Sequencing, genomic organization, and preliminary promoter analysis of a black cherry (R)-(+)-mandelonitrile lyase gene.

The flavoprotein (R)-(+)-mandelonitrile lyase (MDL; EC 4.1.2.10) plays a key role in cyanogenesis in rosaceous stone fruits. An MDL gene (mdl3) and its corresponding cDNA (MDL3) were isolated from black cherry (Prunus serotina) and characterized. The mdl3 gene contains 2292 bp of the 5' flanking region, the entire coding region, and 300 bp of the 3' flanking region. The coding region is interrupted by three short introns, of which one possesses the usual GC-AG splice junction dinucleotides. This gene encodes a polypeptide of 573 amino acids that includes a putative signal sequence, 13 potential N-glycosylation sites, and a presumptive flavin adenine dinucleotide-binding site. To determine whether the 5' flanking region of the mdl3 gene is capable of driving MDL expression, it was fused to the beta-glucuronidase reporter gene for Agrobacterium-mediated transformation into tobacco. Matching endogenous MDL expression patterns, beta-glucuronidase staining was observed in maturing embryos and seeds; it also occurred in postembryonic tissues, especially in association with vascular tissues. After developing a homologous transient transformation system to facilitate identification of putative regulatory sequences, we demonstrated that 125 bp (-107 to +18) of the 5' flanking sequence of the mdl3 gene is sufficient for MDL expression in protoplasts derived from immature black cherry embryos.     

Identification and characterization of a novel gene family YPEL in a wide spectrum of eukaryotic species

During comprehensive sequence analysis of human chromosome 22, we identified a novel gene family consisting of five members (YPEL1 through YPEL5) which has high homology with Drosophila yippee gene. We cloned and sequenced cDNAs for all five genes and determined their exon/intron organization. These YPEL genes showed high homology (43.8-96.6%) at amino acid sequence level among them. Mouse counterparts (Ypel1 through Ypel5) were also identified in the syntenic region of mouse chromosomes and their cDNAs were cloned and sequenced. Each of five pairs of human/mouse orthologs revealed extremely high homology. Thus, we named these genes as members of YPEL gene family. We searched YPEL family genes from the public databases, and found 100 genes from 68 species including animals, plants and fungi. Amino acid sequences of these 100 YPEL proteins were extremely similar and a consensus sequence of C-X(2)-C-X(19)-G-X(3)-L-X(5)-N-X(13)-G-X(8)-C-X(2)-C-X(4)-GWXY-X(10)-K-X(6)-E was established for all the YPEL family proteins without exception. Interestingly, the indirect immunofluorescent staining indicated that YPEL1-4 proteins are localized to the centrosome and nucleolus during interphase and at several dot-like structures around the mitotic apparatus during mitotic phase of COS-7 cells. YPEL5 protein is localized to the centrosome and nucleus during interphase and at the mitotic spindle during mitosis of the same cell line. Thus, the YPEL family proteins were found in essentially all the eukaryotes and hence they must play important roles in the maintenance of life. The subcellular localization of YPEL proteins in association with centrosome or mitotic spindle suggests a novel function involved in the cell division.     

The third member of the transforming acidic coiled coil-containing gene family, TACC3, maps in 4p16, close to translocation breakpoints in multiple myeloma, and is upregulated in various cancer cell lines.

We have recently identified a novel gene, TACC1 (transforming acidic coiled coil-containing gene 1), which is located close to FGFR1 within a region amplified in breast cancer on human chromosome 8p11. The coiled coil domain of this gene identified a series of cDNAs in the expressed sequence tag database, which suggested the existence of a family of TACC genes comprising at least three family members. We have now characterized the human and mouse TACC3 cDNAs, and demonstrate that this gene is upregulated in various cancer cell lines, and at Embryonic Day 15 in mice, suggesting that the TACC3 protein is involved in the control of cell growth and differentiation. The TACC3 gene maps telomeric to the FGFR3 gene in 4p16.3, close to a region disrupted by translocation breakpoints associated with multiple myeloma. Thus, TACC1, TACC2, and TACC3 map close to the corresponding FGFR1, FGFR2, and FGFR3 genes. The phylogenetic relationship among the three TACC genes is similar to that of the three FGFR family members. These relationships suggest that the FGFR and TACC genes arose from a physically linked ancestral gene pair. Subsequently, this gene pair has undergone two successive rounds of gene duplication to give rise to the three FGFR/TACC gene pairs on chromosomes 4, 8, and 10.     

Isolation and characterization of maize cDNAs encoding a high mobility group protein displaying a HMG-box.

cDNAs encoding a nonhistone chromosomal high mobility group (HMG) protein corresponding to the animal HMG1 family were isolated from a maize cDNA library using an immunoscreening approach. The cDNAs revealed an open reading frame of 471 base pairs together with 413 base pairs of flanking region, in agreement with the size of mRNA detected by Northern analysis of maize endosperm RNA. Like its animal counterparts the 17146 Da maize HMG protein contains a basic aminoterminus and an acidic carboxyterminus. The HMG-box region of this plant HMG protein shows striking sequence similarity to members of the vertebrate HMG1 family. Based on Southern blot hybridization analysis of genomic DNA, the isolated cDNA appears to be derived from a single or low copy gene.     

The keratin BIIIB gene family: isolation of cDNA clones and structure of a gene and a related pseudogene

The nucleotide sequence of cDNA clones encoding the three major BIIIB high-sulfur wool keratin proteins (BIIIB2, 3, and 4) and the structure of a BIIIB4 gene and a BIIIB3 pseudogene are reported. Although Southern blot analysis indicates that the BIIIB genes comprise a multigene family in the sheep genome, they are poorly represented in genomic DNA libraries. The family sequence homology of the coding region extends into the 5' and 3' untranslated regions and the near 5' flanking region of the BIIIB3 and 4 genes. These homologies suggest that the BIIIB3 and 4 genes represent the latest gene duplication event in the evolution of the BIIIB multigene family. Like the genes coding for other wool keratin matrix protein components, the BIIIB genes have the conserved 18-bp sequence immediately 5' to the initiation codon and also appear to lack introns.     

Cytosolic glutamine synthetase in soybean is encoded by a multigene family, and the members are regulated in an organ-specific and developmental manner.

Gln synthetase (GS) is the key enzyme in N metabolism and it catalyzes the synthesis of Gln from glutamic acid, ATP, and NH4+. There are two major isoforms of GS in plants, a cytosolic form (GS1) and a chloroplastic form (GS2). In leaves, GS2 functions to assimilate ammonia produced by nitrate reduction and photorespiration, and GS1 is the major isoform assimilating NH3 produced by all other metabolic processes, including symbiotic N2 fixation in the nodules. GS1 is encoded by a small multigene family in soybean (Glycine max), and cDNA clones for the different members have been isolated. Based on sequence divergence in the 3'-untranslated region, three distinct classes of GS1 genes have been identified (alpha, beta, and gamma). Genomic Southern analysis and analysis of hybrid-select translation products suggest that each class has two distinct members. The alpha forms are the major isoforms in the cotyledons and young roots. The beta forms, although constitutive in their expression pattern, are ammonia inducible and show high expression in N2-fixing nodules. The gamma1 gene appears to be more nodule specific, whereas the gamma2 gene member, although nodule enhanced, is also expressed in the cotyledons and flowers. The two members of the alpha and beta class of GS1 genes show subtle differences in the expression pattern. Analysis of the promoter regions of the gamma1 and gamma2 genes show sequence conservation around the TATA box but complete divergence in the rest of the promoter region. We postulate that each member of the three GS1 gene classes may be derived from the two ancestral genomes from which the allotetraploid soybean was derived.     

The presence of a Sar1 gene family in Brassica campestris that suppresses a yeast vesicular transport mutation Sec12-1

Two new members (Bsar1a and Bsar1b) of the Sar1 gene family have been identified from a flower bud cDNA library of Brassica campestris and their functional characteristics were analyzed. The two clones differ from each other at 14 positions of the 193 amino acid residues deduced from their coding region. The amino acid sequences of Bsar1a and Bsar1b are most closely related to the Sar1 family, genes that function early in the process of vesicle budding from the endoplasmic reticulum (ER). The sequences contain all the conserved motifs of the Ras superfamily (G1–G4 motifs) as well as the distinctive structural feature near the C-terminus that is Sar1 specific. Our phylogenetic analysis confirmed that these two clones can indeed be considered members of the Sar1 family and that they have a close relationship to the ARF family. The Bsar1 proteins, expressed in Escherichia coli, cross-reacted with a polyclonal antibody prepared against Saccharomyces cerevisiae Sar1 protein. It also exhibited GTP-binding activity. Genomic Southern blot analysis, using the 3'-gene-specific regions of the Bsar1 cDNAs as probes, revealed that the two cDNA clones are members of a B. campestris Sar1 family that consists of 2 to 3 genes. RNA blot analysis, using the same gene-specific probes, showed that both genes are expressed with similar patterns in most tissues of the plant, including leaf, stem, root, and flower buds. Furthermore, when we placed the two Bsar1 genes under the control of the yeast pGK1 promoter into the temperature-sensitive mutant yeast strain S. cerevisiae Sec12-1, they suppressed the mutation which consists of a defect in vesicle transport. The amino acid sequence similarity, the GTP-binding activity, and the functional suppression of the yeast mutation suggest that the Bsar1 proteins are functional homologues of the Sar1 protein in S. cerevisiae and that they may perform similar biological functions.     

A hyaluronan binding link protein gene family whose members are physically linked adjacent to chondroitin sulfate proteoglycan core protein genes: the missing links

We describe a vertebrate hyaluronan and proteoglycan binding link protein gene family (HAPLN), consisting of four members including cartilage link protein. The encoded proteins share 45-52% overall amino acid identity. In contrast to the average sequence identity between family members, the sequence conservation between vertebrate species was very high. Human and mouse link proteins share 81-96% amino acid sequence identity. Two of the four link protein genes (HAPLN2 and HAPLN4) were restricted in expression to the brain/central nervous system, while one of the four genes (HAPLN3) was widely expressed. Genomic structures revealed that all four HAPLN genes were similar in exon-intron organization and were also similar in genomic organization to the 5' exons for the CSPG core protein genes. Strikingly, all four HAPLN genes were located immediately adjacent to the four CSPG core protein genes creating four pairs of CSPG-HAPLN genes within the mammalian genome. Furthermore, the two brain-specific HAPLN genes (HAPLN2 and HAPLN4) were physically linked to the brain-specific CSPG genes encoding brevican and neurocan, respectively. The tight physical association of the HAPLN and CSPG genes supports a hypothesis that the first HAPLN gene arose as a partial gene duplication event from an ancestral CSPG gene. There is some degree of coordinated expression of each gene pair. Collectively, the four HAPLN genes are expressed by most tissue types, reflecting the fundamental importance of the hyaluronan-dependent extracellular matrix to tissue architecture and function in vertebrate species. Comparison of the genomic structures for the HAPLN, CSPG genes and other members of the link module superfamily provide strong support for a common evolutionary origin from an ancestral gene containing one link module encoding exon.     

Homologues of amino acid permeases: cloning and tissue expression of XAT1 and XAT2

The L-type (LAT) family of amino acid transporters is composed of exchangers for neutral, cationic, and anionic amino acids. They form functional heterodimers with membrane glycoproteins, rBAT or 4F2hc/CD98, to which they are linked by a disulphide bond. We report the molecular cloning and tissue expression of new mouse and human homologues of the LAT family, termed mXAT1, mXAT2 and hXAT2. The latter two proteins may correspond to ortholog genes in mouse and human. The hXAT2 gene is located on chromosome 8q21.3. The cloned X amino acid transporter (XAT) cDNAs are predicted to encode proteins of about 50 kDa. From a phylogenetic point of view, the three XAT proteins cluster together, but sequence comparison and secondary structure prediction show that they are also related to the members of the LAT family. Like these transporters, the XAT proteins show 12 transmembrane domains and a conserved cysteine residue, located in the second extracellular loop. This conserved cysteine is involved in the disulphide bond formed between the known members of the LAT family and 4F2hc or rBAT. The mXAT1 and hXAT2 mRNAs are expressed in the kidney but they are not detectable in a variety of other tissues. The corresponding proteins were efficiently translated following transfection of their cDNAs in Chinese hamster ovary (CHO) cells. However, cDNA transfection in CHO cells did not induce amino acid uptake, even when cotransfected with vectors expressing 4F2hc or rBAT. This could be related to the fact that mXAT1 and hXAT2 did not form detectable disulphide-linked heterodimers with 4F2hc or rBAT when they were co-expressed in CHO cells. Identification of other putative partner(s) of these LAT family-related transporters may be necessary to understand their role in renal physiology.     

Characterization of the tobacco eIF-4A gene family

Characterization of cDNAs encoding eukaryotic translation initiation factor 4A (eIF-4A) indicates the expression of a minimum of ten related genes in tobacco leaf cells. The ten groups fall into two gene families, NeIF-4A2 and NeIF-4A3. The majority of the cDNAs exhibit significant sequence similarity to the NeIF-4A2 family at both the DNA and deduced amino acid levels. Northern analysis using specific probes indicates variable expression of four family members in various tobacco organs. Western analysis, using an anti-tobacco eIF-4A polyclonal antibody, reveals a complex pattern of immunologically related polypeptides of approximately 46 kDa. Subcellular fractionation suggests that at least one eIF-4A-related polypeptide is located in the chloroplast where it is ribosome-associated.     

Length polymorphism of PCR-amplified genomic fragments of the Pregnancy-Associated Glycoprotein (PAG) gene family in the pig and some other domestic and wild mammals

Porcine pregnancy-associated glycoprotein genes (pPAG) are known as a multigene family, in which five members have been cloned and sequences of their cDNAs identified. Porcine PAG1 and pPAG3 genes, belonging to the pPAG1-like subfamily, both encode enzymatically inactive precursors. In contrast, cDNAs of pPAG2, pPAG4 and pPAG6 represent the pPAG2-like gene subfamily, encoding enzymatically active precursors. The objective of this study was to investigate the polymorphism of both pPAG-like gene subfamilies in the pig in comparison to other domestic species, including cattle, sheep and goat (Artiodactyla), their wild relatives (red deer and wild pig) and horse (Perissodactyla). This is the first paper indicating the polymorphism of the pPAG gene family, examined by lengths of amplified genomic fragments (PCR). Obtained PCR products were analysed in relation to five characterised cDNAs of pPAGs (pPAG1-like and/or pPAG2-like subfamilies) and according to one recognised structural exon-intron organisation of the pPAG2 gene, among at least eight pPAG2-like genes expected in the porcine genome. The highest polymorphism frequency of both pPAG1- and pPAG2-like gene subfamilies was found in the second region, exons 5 and 6 (with intron E). The length of PCR-amplified genomic fragments was approximately: 1043, 700, 600 and 193 bp. A high polymorphism frequency was found in the 3'-terminal fragment, corresponding to exons 7-9 (with introns G and H), more frequent the pPAG2-like gene subfamily. The length of PCR-amplified genomic fragments was approximately: 733, 650 and 356 bp. In contrast, PAG polymorphism was not detected in another region, encompassing exons 2-4 (with introns B and C). The length of PCR-amplified genomic fragments was approximately 279 bp in all examined genomes. In conclusion, amplification of various regions of the PAG gene family presents a relatively inexpensive PCR method of animal pre-selection with different genotypes. Such a pre-selection of animals is helpful for further gene number inquiry of the PAG gene family in each animal, then in related generations. The obtained results provide a useful background for a genetic marker preparation (by Southern analysis of the PAG family) that will presumably enable an economical early selection of young animals for effective reproduction.