Cuticular Protein Gene Expression Research Articles

Insect cuticular protein; gene expression, genomic structure, transcriptional regulation, speculated cuticular structure, clarified through the genomic analysis of Bombyx mori.

JH and ecdysone signaling regulateinsect metamorphosis through the master transcription factors, Krüppel homolog 1 (kr-h1), Broad-Complex (BR-C), and E93. Ecdysone signaling activates successively expressed ecdysone responsive transcription factors (ERTFs), and the interaction between ERTFs determines the expression profiles of ERTFs themselves. Through the construction of expressed sequence tag(EST) database of Bombyx mori from many tissues, the existence of a large number of cuticular protein (CP) genes was identified in wing disc cDNA library of the 3 days after the start of wandering (W3). From the genomic analysis, 12 types of CPclusters of CP genes were identified. DNA sequences of CP genes revealed the duplication of CP genes, which suggests to reflect the insect evolution. These CP genes responded to ecdysone and ecdysone pulse; therefore, CP genes were applied for the analysis of transcriptional regulation by ERTF. The binding sites of ERTF have been reported to exist upstream of CP genes in several insects, and the activation of CP genes occurred by the binding of ERTFs. Through the analysis, the followingwere speculated; the successive appearance of ERTFs and the activation of target genesresulted in the successively produced CPs and cuticular layer. The sequence of the ERTF and CP gene expression was the same at larval to pupal and pupal to adult transformation. The involvement of several ERTFs in one CP gene expression was also clarified; BmorCPG12 belongs to group showing expression peak at W3 and was regulated by two ERTFs; BHR3 and ßFTZ-F1, BmorCPH2 belongs to group showing expression peak at P0 and was regulated by two ERTFs; ßFTZ-F1 and E74A. The involvement of BHR39 as a negative regulator of CP gene expression was found. Larval, pupal, and adult cuticular layers were supposed to be constructed by the combination of different and similar types of CPs, through the expressed timing of CP genes.

CRISPR-Cas9-Mediated Mutation of Methyltransferase METTL4 Results in Embryonic Defects in Silkworm Bombyx mori

DNA N6-methyladenine (6mA) has recently been found to play regulatory roles in gene expression that links to various biological processes in eukaryotic species. The functional identification of 6mA methyltransferase will be important for understanding the underlying molecular mechanism of epigenetic 6mA methylation. It has been reported that the methyltransferase METTL4 can catalyze the methylation of 6mA; however, the function of METTL4 remains largely unknown. In this study, we aim to investigate the role of the Bombyx mori homolog METTL4 (BmMETTL4) in silkworm, a lepidopteran model insect. By using CRISPR-Cas9 system, we somatically mutated BmMETTL4 in silkworm individuates and found that disruption of BmMETTL4 caused the developmental defect of late silkworm embryo and subsequent lethality. We performed RNA-Seq and identified that there were 3192 differentially expressed genes in BmMETTL4 mutant including 1743 up-regulated and 1449 down-regulated. Gene Ontology and Kyoto Encyclopedia of Genes and Genomes analyses showed that genes involved in molecular structure, chitin binding, and serine hydrolase activity were significantly affected by BmMETTL4 mutation. We further found that the expression of cuticular protein genes and collagens were clearly decreased while collagenases were highly increased, which had great contributions to the abnormal embryo and decreased hatchability of silkworm. Taken together, these results demonstrated a critical role of 6mA methyltransferase BmMETTL4 in regulating embryonic development of silkworm.

Cuticular protein genes showing peaks at different stages are probably regulated by different ecdysone responsive transcription factors during larval-pupal transformation.

We aimed to explain the reason and function of the successive expression of ecdysone-responsive transcription factors (ERTFs) and related cuticular protein (CP) genes during transformation from larva to pupa. The regulation of the expression of CP genes by ERTFs was examined by in vitro wing disc culture and reporter assay using a gene gun transduction system. Two CP genes that showed expression peaks at different stages-BmorCPG12 at W3L and BmorCPH2 at P0 stage-were selected and examined. Reporter constructs conveying putative BHR3, ßFTZ-F1, BHR39, and E74A binding sites of BmorCPG12 and BmorCPH2 showed promoter activity when introduced into wing discs. In the present study, we showed the functioning of the putative BHR3 and E74A binding sites, together with putative ßFTZ-F1 binding sites, on the activation of CP genes, and different ERTF binding sites functioned in one CP gene. From these, we conclude that BHR3, ßFTZ-F1, and E74A that are successively expressed bring about the successive expression of CP genes, resulting in insect metamorphosis. In addition to this, reporter constructs conveying putative BHR39 binding sites of BmorCPG12 and BmorCPH2 showed negative regulation.

Transcriptional regulation of cuticular genes during insect metamorphosis.

In some adult holometabolous insects, specific epithelial tissues form imaginal discs, small sac-like clusters of cells that form in the larval body. During metamorphosis, in response to hormones, the discs undergo dramatic changes including cell proliferation and differentiation. In Bombyx mori insects, the cuticular protein (CP) genes, which are expressed at prepupal stage in the wing discs, are divided into six groups according to their developmental expression profile and responsiveness to steroid hormones. In this article, we discuss the expression of CP genes in the wing disc, and examine the molecular mechanisms by which metamorphosis and cell transformations are regulated by hormones in insects.

Expression profiles of cuticular protein genes in wing tissues during pupal to adult stages and the deduced adult cuticular structure of Bombyx mori

We aimed to clarify the regulation of cuticular protein (CP) gene expression and the resulting insect cuticular layers by comparing the expression pattern of CP genes and related ecdysone-responsive transcription factor (ERTF) genes, the coding amino acid sequences of CP genes, and histological observation. The expression of CP and ERTF genes during pupal and adult stages was examined via qPCR. The number of CP genes expressed during pupal and adult stages decreased as compared to that during prepupal to pupation stages, particularly in CPRs. The peaks of transcripts were observed at P5, P6, P9, A0, and A1. The order of the ERTF and CP genes expression resembled that at prepupal and pupation stages, suggesting the relatedness of ERTFs with the same CP genes at both stages. Moreover, the order of expression of CP genes resembled that in prepupal to pupation stages, by which we presumed the spaces of CPs in the epicuticle, outer-exocuticle, inner-exocuticle, endocuticle layer.

Identification and expression of cuticular protein genes based on Locusta migratoria transcriptome

Many types of cuticular proteins are found in a single insect species, and their number and features are very diversified among insects. The cuticle matrix consists of many different proteins that confer the physical properties of the exoskeleton. However, the number and properties of cuticle proteins in Locusta migratoria remain unclear. In the present study, Illumina sequencing and de novo assembly were combined to characterize the transcriptome of L. migratoria. Eighty-one cuticular protein genes were identified and divided into five groups: the CPR family (51), Tweedle (2), CPF/CPFLs (9), CPAP family (9), and other genes (10). Based on the expression patterns in different tissues and stages, most of the genes as a test were distributed in the integument, pronotum and wings, and expressed in selected stages with different patterns. The results showed no obvious correlation between the expression patterns and the conservative motifs. Additionally, each cluster displayed a different expression pattern that may possess a different function in the cuticle. Furthermore, the complexity of the large variety of genes displayed differential expression during the molting cycle may be associated with cuticle formation and may provide insights into the gene networks related to cuticle formation.

Characterization of the transcriptomes and cuticular protein gene expression of alate adult, brachypterous neotenic and adultoid reproductives of Reticulitermes labralis.

The separation of primary reproductive and secondary reproductive roles based on the differentiation of alate adults and neotenic reproductives is the most prominent characteristic of termites. To clarify the mechanism underlying this differentiation, we sequenced the transcriptomes of alate adults (ARs), brachypterous neotenics (BNs) and adultoid reproductives (ANs) from the last instar nymphs of Reticulitermes labralis. A total of 404,152,188 clean sequencing reads was obtained and 61,953 unigenes were assembled. Of the 54 identified cuticular protein (CP) genes of the reproductives, 22 were classified into the CPR family and 7 were classified into the CPG family. qRT-PCR analyses of the 6 CP genes revealed that the CP genes involved in exocuticle sclerotization were highly expressed in the ARs and RR-1 involved in soft endocuticle was highly expressed in the ARs and ANs. These results suggest that the alate adults might increase cuticular component deposition to adapt to new or changing environments and that the development of reproductive individuals into primary or secondary reproductives is controlled by the expression of cuticular protein genes involved in the hardening of the exocuticle. In addition, the AN caste is a transitional type between the BN and AR castes in the process of evolution.

Cuticular protein and transcription factor genes expressed during prepupal-pupal transition and by ecdysone pulse treatment in wing discs of Bombyx mori.

We aimed to understand the underlying mechanism that regulates successively expressed cuticular protein (CP) genes around pupation in Bombyx mori. Quantitative PCR was conducted to clarify the expression profile of CP genes and ecdysone-responsive transcription factor (ERTF) genes around pupation. Ecdysone pulse treatment was also conducted to compare the developmental profiles and the ecdysone induction of the CP and ERTF genes. Fifty-two CP genes (RR-1 13, RR-2 18, CPG 8, CPT 3, CPFL 2, CPH 8) in wing discs of B. mori were examined. Different expression profiles were found, which suggests the existence of a mechanism that regulates CP genes. We divided the genes into five groups according to their peak stages of expression. RR-2 genes were expressed until the day of pupation and RR-1 genes were expressed before and after pupation and for longer than RR-2 genes; this suggests different construction of exo- and endocuticular layers. CPG, CPT, CPFL and CPH genes were expressed before and after pupation, which implies their involvement in both cuticular layers. Expression profiles of ERTFs corresponded with previous reports. Ecdysone pulse treatment showed that the induction of CP and ERTF genes in vitro reflected developmental expression, from which we speculated that ERTFs regulate CP gene expression around pupation.

Ecdysone-responsive transcriptional regulation determines the temporal expression of cuticular protein genes in wing discs of Bombyx mori

The present study was conducted to clarify the regulatory mechanism of cuticular protein genes of Bombyx mori expressed in wing discs in the prepupal stage. BHR3, BHR4, E74A, and ßFTZ-F1 were successively expressed in wing discs at the pre-pupal stage. BHR3 showed different ecdysone responsiveness from other ecdysone-responsive transcription factors (ERTFs) and was induced by ecdysone addition but showed decrease by ecdysone removal after treatment (ecdysone pulse). BHR4 and E74A were induced by the ecdysone addition and by the ecdysone pulse. ßFTZ-F1 was not induced by the ecdysone addition but was induced by the ecdysone pulse. Thus, ERTFs showed different hormone responsiveness, resulting in the different expression timing. We selected cuticular protein genes that showed the same expression stage with each transcription factor and examined their ecdysone responsiveness. The developmental expression and ecdysone responsiveness of BmorCPH5, BmorCPR34, BmorCPR23, and BmorCPR99 resembled those of BHR3, BHR4, E74A, and ßFTZ-F1, respectively. The results of the transient reporter assay strongly suggested the regulation of each cuticular protein promoter by ERTF. These ERTFs regulated different cuticular protein genes and determined their expression timing and probably the nature of the cuticle layer of insects.

Expression of cuticular protein genes, BmorCPG11 and BMWCP5 is differently regulated at the pre-pupal stage in wing discs of Bombyx mori

Through BLAST search of the genomic database of Bombyx mori, we found a clone, BmorCPG11, which has only putative BR-C binding sites in the 2 kb upstream region. Both BmorCPG11 and BR-Z2 were expressed in the cephalic region of the epidermis, differently from BR-Z1 and BR-Z4. BR-Z2 transcripts increased by the addition of 20-hydroxyl-ecdysone (20E), which was slightly inhibited by cycloheximide. BmorCPG11 expression was also induced by the addition of 20E, which was inhibited by cycloheximide. Both BmorCPG11 and BR-Z2 were induced by the 20E pulse treatment, but they were inhibited by the addition of cycloheximide. Both genes showed similar expression pattern in wing discs during the developmental stage and in vitro ecdysone responsiveness, and both showed relatedness. The result of a reporter assay demonstrated the strong relatedness of BmorCPG11 and BR-Z2. The expression profiles of BmorCPG11 and BR-Z2 are different from those of BMWCP5 and βFTZ-F1. The present findings showed different regulation of cuticular protein genes by ecdysone-responsive transcription factors at the pre-pupal stage of wing discs of B. mori.