Identification of six chymotrypsin cDNAs from larval midguts of Helicoverpa zea and Agrotis ipsilon feeding on the soybean (Kunitz) trypsin inhibitor

Lepidopteran insects like Helicoverpa zea and Agrotis ipsilon produce STI-insensitive trypsins in the midgut following ingestion of dietary plant proteinase inhibitors like STI [Broadway, R. M., J. Insect Physiol. 43(9) (1997) 855-874]. In this paper, the effects of dietary STI on a related family of midgut serine proteinases, the chymotrypsins, were investigated. STI-insensitive midgut chymotrypsins were detected in larvae of H. zea and A. ipsilon feeding on diets containing 1% STI while STI-sensitive chymotrypsins were present in larvae feeding on diets containing 0% STI. These chymotrypsins were unaffected by TPCK, a diagnostic inhibitor of mammalian chymotrypsins but were fully inhibited by chymostatin. Four midgut cDNA libraries were constructed from larvae of each species fed either 0% STI or 1% STI diets. Six full-length cDNAs(1) encoding diverse preprochymotrypsins were isolated (three from H. zea and three from A. ipsilon) with certain sequence motifs that set them apart from their mammalian counterparts. Northern blots showed that some chymotrypsin mRNA were detected at higher levels while others were down-regulated when comparing insects reared on 0% STI and 1% STI diets. Southern hybridizations suggested that (like mammals) both species contained several chymotrypsin genes. A full-length chymotrypsin gene(1) from H. zea was sequenced for the first time and the presence of four introns was deduced. A first time comparison of 5' upstream regions(1) from three chymotrypsin genes and two trypsin genes of A. ipsilon indicated the presence of putative TATA boxes and regulatory elements. However a lack of consensus motifs in these upstream regions suggested the likelihood of multiple trans factors for regulation of genes encoding digestive proteinases and a complex response mechanism linked to ingestion of proteinase inhibitors.     

Translation of aberrant mRNAs lacking a termination codon or with a shortened 3'-UTR is repressed after initiation in yeast

A novel mRNA surveillance for mRNA lacking a termination codon (nonstop mRNA) has been proposed in which Ski7p is thought to recognize stalled ribosomes at the 3' end of mRNA. Here we report our analysis of translation and decay of nonstop mRNAs in Saccharomyces cerevisiae. Although the reduction of nonstop mRNAs was only 4.5-fold, a level that is sufficient for residual protein synthesis, translation products of nonstop mRNAs were hardly detectable. We show that nonstop mRNAs were associated with polysomes, but not with Pab1p. We also show that ribosomes translating nonstop mRNA formed stable and heavy polysome complexes with mRNA. These data suggest that ribosome stalling at the 3' end of nonstop mRNA may block further rounds of translation, hence repressing protein synthesis. Furthermore, it was found that the 5' --> 3' decay pathway was accelerated for nonstop mRNA decay in the absence of Ski7p. We also found that translation of aberrant mRNAs with a shortened 3'-UTR was repressed, suggesting that an improper spatial distance between the termination codon and the 3' end of mRNA results in translation repression.     

SsrA-mediated trans-translation plays a role in mRNA quality control by facilitating degradation of truncated mRNAs

An important unsolved question regarding the bacterial SsrA system is the fate of target mRNAs replaced by SsrA RNA during trans-translation. The aim of the present study is to address the potential role of SsrA system in mRNA quality control, focusing on truncated mRNAs that are expected to arise from 3'-to-5' exonucleolytic attack. We found that significant amounts of truncated mRNAs and polypeptides were produced from genes lacking a rho-independent terminator in SsrA-deficient cells. These truncated mRNAs, hence truncated polypeptides, were no longer observed in the presence of SsrA RNA. The data indicate that the SsrA system facilitates degradation of "nonstop" mRNAs by presumably removing the stalled ribosomes. Furthermore, analysis of affinity-purified proteins indicated that truncated polypeptides could be produced even from a gene with an intact rho-independent terminator, although less efficiently, implying that C-terminally truncated proteins and 3'-truncated mRNA may be produced from virtually all protein-coding genes. We conclude that the SsrA system not only promotes the degradation of incomplete polypeptides but also minimizes the synthesis of incomplete polypeptides by facilitating the degradation of truncated mRNAs that are produced in cells.     

Dom34:hbs1 plays a general role in quality-control systems by dissociation of a stalled ribosome at the 3' end of aberrant mRNA

Translation arrest leads to an endonucleolytic cleavage of mRNA that is termed no-go decay (NGD). It has been reported that the Dom34:Hbs1 complex stimulates this endonucleolytic cleavage of mRNA induced by translation arrest in vivo and dissociates subunits of a stalled ribosome in vitro. Here we report that Dom34:Hbs1 dissociates the subunits of a ribosome that is stalled at the 3' end of mRNA in vivo, and has a crucial role in both NGD and nonstop decay. Dom34:Hbs1-mediated dissociation of a ribosome that is stalled at the 3' end of mRNA is required for degradation of a 5'-NGD intermediate. Dom34:Hbs1 facilitates the decay of nonstop mRNAs from the 3' end by exosomes and is required for the complete degradation of nonstop mRNA decay intermediates. We propose that Dom34:Hbs1 stimulates degradation of the 5'-NGD intermediate and of nonstop mRNA by dissociating the ribosome that is stalled at the 3' end of the mRNA.     

Molecular analysis of CYP321A1, a novel cytochrome P450 involved in metabolism of plant allelochemicals (furanocoumarins) and insecticides (cypermethrin) in Helicoverpa zea

Cytochrome P450 monooxygenases play a significant role in the detoxification of hostplant allelochemicals and synthetic insecticides in Lepidoptera. In the corn earworm Helicoverpa zea, a noctuid of considerable economic importance, metabolisms of xanthotoxin, a toxic furanocoumarin, and alpha-cypermethrin, an insecticide, are mediated by at least one P450 with a catalytic site capable of accepting both substrates. To further the characterization of P450s in this species, we have cloned three full-length cDNAs encoding two CYP4M subfamily members and a novel CYP321A subfamily member. RNA analyses have demonstrated that the CYP321A1 gene is highly induced (51-fold) in larval midguts in response to xanthotoxin but not cypermethrin. Both CYP4M genes are expressed at negligible levels that are not increased by xanthotoxin or cypermethrin. Baculovirus-mediated expression of the full-length CYP321A1 cDNA has demonstrated that the CYP321A1 protein metabolizes xanthotoxin and angelicin, like the CYP6B1 protein in the furanocoumarin specialist Papilio polyxenes, and alpha-cypermethrin, like the CYP6B8 protein previously characterized in H. zea. In contrast, the CYP4M7 protein does not metabolize xanthotoxin at any detectable level. We conclude that at least two xanthotoxin-inducible P450s from highly divergent subfamilies (CYP6B and CYP321A) contribute to the resistance of H. zea larvae to toxic furanocoumarins and insecticides. Genomic PCR analysis indicates that the CYP321A1 gene has evolved independently from the CYP6B genes known to be present in this insect.     

New transposable elements identified as insertions in rice transposon Tnr1

Tnr1 (235 bp long) is a transposable element in rice. Polymerase chain reactions (PCRs) done with a primer(s) that hybridizes to terminal inverted repeat sequences (TIRs) of Tnr1 detected new Tnr1 members with one or two insertions in rice genomes. Six identified insertion sequences (Tnr4, Tnr5, Tnr11, Tnr12, Tnr13 and RIRE9) did not have extensive homology to known transposable elements, rather they had structural features characteristic of transposable elements. Tnr4 (1767 bp long) had imperfect 64-bp TIRs and appeared to generate duplication of a 9-bp sequence at the target site. However, the TIR sequences were not homologous to those of known transposable elements, indicative that Tnr4 is a new transposable element. Tnr5 (209 bp long) had imperfect 46-bp TIRs and appeared to generate duplication of sequence TTA like that of some elements of the Tourist family. Tnr11 (811 bp long) had 73-bp TIRs with significant homology to those of Tnr1 and Stowaway and appeared to generate duplication of sequence TA, indicative that Tnr11 is a transposable element of the Tnr1/Stowaway family. Tnr12 (2426 bp long) carried perfect 9-bp TIRs, which began with 5'-CACTA- -3' from both ends and appeared to generate duplication of a 3-bp target sequence, indicative that Tnr12 is a transposable element of the En/Spm family. Tnr13 (347 bp long) had 31-bp TIRs and appeared to generate duplication of an 8-bp target sequence. Two sequences, one the transposon-like element Crackle, had partial homology in the Tnr13 ends. All five insertions appear to be defective elements derived from autonomous ones encoding the transposase gene. All had characteristic tandem repeat sequences which may be recognized by transposase. The sixth insertion sequence, named RIRE9 (3852 bp long), which begins with 5'-TG- -3' and ends with 5'- -CA-3', appeared to generate duplication of a 5-bp target sequence. These and other structural features indicate that this insertion is a solo LTR (long terminal repeat) of a retrotransposon. The transposable elements described above could be identified as insertions into Tnr1, which do not deleteriously affect the growth of rice cells.     

DNA sequence requirements for hobo transposable element transposition in Drosophila melanogaster

We have conducted a structure and functional analysis of the hobo transposable element of Drosophila melanogaster. A minimum of 141 bp of the left (L) end and 65 bp of the right (R) end of the hobo were shown to contain sequences sufficient for transposition. Both ends of hobo contain multiple copies of the motifs GGGTG and GTGGC and we show that the frequency of hobo transposition increases as a function of the copy number of these motifs. The R end of hobo contains a unique 12 bp internal inverted repeat that is identical to the hobo terminal inverted repeats. We show that this internal inverted repeat suppresses transposition activity in a hobo element containing an intact L end and only 475 bp of the R end. In addition to establishing cis-sequences requirements for transposition, we analyzed trans-sequence effects of the hobo transposase. We show a hobo transposase lacking the first 49 amino acids catalyzed hobo transposition at a higher frequency than the full-length transposase suggesting that, similar to the related Ac transposase, residues at the amino end of the transposase reduce transposition. Finally, we compared target site sequences of hobo with those of the related Hermes element and found both transposons have strong preferences for the same insertion sites.