exon 4 primers determined that this BAC clone contains only the type II gene. The presence and relative orientation of the untranslated 5'- exons 1A and 1B, previously demonstrated for the type III isoform were evaluated in the BAC clone and genomic DNA by PCR. The 265 bp fragment generated from both PCR reactions was confirmed by sequence analysis to contain exons 1A and 1B that are located contiguous to each other and separated by only three bp. A diagnostic procedure for typing aromatase isoforms was developed, based on the presence of specific restriction sites within isoform-specific exons. The use of this protocol confirmed the existence of only three aromatase isoforms in the porcine genome and indicated changes in aromatase types expressed by the uterine endometrium as a function of pregnancy stage. The presence of distinct genes encoding each of the aromatase isoform predicts important differences in the mechanisms underlying the molecular evolution and regulation of porcine aromatase, unique from those of other mammals, and suggests a critical role for P450 aromatase steroidal products in uterine functions related to pregnancy events.     

Human brain acyl-CoA hydrolase isoforms encoded by a single gene

Acyl-CoA hydrolases are a group of enzymes that catalyze the hydrolysis of acyl-CoA thioesters to free fatty acids and CoA-SH. The human brain acyl-CoA hydrolase (BACH) gene comprises 13 exons, generating several isoforms through the alternative use of exons. Four first exons (1a-1d) can be used, and three patterns of splicing occur at exon X located between exons 7 and 8 that contains an internal 3(')-splice acceptor site and creates premature stop codons. When examined with green fluorescent protein-fusion constructs expressed in Neuro-2a cells, the nuclear localization signal encoded by exon 9 was functional by itself, whereas the whole structure was cytosolic, suggesting nuclear translocation of the enzyme. This was consistent with dual staining of the cytosol and nucleus in certain neurons by immunohistochemistry using anti-BACH antibody. The mitochondrial targeting signals encoded by exons 1b and 1c were also functional and directed mitochondrial localization of BACH isoforms with the signals. Although BACH mRNA containing the sequence derived from exon 1a, but not exon X, was exclusively expressed in human brain, these results suggest that the human BACH gene can express long-chain acyl-CoA hydrolase activity in multiple intracellular compartments by generating BACH isoforms with differential localization signals to affect various cellular functions that involve acyl-CoAs.     

Soluble and membrane-bound forms of dopamine beta-hydroxylase are encoded by the same mRNA.

A full length cDNA clone for bovine dopamine beta-hydroxylase was expressed in rat pheochromocytoma PC12 cells by stable transformation of this cell line with a plasmid expression vector. The recombinant protein exhibited dopamine beta-hydroxylase enzyme activity and was found in both the soluble and membrane fractions of the secretory vesicle. Immunoprecipitation of cell extracts from recombinant cell lines with dopamine beta-hydroxylase antisera followed by fractionation on sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed two subunits, which migrated to relative molecular masses of 76 and 78 kDa. The recombinant protein co-fractionated with neurotransmitter when subcellular structures were separated by sucrose gradient density centrifugation, suggesting that the protein was routed to the secretory vesicles. Dopamine beta-hydroxylase immunoreactivity in those sucrose gradient fractions presumed to contain secretory vesicles was resistant to treatment with trypsin unless the nonionic detergent Triton X-100 was also present to disrupt membrane structure. The 76- and 78-kDa isoform were each found in both the membrane and soluble fractions of the secretory vesicle. Treatment of cultured cells with nerve growth factor or 8-(4-chlorophenylthio)-cyclic AMP alters the relative distribution of the subunits such that the 76-kDa form predominates. The subcellular distribution of a dopamine beta-hydroxylase cDNA clone lacking the first 16 nucleotide residues was also determined. The predicted amino acid sequence of the protein encoded by this cDNA would be deleted of the first 13 residues of the signal sequence, which were reported to be present in the membrane-bound form, but not the soluble form, of native dopamine beta-hydroxylase (Taljanidisz, J., Stewart, L., Smith, A. J., and Klinman, J. P. (1989) Biochemistry 28, 10054-10061). Immunoprecipitable dopamine beta-hydroxylase derived from expression of the deleted cDNA was found in both the membrane-bound and soluble fractions of the secretory vesicle. These experiments demonstrate that the membrane-bound and soluble forms of dopamine beta-hydroxylase are derived from one primary translation product, which is also sufficient to produce enzyme activity. In addition, the amino-terminal amino acids encoding residues 1-13, which compose the hydrophilic region of the signal sequence, are not necessary for the biogenesis of membrane-bound dopamine beta-hydroxylase.     

Cardiac and skeletal muscle troponin I isoforms are encoded by a dispersed gene family on mouse Chromosomes 1 and 7

We mapped the locations of the genes encoding the slow skeletal muscle, fast skeletal muscle, and cardiac isoforms of troponin I (Tnni) in the mouse genome by interspecific hybrid backcross analysis of species-specific (C57BL/6 vs Mus spretus) restriction fragment length polymorphisms (RFLPs). The slow skeletal muscle troponin I locus (Tnni1) mapped to Chromosome (Chr) 1. The fast skeletal muscle troponin I locus (Tnni2), mapped to Chr 7, approximately 70 cM from the centromere. The cardiac troponin I locus (Tnni3) also mapped to Chr 7, approximately 5–10 cM from the centromere and unlinked to the fast skeletal muscle troponin I locus. Thus, the troponin I gene family is dispersed in the mouse genome. Received: 10 May 1995 / Accepted: 1 September 1995     

Different isoforms of the non-integrin laminin receptor are present in mouse brain and bind PrP

The prion protein (PrP) plays a central role in prion diseases, and identifying its cellular receptor appears to be of crucial interest. We previously showed in the yeast two-hybrid system that PrP interacts with the 37 kDa precursor (LRP) of the high affinity 67 kDa laminin receptor (LR), which acts as the cellular receptor of PrP in cellular models. However, among the various isoforms of the receptor that have been identified so far, those which are present in the central nervous system and which bind PrP are still unknown. In this study, we have purified mouse brain fractions enriched in the laminin receptor and have performed overlay assays in order to identify those isoforms that interact with the prion protein. We demonstrate (i) the presence, in mouse brain, of several isoforms of the LRP/LR corresponding to different maturation states of the receptor (44, 60, 67 and 220 kDa) and (ii) the binding of all of these isoforms to PrP. Our data strongly support a physiological role of the laminin receptor/PrP interaction in the brain and highlight its relevance for transmissible spongiform encephalopathies.     

Acetylcholinesterase from Drosophila melanogaster. Identification of two subunits encoded by the same gene

Purified acetylcholinesterase from Drosophila melanogaster is composed of a 55 kDa and a 16 kDa noncovalently associated subunit. Cleavage of disulfide bonds reveals that two 55 kDa polypeptides are linked together in native dimeric AChE. Western blots with two antibodies directed against the N- and C-termini of the predicted AChE primary sequence show that the 55 and 16 kDa polypeptides originate from proteolysis of the same precursor encoded by the Ace locus.     

cis-diol dehydrogenases encoded by the TOL pWW0 plasmid xylL gene and the Acinetobacter calcoaceticus chromosomal benD gene are members of the short-chain alcohol dehydrogenase superfamily.

In the aerobic degradation of benzoate by bacteria, benzoate is first dihydroxylated by a ring-hydroxylating dioxygenase to form a cis-diol (1,2-dihydroxycyclohexa-3,4-diene carboxylate) which is subsequently transformed to a catechol by an NAD(+)-dependent cis-diol dehydrogenase. The structural gene for this dehydrogenase, encoded on TOL plasmid pWW0 of Pseudomonas putida (xylL) and that encoded on the chromosome of Acinetobacter calcoaceticus (benD), were sequenced. They encode polypeptides of about 28 kDa in size. These proteins are similar to each other, exhibiting 58% sequence identity. They are also similar to other proteins of at least 20 different functions, which are members of the short-chain alcohol dehydrogenase family. The alignment of these proteins suggest two amino acids, lysine and tyrosine, as catalytically important residues.