Family Report for: Carb_B_Nematoda

The structure of an esterase gene from Caenorhabditis elegans has been determined by comparison of the sequences in genomic and cDNA clones. The gene was mapped close to the center of chromosome V (1.7 centimorgans to the left of dpy-11) and is therefore distinct from the gut esterase gene ges-1. It possessed 7 short introns. The 5' splice site of intron 3 presented the sequence GC instead of the usual GT that was found in the other six introns. The cDNA was trans-spliced with the short leader SL1. The open reading frame indicated that a protein of 557 aminoacids was encoded. The deduced aminoacid sequence did not present a signal peptide at the N-terminal but a potential N-myristoylation site (GXXXS) provided that the initiator methionine was removed. This protein should therefore remain intracellular. Comparison of this C. elegans sequence to other protein sequences in databases, as well as the analysis of the secondary structure in the protein showed that it belongs to the subgroup of esterases in the alpha/beta hydrolase fold family.

The ges-1 gene codes for a non-specific carboxylesterase that is normally expressed only in the intestine of the nematode Caenorhabditis elegans. In the current paper, we describe the cloning and characterization of the ges-1 gene from C. elegans, as well as the homologous gene from the nematode Caenorhabditis briggsae. The ges-1 esterases from the two nematodes are 83% identical at the amino acid level and contain regions of significant similarity to insect and mammalian esterases; these conserved regions can be identified with residues believed to be necessary for esterase function. The ges-1 mRNAs from both C. elegans and C. briggsae are trans-spliced. The coding regions, the codon bias and the splicing signals of the two ges-1 genes are quite similar and most (6/7) of the intron positions are retained precisely. Yet, the flanking sequences of the two ges-1 genes appear to have diverged almost completely. For example, the C. elegans ges-1 5'-flanking region (as well as several introns) contains copies of three different SINE-like sequences, previously identified near the hsp-16 genes, near the unc-22 gene and in a repetitive element CeRep-3; none of these elements are found in the C. briggsae ges-1 gene. We show that: (1) the C. elegans ges-1 gene can be used to transform C. briggsae, whereupon expression of the exogenous ges-1 gene is confined to the C. briggsae intestine; (2) the ges-1 homologue cloned from C. briggsae can be transformed into C. elegans, whereupon it is expressed largely in the C. elegans intestine; and (3) a 5'-deletion of the C. elegans ges-1 gene that we have previously shown to be expressed in the C. elegans pharynx is also expressed in the pharynx of C. briggsae (either in the presence or absence of vector sequences). These results suggest that the ges-1 gene control circuits have been maintained between the two nematode species, despite the divergent 5'-flanking sequences of the gene. This raises the question of the evolutionary distance between C. elegans and C. briggsae and we attempt to estimate the C. elegans-C. briggsae divergence time by analysing the rate of synonymous substitutions in coding regions of ges-1 and six other C. elegans-C. briggsae gene pairs. We propose a new method of analysis, which attempts to remove rate differences found between different genes by extrapolating to zero codon bias.

Comparisons among the primary sequences of five cloned eukaryotic esterases reveal two distinct lineages, neither bearing any significant overall sequence similarity to the functionally related serine protease multigene family. We have not eliminated the possibility that the esterases may have residual conformational similarities to the serine proteases. However, our profile analysis and analyses of the predicted conformations of the esterases reveal little similarity to the serine proteases. Four of the esterase proteins share 27%-53% overall sequence similarity and evidence of a catalytic mechanism involving the same Arg-Asp-Ser or His-Asp-Ser charge relay. We propose that these four esterases, three of them cholinesterases, form part of a multigene family essentially separate from the serine proteases.

We have identified a carboxylesterase in A. suum that appears to be the homolog of the gut-specific C. elegans ges-1 enzyme. The A. suum esterase was purified and its N-terminal sequence found to be 50% identical to the C. elegans ges-1 protein. We have used isoelectric focusing analysis to demonstrate that, unlike the C. elegans ges-1 esterase, the A. suum enzyme is not restricted to the gut but is expressed in a wide range of tissues.

The structure of an esterase gene from Caenorhabditis elegans has been determined by comparison of the sequences in genomic and cDNA clones. The gene was mapped close to the center of chromosome V (1.7 centimorgans to the left of dpy-11) and is therefore distinct from the gut esterase gene ges-1. It possessed 7 short introns. The 5' splice site of intron 3 presented the sequence GC instead of the usual GT that was found in the other six introns. The cDNA was trans-spliced with the short leader SL1. The open reading frame indicated that a protein of 557 aminoacids was encoded. The deduced aminoacid sequence did not present a signal peptide at the N-terminal but a potential N-myristoylation site (GXXXS) provided that the initiator methionine was removed. This protein should therefore remain intracellular. Comparison of this C. elegans sequence to other protein sequences in databases, as well as the analysis of the secondary structure in the protein showed that it belongs to the subgroup of esterases in the alpha/beta hydrolase fold family.

The ges-1 gene codes for a non-specific carboxylesterase that is normally expressed only in the intestine of the nematode Caenorhabditis elegans. In the current paper, we describe the cloning and characterization of the ges-1 gene from C. elegans, as well as the homologous gene from the nematode Caenorhabditis briggsae. The ges-1 esterases from the two nematodes are 83% identical at the amino acid level and contain regions of significant similarity to insect and mammalian esterases; these conserved regions can be identified with residues believed to be necessary for esterase function. The ges-1 mRNAs from both C. elegans and C. briggsae are trans-spliced. The coding regions, the codon bias and the splicing signals of the two ges-1 genes are quite similar and most (6/7) of the intron positions are retained precisely. Yet, the flanking sequences of the two ges-1 genes appear to have diverged almost completely. For example, the C. elegans ges-1 5'-flanking region (as well as several introns) contains copies of three different SINE-like sequences, previously identified near the hsp-16 genes, near the unc-22 gene and in a repetitive element CeRep-3; none of these elements are found in the C. briggsae ges-1 gene. We show that: (1) the C. elegans ges-1 gene can be used to transform C. briggsae, whereupon expression of the exogenous ges-1 gene is confined to the C. briggsae intestine; (2) the ges-1 homologue cloned from C. briggsae can be transformed into C. elegans, whereupon it is expressed largely in the C. elegans intestine; and (3) a 5'-deletion of the C. elegans ges-1 gene that we have previously shown to be expressed in the C. elegans pharynx is also expressed in the pharynx of C. briggsae (either in the presence or absence of vector sequences). These results suggest that the ges-1 gene control circuits have been maintained between the two nematode species, despite the divergent 5'-flanking sequences of the gene. This raises the question of the evolutionary distance between C. elegans and C. briggsae and we attempt to estimate the C. elegans-C. briggsae divergence time by analysing the rate of synonymous substitutions in coding regions of ges-1 and six other C. elegans-C. briggsae gene pairs. We propose a new method of analysis, which attempts to remove rate differences found between different genes by extrapolating to zero codon bias.

Comparisons among the primary sequences of five cloned eukaryotic esterases reveal two distinct lineages, neither bearing any significant overall sequence similarity to the functionally related serine protease multigene family. We have not eliminated the possibility that the esterases may have residual conformational similarities to the serine proteases. However, our profile analysis and analyses of the predicted conformations of the esterases reveal little similarity to the serine proteases. Four of the esterase proteins share 27%-53% overall sequence similarity and evidence of a catalytic mechanism involving the same Arg-Asp-Ser or His-Asp-Ser charge relay. We propose that these four esterases, three of them cholinesterases, form part of a multigene family essentially separate from the serine proteases.