Genomic organization of the extracellular coding region of the human FGFR4 and FLT4 genes: Evolution of the genes encoding receptor tyrosine kinases with immunoglobulin-like domains

Receptor tyrosine kinases with five, seven, and three Ig-like domains in their extracellular region are grouped in subclasses IIIa, IIIb, and IIIc, respectively. Here, we describe the genomic organization of the extracellular coding region of the human FGFR4 (IIIc) and FLT4 (IIIb) genes and compare it to that of the human FGFR1(IIIc), KIT, and FMS (IIIa). The results show that while genes belonging to the same subclass have an identical exon/intron structure in their extracellular coding region—as they do in their intracellular coding region—genes of related subclasses only have a similar exon/intron structure. These results strongly support the hypothesis that the genes of the three subclasses evolved from a common ancestor by duplications involving entire genes, already in pieces. Hypotheses on the origin of introns and on the difference in the number of extracellular Ig-like domains in the three gene subclasses are discussed. Received: 19 August 1996 / Accepted: 2 January 1997     

Expression of tandem invertase genes associated with sexual and vegetative growth cycles in potato

The organisation of two invertase genes (invGE and invGF) linked in direct tandem repeat within the potato genome is detailed. The genes exhibit a similar intron/exon structure which differs from previously described plant invertase genes; while intron locations are conserved between the genes, minor differences in exon length are seen. Both genes encode enzymes with putative extracellular location. Biochemical analysis of gene expression showed expression in floral tissues for both genes, with expression of the upstream gene (invGE) also detected in leaf tissue. Promoter sequences from both genes have been fused to the -glucuronidase (GUS) reporter gene (uidA) and transformed into potato. One promoter-GUS reporter construct was also transformed into tobacco. Histochemical analysis of transgenic lines defined specific expression from the downstream (invGF) promoter in potato and tobacco pollen, with expression first detected in the late uninucleate stage of tobacco microspore development. The invGE promoter determined expression in pollen and other floral tissues, but also at lateral nodes in stem, root and tuber. An association of invertase expression with generative tissue, both in vegetative and sexual modes of growth, is indicated.     

Introns in,introns out in plant gene families: a genomic approach of the dynamics of gene structure

Gene duplication is considered to be a source of genetic information for the creation of new functions. The Arabidopsis thaliana genome sequence revealed that a majority of plant genes belong to gene families. Regarding the problem of genes involved in the genesis of novel organs or functions during evolution, the reconstitution of the evolutionary history of gene families is of critical importance. A comparison of the intron/exon gene structure may provide clues for the understanding of the evolutionary mechanisms underlying the genesis of gene families. An extensive study of A. thaliana genome showed that families of duplicated genes may be organized according to the number and/or density of intron and the diversity in gene structure. In this paper, we propose a genomic classification of several A. thaliana gene families based on introns in an evolutionary perspective. abbreviations BGAL, -galactosidases; PCMP, plant combinatorial and modular protein     

Hypervariable and Highly Divergent Intron–Exon Organizations in the Chordate Oikopleura dioica

Oikopleura dioica is a pelagic tunicate with a very small genome and a very short life cycle. In order to investigate the intron–exon organizations in Oikopleura, we have isolated and characterized ribosomal protein EF-1, Hox, and -tubulin genes. Their intron positions have been compared with those of the same genes from various invertebrates and vertebrates, including four species with entirely sequenced genomes. Oikopleura genes, like Caenorhabditis genes, have introns at a large number of nonconserved positions, which must originate from late insertions or intron sliding of ancient insertions. Both species exhibit hypervariable intron–exon organization within their -tubulin gene family. This is due to localization of most nonconserved intron positions in single members of this gene family. The hypervariability and divergence of intron positions in Oikopleura and Caenorhabditis may be related to the predominance of short introns, the processing of which is not very dependent upon the exonic environment compared to large introns. Also, both species have an undermethylated genome, and the control of methylation-induced point mutations imposes a control on exon size, at least in vertebrate genes. That introns placed at such variable positions in Oikopleura or C. elegans may serve a specific purpose is not easy to infer from our current knowledge and hypotheses on intron functions. We propose that new introns are retained in species with very short life cycles, because illegitimate exchanges including gene conversion are repressed. We also speculate that introns placed at gene-specific positions may contribute to suppressing these exchanges and thereby favor their own persistence.Supplementary material () is available for this article.     

Ubiquitin promoter-based vectors for high-level expression of selectable and/or screenable marker genes in monocotyledonous plants

A set of plasmids has been constructed utilizing the promoter, 5 untranslated exon, and first intron of the maize ubiquitin (Ubi-1) gene to drive expression of protein coding sequences of choice. Plasmids containing chimaeric genes for ubiquitin-luciferase (Ubi-Luc), ubiquitin--glucuronidase (Ubi-GUS), and ubiquitin-phosphinothricin acetyl transferase (Ubi-bar) have been generated, as well as a construct containing chimaeric genes for bothUbi-GUS andUbi-bar in a single plasmid. Another construct was generated to allow cloning of protein coding sequences of choice onBam HI andBam HI-compatible restriction fragments downstream of theUbi-1 gene fragment. Because theUbi-1 promotor has been shown to be highly active in monocots, these constructs may be useful for generating high-level gene expression of selectable markers to facilitate efficient transformation of monocots, to drive expression of reference reporter genes in studies of gene expression, and to provide expression of biotechnologically important protein products in transgenic plants.     

Legumin-like and vicilin-like seed storage proteins: Evidence for a common single-domain ancestral gene

Legumin-like 11S and vicilin-like 7S globulins are the main storage proteins of most angiosperms and gymnosperms. The subunits of the hexameric legumin are synthesized as a precursor comprising a N-terminal acidic - and a C-terminal basic -chain. The trimeric vicilin molecule consists of subunits composed of two symmetrical N- and C-terminal structural domains.In a multiple alignment we have compared the N-terminal and C-terminal domains of 11 legumns and seven vicilins of several dicot, monocot, and gymnosperm species. The comparisons using all six possible pairwise combinations reveal that the N-terminal and C-terminal domains of both protein families are similar to each other. These results together with data on the distribution of variable and conserved regions, on the positions of susceptible sites for proteolytic attack, as well as on the published 7S protein tertiary structure suggest that both protein families share a common single-domain ancestor molecule and lead to the hypothesis that a triplication event has occurred during the evolution of a putative legumin/vicilin ancestor gene.Moreover, the comparison of the intron/exon pattern reveals that at least three out of five intron positions are precisely conserved between the genes of both protein families, further supporting the idea of a common evolutionary origin of recent legumin and vicilin encoding genes. Correspondence to: H. Bäumlein     

Allelic diversity at the primateMhc-G locus: Exon 3 bears stop codons in allCercophitecinae sequences

Twenty-seven major histocompatibility complex (Mhc)-G exon 2, exon 3, and exon 2 and 3 allelic sequences were obtained together with 12 different intron 2 sequences.Homo sapiens, Pan troglodytes, Pan paniscus, Gorilla gorilla, Pongo pygmaeus, Macaca fascicularis, Macaca mulatta, andCercopithecus aethiops individuals were studied. Polymorphism does not follow the classical pattern of three hypervariable regions per domain and is found in all species studied; exon 3 (equivalent to the 2 protein domain) shows stop codons in theCercopithecinae group but not in thePongidae and human groups. Dendrograms show that cotton top tamarin (Saguinus oedipus) Mhc-G sequences are closer toHomo sapiens andPongidae than toCercopithecinae, probably due to the stop codons existing at exon 3 of the latter. There is a clear trans-species evolution of allelism inCercopithecinae and also in exon 2 of all the other apes studied, but a generation of allelism within each species may be present on exon 3 sequences. This discrepancy may be due to the preferential use of exon 2 over exon 3 at the mRNA splicing level within each species in order to obtain the appropriate functional G product.Mhc-G intron 2 shows conserved motifs in all species studied, particularly a 23 base pair deletion between positions 161 and 183 which is locus specific, and some of the invariant residues, important for peptide presentation, conserved in classical class 1 molecules from fish and reptiles to humans were not found inMhc-G alleles; the intron 2 Dendrogram also shows a particular pattern of allelism within each species. In summary,Mhc-G has substantial differences from other classical class I genes: polymorphism patterns, tissue distribution, gene structure, splicing variability, and probably an allelism variability within each species at exon 3. The G proteins may also be different. This indicates that theMhc-G function may not be peptide presentation to the clonotypic T-cell receptor.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence data base and have been assigned the accession numbers L41362 (HLA-G*01012), L41363 (HLA-G*01013), U33307 (intron 2HLA-G sequence from BeWo cell line), L48999 (Patr-Mhc-G*I), U33291 [Patr Mhc-G*II(3)], L49003 (intron 2Patr Mhc-G*I sequence), L48998 (Gogo Mhc-G*I), L49002 (intron 2Gogo Mhc-G*I sequence), L49000 (Popy Mhc-G*I), L49001 (Popy Mhc-G*II), L49004 (intron 2Popy Mhc-G*I sequence), L49005 (intron 2Popy Mhc-G*II sequence), U33312 (Mafa Mhc-G*I), U33301 (Mafa Mhc-G*II), U33302 (Mafa Mhc-G*III), U33303 (Mafa Mhc-G*IV), L41257 [Mafa Mhc-G*V(3)], L41259 [Mafa Mhc-G*VI(3)], L41260 [Mafa Mhc-G*VII(3)], U33296 (intron 2Mafa Mhc-G*I/*II/*III sequence), U33297 (intron 2Mafa Mhc-G*IV sequence), U33304 (Mamu Mhc-G*I), U33305 (Mamu Mhc-G*II), U33306 (Mamu Mhc-G*III), U33295 (Mamu Mhc-G*IV), L41263 [Mamu Mhc-G*V(3)], L41261 [Mamu Mhc-G*VI(3)], L41264 [Mamu Mhc-G*VII(3)], U33298 (intron 2Mamu Mhc-G*I/III sequence), U33299 (intron 2Mamu Mhc-G*II sequence), U33300 (intron 2Mamu Mhc-G*IV sequence), U33310 (Ceae Mhc-G*I), U33311 (Ceae Mhc-G*II), U33308 (intron 2Ceae Mhc-G*I sequence), and U33309 (intron 2Ceae Mhc-G*II)The contribution by M.J. Castro and P. Morales is equal and the order of authorship is arbitrary     

Origin and molecular evolution of receptor tyrosine kinases with immunoglobulin-like domains

Receptor tyrosine kinases (RTKs) are involved in the control of fundamental cellular processes in metazoans. In vertebrates, RTK could be grouped in distinct classes based on the nature of their cognate ligand and modular composition of their extracellular domain. RTK with immunoglobulin-like domains (IG-like RTK) encompass several RTK classes and have been found in early metazoans, including sponges. Evolution of IG-like RTK is characterized by extended molecular and functional diversification, which prompted us to study their evolutionary history. For that purpose, a nonredundant data set including annotated protein sequences of IG-like RTK (n = 85) was built, representing 19 species ranging from sponges to humans. Phylogenetic trees were generated from alignment of conserved regions using maximum likelihood approach. Molecular phylogeny strongly suggests that IG-like RTK diversification occurred according to a complex scenario. In particular, we propose that specific cis duplications of a common ancestor to both platelet-derived growth factor receptor (class III) and vascular endothelial growth factor receptor (class V) families preceded two trans duplications. In contrast, other IG-like RTK genes, like Musk and PTK7, apparently did not evolve by duplications, whereas fibroblast growth factor receptors (class IV) evolved through two rounds of trans duplications. The proposed model of IG-like RTK evolution is supported by high bootstrap values and by the clustering of genes encoding class III and class V RTKs at specific chromosomal locations in mouse and human genomes.     

Conserved and variable repeat structures in the Balbiani ring gene family in Chironomus tentans

Summary The four Balbiani ring (BR) genes, BR1, BR2.1, BR2.2, and BR6 in the midge Chironomus tentans constitute a gene family encoding secretory proteins with molecular weights of approximately 10⁶ daltons. The major part of each gene is known to consist of tandemly organized composite repeat units resulting in a hierarchic repeat arrangement.Here, we present the sequence organization of the 5 part of the BR2.2 and BR6 genes and describe the entire transcribed part of the two genes. As the BR1 and BR2.1 genes were also fully characterized recently, this allows the comparison of all genes in the BR gene family.All four genes share the same exon-intron structure and have evolved by gene duplications starting from a common ancestor, having the same overall organization as the BR genes of today.The genes encode proteins that have an approximately 10,000-amino acid residue extended central domain, flanked by a highly charged, 200-residue amino-terminal domain and a globular 110-residue carboxy-terminal domain. Exons 1–3 and the beginning of exon 4 encode the amino-terminal domain, which throughout contains many regions built from short repeats. These repeats are often degenerate as to repeat unit and sequence and are present in different numbers between the genes. In several instances these repeat structures, however, are conserved at the protein level where they form positively or negatively charged regions.Each BR gene has a 26–38-kb-long exon 4, which consists of an array of 125–150 repeat units and encodes the central domain. The number of repeat units appears to be largely preserved by selection and all repeat units in the array are very efficiently homogenized. Occasionally variant repeats have been introduced, presumably from another BR gene by gene conversion, and spread within the array.Introns 1–3 at the 5 end of the genes have diverged extensively in sequence and length between the genes. In contrast, intron 4 at the 3 end is virtually identical between three of the four genes, suggesting that gene conversion homogenizes the 3 ends of the genes, but not the 5 ends. Offprint requests to: L. Wieslander     

Intron and exon length variation in <Emphasis Type="Italic">Arabidopsis</Emphasis>, rice,nematode, and human

As determined by computer sequence analysis, the average exon length in Arabidopsis thaliana, Oryza sativa, Caenorhabditis elegans, and Homo sapiens genes decreases with an increasing number of introns. In A. thaliana and O. sativa, variations in intron and exon lengths with an increasing number of introns are highly correlated. Linear correlation is observed between the total exon length and the number of introns, while the gene length increases in proportion to the number of introns. In human, the average intron and gene lengths depended on the gene density in DNA.     

Intron length variation of the Adh gene in Brachyscome (Asteraceae)

Eighteen polymerase chain reaction (PCR) products of the partial sequence of the Adh (alcohol dehydrogenase) gene from 10 Brachyscome species were sequenced and compared. These products contained the 5 three fourths of exon 4 and whole sequences of intron 3. They varied extensively in length due to the differences in length of intron 3. A total of 10 long insertions were flanked by direct repeats of 5 to 12 bp sequences, indicating inserted elements. These inserted elements were classified into the following five categories based on nucleotide sequence characteristics and length; (1) a region homologous to that of 5S RNA genes (5S DNA), (2) A-rich structure at the 3 end-like short interspersed elements (SINEs) in animals, (3) a sequence of 280 bp with no characteristic features, (4) a sequence of 125 bp with no characteristic features, (5) termini of 11 bp inverted repeats flanked by 5 bp sequence of direct repeats characteristics of a transposon.     

Rps3 and rpl16 genes do not overlap in Oenothera mitochondria: GTG as a potential translation initiation codon in plant mitochondria?

Characterization of the Oenothera mitochondrial ribosomal gene cluster rps19-rps3-rpl16 shows the two genes rps3 and rpl16 to be separated by 9 nucleotides. The first codon of rpl16 is a GTG codon for valine and the only potential translational start. This GTG codon is conserved at the same position in maize, Petunia and Marchantia mitochondria, while sequences diverge upstream. These observations suggest that GTG at least at this position may act as translation initiation codon in plant mitochondria. Analysis of RNA editing suggests both genes to code for functional ribosomal proteins in Oenothera mitochondria. A duplication/recombination event at a decanucleotide in the intron of rps3 created a pseudogene missing part of the intron and the 3 exon.     

Specific molecular marker of the genes controlling linolenic acid content in rapeseed

In rapeseed, which is an agronomically important oilseed, variation in the linolenic acid content of the oil has been obtained through chemical mutagenesis treatment. Conventional breeding of this quantitative trait, however requires specific molecular markers. By means of biochemical experiments, we have established that the induced variation in linolenic acid content is associated with the fad3 gene encoding the microsomal ¹⁵ desaturase. Using a pair of primers specific to this gene and a doubled haploid progeny derived from a low linolenic x high linolenic acid F₁hybrid, we have identified a polymorphism of the fad3 alleles between the low- and the high-linolenic acid genotypes. The structure exon/intron of the fad3 DNA sequence seems to be very similar to that of the Arabidopsis fad3 gene. The choice of the primer pair allows specific amplification of one of the two rapeseed fad3 genes. The value and contribution of specific markers to conventional plant breeding is discussed.     

The Mutation Spectrum of the CFTR Gene in Cystic Fibrosis Patients from Bashkortostan

Mutations of CFTR were studied in patients with cystic fibrosis (CF) from Bashkortostan. In total, 15 mutations were observed and 51% of all mutant alleles identified. The most diagnostically significant mutations were delF508 (33.8%), 394delTT (3.52%), CFTRdele2,3(21kb) (1.41%), R334W (1.41%), 3849 + 10kbC T (1.41%), and N1303K (1.41%). Mutations G542X, 2184insA, S1196X, and W1282X were each found in less than 1% patients. Five new mutations and two neutral substitutions were revealed. These were I488M (exon 10), 1811 + 12A C (intron 11), T663S (exon 13), I1226R (exon 19), 4005 + 9A C (intron 20), 2097A C (A655A, exon 13), and 3996G C (V1288V, exon 20). Bashkortostan was shown to differ in the CFTR mutation spectrum from other regions of Russia. The results will allow direct DNA diagnostics of CF in far more families. Molecular screening of probands" relatives will contribute to identification and medical genetic counseling of heterozygous carriers, which is essential for CF prevention.     

A Comparison of Intraspecific Patterns of DNA Sequence Variation in Mitochondrial DNA, α-Enolase,and MHC Class II B Loci in Auklets (Charadriiformes: Alcidae)

Patterns of DNA sequence variation can be used to learn about mechanisms of organismal evolution, but only if mechanisms of sequence evolution are well understood. Although theories of molecular evolution are well developed, few empirical studies have addressed patterns and mechanisms of sequence evolution in nuclear genes within species. In the present study, we compared DNA sequences among three loci with different evolutionary constraints to determine the influences of effective population size, balancing selection, and linkage on intraspecific patterns of sequence variation. Specifically, we assessed the degree and nature of polymorphism in a 307-base pair (bp) fragment of the mitochondrial cytochrome b gene, intron VIII of the gene for -enolase (a presumably neutral nuclear gene), and an ~600-bp fragment of an MHC class II B gene, including 155 bp of the hypervariable peptide binding region (a nuclear locus thought to be under balancing selection) for least and crested auklets (Aethia pusilla and A. cristatella; Charadriiformes: Alcidae). Transspecies polymorphism was found in both -enolase and the MHC but not cytochrome b and, given estimates of effective population size, probably represents retained ancestral variation. Biases in nucleotide composition suggested that mutational bias, tRNA availability, and the secondary structure of mRNA and/or DNA may influence base usage. Several lines of evidence indicated that balancing selection may be acting on the MHC II B exon 2. However, no evidence of balancing selection was observed in the intron and exon sequences immediately downstream of MHC II B exon 2. Current address (Hollie E. Walsh): Department of Zoology, University of Washington, Box 351800, Seattle, WA 98195-1800, USA     

Organization of the genes encoding chalcone synthase in Pisum sativum

To analyze the regulation of defense-related genes by signal molecules produced by phytopathogens, we isolated genes that encode chalcone synthase (CHS) in Pisum sativum. We have obtained seven independent genomic clones that contain at least seven classes of CHS genes, identified by the hybridization analysis to CHS cDNA and by the restriction mapping analysis. Two of the genomic clones (clone 5 and 6) each contain two CHS genes in a tandem repeat. The nucleotide sequence analysis of CHS genomic clone 5 revealed that PsCHS1 and PsCHS2 were corresponding genes of the CHS cDNA clones, pCC6 and pCC2, respectively, as reported earlier. Both genes are interrupted by a single intron of 88 nucleotides with identical sequences, although exonic sequences and 5-flanking sequences are divergent. Nucleotide sequences of the introns in five other classes of CHS genes showed that three classes had an intron of 87 nt with a striking homology to each other, but that the intron of the other two classes of CHS genes showed heterogeneity both in size and nucleotide sequence. 5-upstream regions of PsCHS1 and PsCHS2 did not show sequence homology except the 31 bp identical sequence that contains the CCTACC motif resembling the box-1 sequence. Both PsCHS1 and PsCHS2 genes are shown to be induced by fungal elicitor by a primer extension analysis and a transient transformation analysis using pea protoplasts prepared from suspension cultured-cells.     

Cloning of the fibroin gene from the oak silkworm, Antheraea yamamai and its complete sequence

The nucleotide sequences containing an entire genomic region and 5 upstream region of Antheraea yamamai fibroin gene have been determined. The gene consists of an initial exon encoding 14 amino acids, an intron (150 bp), and a long second exon coding for 2641 amino acids. The fibroin coding sequence shows a specialized organization with a highly repetitive region flanked by non repetitive 5 and 3 ends. Northern blot analyses confirmed that fibroin gene is actively expressed in the posterior silk gland of the final instar larvae of Antheraea yamamai.     

Development and characterization of a recombinant chicken single-chain Fv antibody detecting <Emphasis Type="Italic">Eimeria acervulina</Emphasis> sporozoite antigen

Chicken monoclonal antibody (mAb), 8C3, which is reactive with a sporozoite antigen of Eimeria acervulina, is a potential therapeutic agent against avian coccidiosis caused by Eimeria spp. However, production of large amounts of 8C3 mAb in cell culture system is labor intensive and not cost-effective. Accordingly, recombinant single chain variable fragment (ScFv) antibody was constructed by amplification of the V_H and V_L genes from chicken hybridoma, 8C3 and when expressed in E. coli gave 5 mg l^–1. The expressed protein showed antigen binding activity equivalent to that of the parental mAb. In addition, nucleotide sequence comparison of 8C3 gene to the germline chicken V_L genes suggested that the gene conversion with V pseudogenes might contribute to the diversification of V_L genes in chickens.