Characterization and expression patterns of <Emphasis Type="Italic">let-7</Emphasis> microRNA in the silkworm (<Emphasis Type="Italic">Bombyx mori</Emphasis>)

Background  

lin-4 and let-7, the two founding members of heterochronic microRNA genes, are firstly confirmed in Caenorhabditis elegans to control the proper timing of developmental programs in a heterochronic pathway. let-7 has been thought to trigger the onset of adulthood across animal phyla. Ecdysone and Broad-Complex are required for the temporal expression of let-7 in Drosophila melanogaster. For a better understanding of the conservation and functions of let-7, we seek to explore how it is expressed in the silkworm (Bombyx mori).     

The sterol modifying enzyme LET-767 is essential for growth,reproduction and development in<Emphasis Type="Italic"> Caenorhabditis elegans</Emphasis>

The let-767 gene encodes a protein that is similar to mammalian steroid enzymes that are responsible for the reduction of 17-beta hydroxysteroid hormones. Caenorhabditis elegans is incapable of the de novo synthesis of cholesterol. Therefore, this free-living nematode must extract cholesterol from its environment and modify it to form steroid hormones that are necessary for its survival. C. elegans is unable to survive in the absence of supplemental cholesterol, and is therefore sensitive to cholesterol limitation. We show that a mutation in let-767 results in hypersensitivity to cholesterol limitation, supporting the hypothesis that LET-767 acts on a sterol derivative. Furthermore, let-767 mutants exhibit defects in embryogenesis, female reproduction and molting. Although ecdysone is the major molting hormone in insects, there is as yet no evidence for ecdysone synthesis in C. elegans, suggesting that a different hormone is required for molting in C. elegans. Our results suggest that LET-767 modifies a sterol hormone that is required both for embryogenesis and for later stages of development.Communicated by C. P. Hollenberg     

Construction of a Promoter-probe Vector for <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis>: the Identification of <Emphasis Type="Italic">cis</Emphasis>-acting Elements of the <Emphasis Type="Italic">chiA</Emphasis> Locus

The expression and application of Bacillus thuringiensis (Bt) chitinase genes have been extensively investigated. However, little information is available regarding the regulation of chitinase gene expression in Bt. In this study, a shuttle promoter-probe vector was constructed incorporating the thermostable β-galactosidase gene bgaB of B. stearothermophilus as the reporter for the study of Bt promoters. Using this plasmid, the activity of the chiA gene promoter in Bt was investigated. Deletion analysis of the putative chiA promoter region revealed that the sequence located ~75 bp DNA from positions −116 to −42, with respect to the translation start site, is the core promoter of chiA gene. Furthermore, a site for chitin induction was identified near position −36. This site for negative regulation was indicated downstream of the RNA polymerase binding sites of the promoter of chiA. The expression of chiA started in cell grown for about 6 h and reached the maximum after 60 h of incubation. Induction of chiA expression by chitin was demonstrated by an increase in β-galactosidase activity of ~2.5-fold.     

ANK repeat-domain of SHN-1 Is indispensable for <Emphasis Type="Italic">in vivo</Emphasis> SHN-1 function in <Emphasis Type="Italic">C. elegans</Emphasis>

Shank protein is one of the postsynaptic density (PSD) proteins which play a major role in proper localization of proteins at membranes. The shn-1, a homolog of Shank in Caenorhabditis elegans, is expressed in neurons, pharynx, intestine, vulva and sperm. We have previously reported a possible genetic interaction between Shank and IP₃ receptor by examining shn-1 RNAi in IP₃ receptor (itr-1) mutant background. In order to show the direct interaction of Shank and IP₃ receptor as well as to show the direct in vivo function of Shank, we have characterized two different mutant alleles of shn-1, which have different deletions in the different domains. shn-1 mutants were observed for Ca²⁺-related behavioral defects with itr-1 mutants. We found that only shn-1 mutant defective in ANK repeat-domain showed significant defects in defecation, pharyngeal pumping and fertility. In addition, we found that shn-1 regulates defecation, pharyngeal pumping and probably male fertility with itr-1. Thus, we suggest that Shank ANK repeat-domain along with PDZ may play a crucial role in regulating Ca²⁺-signaling with IP₃ receptor.     

Functional analysis of the <Emphasis Type="Italic">egl3</Emphasis> upstream region in filamentous fungus <Emphasis Type="Italic">Trichoderma reesei</Emphasis>

In the filamentous fungus Trichoderma reesei, endoglucanase III (EGIII) is coordinately expressed with other cellulases during growth on cellulose, its derivatives, and L-sorbose. To elucidate EGIII induction mechanism, we cloned and sequenced the upstream region of egl3 encoding EGIII. Two GGCTAA motifs, a putative binding site for ACEII and xylanase regulator Xyr1, were found on the template strand of the egl3 upstream region. Deletion analysis of the egl3 upstream region using the beta-glucuronidase (GUS) reporter system revealed that removal of regions containing the GGCTAA motifs and the region between −1,045 and −1,002 bp containing GGCTAT motif severely affected GUS inducibility. Furthermore, mutation of the two GGCTAA motifs and the GGCTAT motif of this region led to a significant decrease in GUS activity. These data indicate that both GGCTAA and GGCTAT are key motifs for egl3 expression, and that egl3 induction may also be controlled by Xyr1. This hypothesis was supported by in vitro electrophoretic mobility shift assay, in which heterologously expressed Xyr1 specifically bound not only GGCTAA but also GGCTAT motif.     

Molecular cloning and characterization of the promoter for the multiple stress-inducible gene <Emphasis Type="Italic">BjCHI1</Emphasis> from <Emphasis Type="Italic">Brassica juncea</Emphasis>

We have previously isolated a Brassica juncea cDNA encoding a novel chitinase BjCHI1 with two chitin-binding domains (Zhao and Chye in Plant Mol Biol 40:1009–1018, 1999). The expression of BjCHI1 was highly inducible by methyl jasmonate (MeJA) treatment, wounding, caterpillar feeding, and pathogenic fungal infection. These observations suggest that the promoter of BjCHI1 gene might contain specific cis-acting elements for stress responses. Here, we report the cloning and characterization of the BjCHI1 promoter. A 1,098 bp BjCHI1 genomic DNA fragment upstream of the ATG start codon was isolated by PCR walking and various constructs were made by fusing the BjCHI1 promoter or its derivatives to β-glucuronidase reporter gene. The transgenic Arabidopsis plants showed that the BjCHI1 promoter responded to wounding and MeJA treatment, and to treatments with either NaCl or polyethyleneglycol (PEG 6000), indicating that the BjCHI1 promoter responses to both biotic and abiotic stresses. A transient gene expression system of Nicotiana benthamiana leaves was adopted for promoter deletion analysis, and the results showed that a 76 bp region from −695 to −620 in the BjCHI1 promoter was necessary for MeJA-responsive expression. Furthermore, removal of a conserved T/G-box (AACGTG) at −353 to −348 of the promoter greatly reduced the induction by MeJA. This is the first T/G-box element identified in a chitinase gene promoter. Gain-of-function analysis demonstrated that the cis-acting element present in the 76 bp region requires coupling with the T/G-box to confer full magnitude of BjCHI1 induction by MeJA.     

Gene Expression,Intron Density,and Splice Site Strength in <Emphasis Type="Italic">Drosophila</Emphasis> and <Emphasis Type="Italic">Caenorhabditis</Emphasis>

In this paper we investigate the relationships among intron density (number of introns per kilobase of coding sequence), gene expression level, and strength of splicing signals in two species: Drosophila melanogaster and Caenorhabditis elegans. We report a negative correlation between intron density and gene expression levels, opposite to the effect previously observed in human. An increase in splice site strength has been observed in long introns in D. melanogaster. We show this is also true of C. elegans. We also examine the relationship between intron density and splice site strength. There is an increase in splice site strength as the intron structure becomes less dense. This could suggest that introns are not recognized in isolation but could function in a cooperative manner to ensure proper splicing. This effect remains if we control for the effects of alternative splicing on splice site strength. Reviewing Editor: Dr. Nicolas Galtier     

Manipulating the <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis> genome using <Emphasis Type="Italic">mariner</Emphasis> transposons

Tc1, one of the founding members of the Tc1/mariner transposon superfamily, was identified in the nematode Caenorhabditis elegans more than 25 years ago. Over the years, Tc1 and other endogenous mariner transposons became valuable tools for mutagenesis and targeted gene inactivation in C. elegans. However, transposition is naturally repressed in the C. elegans germline by an RNAi-like mechanism, necessitating the use of mutant strains in which transposition was globally derepressed, which causes drawbacks such as uncontrolled proliferation of the transposons in the genome and accumulation of background mutations. The more recent mobilization of the Drosophila mariner transposon Mos1 in the C. elegans germline circumvented the problems inherent to endogenous transposons. Mos1 transposition strictly depends on the expression of the Mos transposase, which can be controlled in the germline using inducible promoters. First, Mos1 can be used for insertional mutagenesis. The mobilization of Mos1 copies present on an extrachromosomal array results in the generation of a small number of Mos1 genomic insertions that can be rapidly cloned by inverse PCR. Second, Mos1 insertions can be used for genome engineering. Triggering the excision of a genomic Mos1 insertion causes a chromosomal break, which can be repaired by transgene-instructed gene conversion. This process is used to introduce specific changes in a given gene, such as point mutations, deletions or insertions of a tag, and to create single-copy transgenes.