Sequence comparisons of developmentally regulated collagen genes of Caenorhabditis elegans

Collagen genes col-6, col-7 (partial), col-8, col-14 and col-19 from the nematode Caenorhabditis elegans were sequenced, and compared to the previously sequenced genes col-1 and col-2. The genes are between 1.0 and 1.2 kb in length, and each includes one or two short introns. The presumptive promoter regions contain sequences similar to the eukaryotic TATA promoter element. Two distinct, conserved sequences were found in the presumptive promoter regions of, respectively, the dauer larva-specific genes col-2 and col-6, and the primarily adult-specific genes col-7 and col-19. The domain structures of the collagen polypeptides are similar: each polypeptide contains two triple-helix forming (Gly-X-Y)n domains, one of 30-33 amino acids (aa), and the other of 127-132 aa. The latter domain is interrupted by one to three short (2-8 aa) non-(Gly-X-Y)n segments that occur at relatively conserved locations in each polypeptide. Sets of cysteine residues flank the (Gly-X-Y)n domains in all of the polypeptides. The genes can be placed into three families based upon amino acid sequence similarities. Genes within a family do not always exhibit similar developmental expression programs, suggesting that structural and regulatory regions of the genes have evolved separately. The codon usage in the genes is highly asymmetrical, with adenine appearing in the third position of 85% of the glycine codons, and 93% of the proline codons.     

Domain organization and intron positions inCaenorhabditis elegans collagen genes: The 54-bp module hypothesis revisited

Summary The amino acid (aa) sequences of the polypeptides encoded by five collagen genes of the nematodeCaenorhabditis elegans, col-6, col-7 (partial),col-8, col-14, andcol-19, were determined. These collagen polypeptides, as well as those encoded by the previously sequencedC. elegans collagen genescol-1 andcol-2, share a common organization into five domains: an amino-terminal leader, a short (30–33 aa) (Gly-X-Y) _n domain, a non(Gly-X-Y) spacer, a long (127–132 aa) (Gly-X-Y) _n domain, and a short carboyl-terminal domain. The domain organizations and intron positions of these polypeptides were compared with those of the polypeptides encoded byDrosophila andStrongylocentrotus type IV, and vertebrate types I, II, III, IV, and IX collagen genes; theC. elegans collagen polypeptides are most similar to the vertebrate type IX collagents. It is suggested that the collagen gene family comprises two divergent subfamilies, one of which includes the vertebrate interstitial collagen genes, and the other of which includes the invertebrate collagen genes and the vertebrate type IV and type IX collagen genes. Only the vertebrate interstitial collagen genes display clear evidence of evolution via the tandem duplication of a 54-bp exon.     

The Caenorhabditis elegans rol-6 gene, which interacts with the sqt-1 collagen gene to determine organismal morphology, encodes a collagen.

The rol-6 gene is one of the more than 40 loci in Caenorhabditis elegans that primarily affect organismal morphology. Certain mutations in the rol-6 gene produce animals that have the right roller phenotype, i.e., they are twisted into a right-handed helix. The rol-6 gene interacts with another gene that affects morphology, sqt-1; a left roller allele of sqt-1 acts as a dominant suppressor of a right roller allele of rol-6. The sqt-1 gene has previously been shown to encode a collagen. We isolated and sequenced the rol-6 gene and found that it also encodes a collagen. The rol-6 gene was identified by physical mapping of overlapping chromosomal deficiencies that cover the gene and by identification of an allele-specific restriction site alteration. The amino acid sequence of the collagen encoded by rol-6 is more similar to that of the sqt-1 collagen than to any of the other ten C. elegans cuticle collagen sequences compared. The locations of cysteine residues flanking the Gly-X-Y repeat regions of rol-6 and sqt-1 are identical, but differ from those in the other collagens. The sequence similarities between rol-6 and sqt-1 indicate that they represent a new collagen subfamily in C. elegans. These findings suggest that these two collagens physically interact, possibly explaining the genetic interaction seen between the rol-6 and sqt-1 genes.     

The six genes of the Rubisco small subunit multigene family from Mesembryanthemum crystallinum,a facultative CAM plant

The nucleotide sequences of the entire gene family, comprising six genes, that encodes the Rubisco small subunit (rbcS) multigene family in Mesembryanthemum crystallinum (common ice plant), were determined. Five of the genes are arranged in a tandem array spanning 20 kb, while the sixth gene is not closely linked to this array. The mature small subunit coding regions are highly conserved and encode four distinct polypeptides of equal lengths with up to five amino acid differences distinguishing individual genes. The transit peptide coding regions are more divergent in both amino acid sequence and length, encoding five distinct peptide sequences that range from 55 to 61 amino acids in length. Each of the genes has two introns located at conserved sites within the mature peptide-coding regions. The first introns are diverse in sequence and length ranging from 122 by to 1092 bp. Five of the six second introns are highly conserved in sequence and length. Two genes, rbcS-4 and rbcS-5, are identical at the nucleotide level starting from 121 by upstream of the ATG initiation codon to 9 by downstream of the stop codon including the sequences of both introns, indicating recent gene duplication and/or gene conversion. Functionally important regulatory elements identified in rbcS promoters of other species are absent from the upstream regions of all but one of the ice plant rbcS genes. Relative expression levels were determined for the rbcS genes and indicate that they are differentially expressed in leaves.     

A conserved nucleotide sequence, coding for a segment of the C-propeptide, is found at the same location in different collagen genes.

The nucleotide sequence of a segment of the chick alpha 1 type III collagen gene which codes for the C-propeptide was determined and compared with the corresponding sequence in the alpha 1 type I and alpha 2 type I collagen genes. As in the alpha 2 type I gene the coding information for the C-propeptide of the type III collagen gene is subdivided in four exons. Similarly, the amino proximal exon contains sequences for both the carboxy terminal end of the alpha-helical segment of collagen and for the beginning of the C-propeptide in both genes. Therefore, this organization of exons must have been established before these two collagen genes arose by duplication of a common ancestor. In several subsegments the deduced amino acid sequence for the C-propeptide of type III collagen shows a strong homology with the corresponding amino acid sequence in alpha 1 and alpha 2 type I. For one of these homologous amino acid sequences, however, the nucleotide sequence is much better conserved than for the others. It is possible that a mechanism of gene conversion has maintained the homogeneity of this nucleotide sequence among the interstitial collagen genes. Alternatively, the conserved nucleotide sequence may represent a regulatory signal which could function either in the DNA or in the RNA.     

Actin gene family of Caenorhabditis elegans

Four actin genes have been isolated from Caenorhabditis elegans that account for all of the major actin hybridization to total genomic DNA. Actin genes I, II and III are clustered within a 12 X 10(3) base region; gene IV is unlinked to the others. All four genes have been sequenced from at least nucleotide -109 to +250. Genes I and III are identical for the first 307 coding nucleotides. Genes I and II differ in 14 positions within the first 250 coding nucleotides; one difference substitutes an aspartic acid for a glutamic acid at codon 5. Genes I and IV differ in 18 positions within the first 259 coding nucleotides without causing any amino acid differences. Genes I, II and III have introns after the first nucleotide of codon 64 and gene IV has an intron between codons 19 and 20. The four nucleotide sequences thus far define two different amino acid sequences. Both of the amino acid sequences resemble vertebrate cytoplasmic actin more than vertebrate muscle actin. A DNA polymorphism between the Bristol and Bergerac strains has been used as a phenotypic marker in genetic crosses to map the cluster of actin genes within a 2% recombination interval on linkage group V between unc-23 and sma-1 in order to begin a molecular genetic analysis of the actin loci.     

The comparative amino acid sequences, substrate specificities and gene or cDNA nucleotide sequences of some prokaryote and eukaryote amidinotransferases: implications for evolution

The amino acid sequences of the amidinotransferases and the nucleotide sequences of their genes or cDNA from four Streptomyces species (seven genes) and from the kidneys of rat, pig, human and human pancreas were compared. The overall amino acid and nucleotide sequences of the prokaryotes and eukaryotes were very similar and further, three regions were identified that were highly identical. Evidence is presented that there is virtually zero chance that the overall and high identity regions of the amino acid sequence similarities and the overall nucleotide sequence similarities between Streptomyces and mammals represent random match. Both rat and lamprey amidinotransferases were able to use inosamine phosphate, the amidine group acceptor of Streptomyces. We have concluded that the structure and function of the amidinotransferases and their genes has been highly conserved through evolution from prokaryotes to eukaryotes. The evolution has occurred with: (1) a high degree of retention of nucleotide and amino acid sequences; (2) a high degree of retention of the primitive Streptomyces guanine+cytosine (G+C) third codon position composition in certain high identity regions of the eukaryote cDNA; (3) a decrease in the specificities for the amidine group acceptors; and (4) most of the mutations silent in the regions suggested to code for active sites in the enzymes.     

Primary structure and differential expression of glutamine synthetase genes in nodules, roots and leaves of Phaseolus vulgaris

In plants, glutamine synthetase (GS) is the enzyme primarily responsible for the assimilation of ammonia into organic nitrogen. In Phaseolus vulgaris a number of isoenzymic forms of GS are found, each of which consists of eight subunits of mol. wt 41 000-45 000. The GS subunits of P. vulgaris have previously been shown to be encoded by a small multigene family and a partial cDNA clone for a nodule-specific GS subunit has been obtained. We report here the isolation and nucleotide sequencing of two essentially full-length GS cDNA clones (pR-1 and pR-2) from a root cDNA library and the deduced amino acid sequences of the corresponding GS subunits (355 amino acid residues each). The coding sequences of pR-1 and pR-2 are closely related (80% nucleotide homology, 88% amino acid homology), but their 5'- and 3'-untranslated regions have diverged almost completely. Both pR-1 and pR-2 are related to, but distinct from, the nodule GS clone, pcPvNGS-01 (or pN-1). Hybridization to genomic Southern blots showed that the three GS mRNAs are encoded by three seperate genes and indicated the existence of a fourth class of GS gene. An S1 nuclease protection assay demonstrated the presence of R-1 and R-2 mRNA in both roots and leaves and confirmed that expression of the N-1 gene is nodule-specific. Expression of the R-1 and R-2 genes in the roots did not change significantly during nodulation. However, only the R-1 gene is expressed in the nodules themselves, indicating that the R-2 gene is specifically repressed during nodule development.     

Nucleotide sequences of Caenorhabditis elegans core histone genes. Genes for different histone classes share common flanking sequence elements

We have determined the nucleotide sequence of core histone genes and flanking regions from two of approximately 11 different genomic histone clusters of the nematode Caenorhabditis elegans. Four histone genes from one cluster (H3, H4, H2B, H2A) and two histone genes from another (H4 and H2A) were analyzed. The predicted amino acid sequences of the two H4 and H2A proteins from the two clusters are identical, whereas the nucleotide sequences of the genes have diverged 9% (H2A) and 12% (H4). Flanking sequences, which are mostly not similar, were compared to identify putative regulatory elements. A conserved sequence of 34 base-pairs is present 19 to 42 nucleotides 3' of the termination codon of all the genes. Within the conserved sequence is a 16-base dyad sequence homologous to the one typically found at the 3' end of histone genes from higher eukaryotes. The C. elegans core histone genes are organized as divergently transcribed pairs of H3-H4 and H2A-H2B and contain 5' conserved sequence elements in the shared spacer regions. One of the sequence elements, 5' CTCCNCCTNCCCACCNCANA 3', is located immediately upstream from the canonical TATA homology of each gene. Another sequence element, 5' CTGCGGGGACACATNT 3', is present in the spacer of each heterotypic pair. These two 5' conserved sequences are not present in the promoter region of histone genes from other organisms, where 5' conserved sequences are usually different for each histone class. They are also not found in non-histone genes of C. elegans. These putative regulatory sequences of C. elegans core histone genes are similar to the regulatory elements of both higher and lower eukaryotes. The coding regions of the genes and the 3' regulatory sequences are similar to those of higher eukaryotes, whereas the presence of common 5' sequence elements upstream from genes of different histone classes is similar to histone promoter elements in yeast.     

Comprehensive cloning of Schizosaccharomyces pombe genes encoding translation elongation factors

In the course of the Schizosaccharomyces pombe cDNA project, we succeeded in cloning all the genes encoding translation elongation factors EF-1α, EF-1β, EF-1γ, EF-2 and EF-3. With the exception of the EF-1γ gene, the nucleotide (nt) sequence of S. pombe elongation factors has not been previously reported. For EF-1α, we found three genes whose amino acid (aa) sequences are quite homologous each other (99.5%), but whose 3′ untranslated regions (UTRs) are completely different. Southern blot indicated that those three EF-1α genes are located at different loci. Northern analysis indicated that one of three EF-1α genes was inducible with UV-irradiation, while the level of expression for another of three EF-1α genes was repressed by UV and heat-shock (HS) treatments. The aa sequence predicted from the nt sequence of the S. pombe EF-1β cDNA clone covered almost all the coding sequence (CDS) of EF-1β except the first methionine which has 55.4% identity with that of S. cerevisiae. We also identified two copies of S. pombe EF-2 genes. Their aa sequences deduced from nt sequences are identical (100%), but they have different 3′ UTRs. The location of these two EF-2 genes in different loci was proved by Southern analysis. The S. pombe EF-3 cDNA clone encoded only a third of the CDS from the C-terminal and its deduced aa sequence has a 76% identity with those of other yeasts and fungi.     

Sequence and expression of the discoidin I gene family in Dictyostelium discoideum

We have isolated recombinant phage and plasmids containing the four developmentally regulated discoidin I genes of Dictyostelium discoideum. Two of the genes are linked within 0.5 × 10³ bases with the same polarity. S¹ nuclease mapping shows that at least three members of the gene family are expressed and that the 5′ ends of the mRNAs start at equivalent sites. The genes have homologous 5′ untranslated regions and extremely divergent 3′ untranslated regions. In addition, some of the genes are flanked by homologous repeat sequences. The genes encode three different isoelectric forms of the protein. Examination of nucleotide sequences in the protein coding region shows that most nucleotide changes in the 5′ half of the gene result in amino acid substitutions while most base substitutions in the 3′ half are neutral.