Structure, organization, and expression of the 16-kDa heat shock gene family of Caenorhabditis elegans

Exposure of the nematode Caenorhabditis elegans to a heat shock results in the induction of a number of genes not normally expressed in the animals under normal growth conditions. Among these are a family of genes encoding 16 kDa heat shock proteins (hsp16s). The major hsp16 genes have been cloned and characterized, and found to reside at two clusters in the C. elegans genome. One cluster contains two distinct genes, hsp16-1 and hsp16-48, arranged in divergent orientations separated by only 348 base pairs (bp). An identical pair, duplicated and inverted with respect to the first pair, is located 415 bp away. This cluster, located on chromosome V, therefore contains four genes as two identical pairs within less than 4 kilobases of DNA, and the pairs form the arms of a large inverted repeat. A second pair of genes, hsp16-2 and hsp16-41, constitutes a second hsp16 locus with an organization very similar to that of the hsp16-1/48 locus, except that it is not duplicated. Comparisons of the derived amino acid sequences show that hsp16-1 and hsp16-2 form a closely related pair, as do hsp16-41 and hsp16-48. These hsps show extensive sequence identity with the small hsps of Drosophila, as well as with mammalian alpha-crystallins. The coding region of each gene is interrupted by a single intron of approximately 50 bp, in a position homologous to that of the first intron in mouse alpha-crystallin gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

Locus encoding a family of small heat shock genes in Caenorhabditis elegans: two genes duplicated to form a 3.8-kilobase inverted repeat.

The genes coding for hsp 16-48, previously identified by cDNA cloning, and for another 16-kilodalton heat shock protein designated hsp16-1 were characterized by DNA sequencing. The two genes were arranged in a head-to-head orientation. Both the coding and flanking regions were located within a 1.9-kilobase module which was duplicated exactly to form a 3.8-kilobase inverted repeat structure. The inverted repeat structure ended in an unusual guanine-plus-cytosine-rich sequence 24 nucleotides in length. The identity of the two modules at the nucleotide sequence level implies that the duplication event may have occurred recently. Alternatively, gene conversion between the two modules could also maintain homology of the two gene pairs. The small heat shock genes of Caenorhabditis elegans contained TATA boxes and heat-inducible promoters, the latter agreeing closely with the Drosophila melanogaster consensus sequence described by Pelham (Cell 30:517-528, 1982). Unlike the homologous D. melanogaster genes, each of these C. elegans genes contained a short intron, the position of which has been conserved in a related murine alpha-crystallin gene. The intron separated variable and conserved regions within the amino acid sequences of the encoded heat shock polypeptides.     

Splicing of a C. elegans myosin pre-mRNA in a human nuclear extract.

Splicing of mammalian introns requires that the intron possess at least 80 nucleotides. This length requirement presumably reflects the constraints of accommodating multiple snRNPs simultaneously in the same intron. In the free-living nematode, C. elegans, introns typically are 45 to 55 nucleotides in length. In this report, we determine whether C. elegans introns can obviate the mammalian length requirement by virtue of their structure or sequence. We demonstrate that a 53 nucleotide intron from the unc-54 gene of C. elegans does not undergo splicing in a mammalian (HeLa) nuclear extract. However, insertion of 31 nucleotides of foreign, prokaryotic sequence into the same intron results in efficient splicing. The observed splicing proceeds by the same two-step mechanism observed with mammalian introns, and exploits the same 3' and 5' splice sites as are used in C. elegans. The branch point used lies in the inserted sequence. We conclude that C. elegans splicing components are either fewer in number or smaller than their mammalian counterparts.     

Alternative 5'' splice site selection induced by heat shock.

The mouse HSP47 gene consists of six exons separated by five introns. Three HSP47 cDNAs differing only in their 5' noncoding regions have been reported. One of these alternatively spliced mRNAs was detected only after heat shock, which caused an alternative 5' splice donor site selection. Other stress inducers, including an amino acid analog and sodium arsenite, had no effect on the alternative splicing. The alternatively spliced mRNA, which was 169 nucleotides longer in the 5' noncoding region compared to mRNA transcribed in non-heat shock conditions, was efficiently translated under heat shock conditions. This novel finding that alternative splicing is caused by artificial treatment like heat shock will provide a useful in vivo model for understanding the exon-intron recognition mechanism as well as heat shock-induced alterations in gene expression.     

Heat shock proteins affect RNA processing during the heat shock response of Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the splicing of mRNA precursors is disrupted by a severe heat shock. Mild heat treatments prior to severe heat shock protect splicing from disruption, as was previously reported for Drosophila melanogaster. In contrast to D. melanogaster, protein synthesis during the pretreatment is not required to protect splicing in yeast cells. However, protein synthesis is required for the rapid recovery of splicing once it has been disrupted by a sudden severe heat shock. Mutations in two classes of yeast hsp genes affect the pattern of RNA splicing during the heat shock response. First, certain hsp70 mutants, which overproduce other heat shock proteins at normal temperatures, show constitutive protection of splicing at high temperatures and do not require pretreatment. Second, in hsp104 mutants, the recovery of RNA splicing after a severe heat shock is delayed compared with wild-type cells. These results indicate a greater degree of specialization in the protective functions of hsps than has previously been suspected. Some of the proteins (e.g., members of the hsp70 and hsp82 gene families) help to maintain normal cellular processes at higher temperatures. The particular function of hsp104, at least in splicing, is to facilitate recovery of the process once it has been disrupted.