Posttranslational modifications, including acetylation and deacetylation of histones and other proteins, modulate hormone action. In Tribolium castaneum TcA cells, Trichostatin A, a histone deacetylase (HDAC) inhibitor, mimics juvenile hormone (JH) in inducing JH response genes (e.g., Kr-h1), suggesting that HDACs may be involved in JH action. To test this hypothesis, we identified genes coding for HDACs in T. castaneum and studied their function. Knockdown of 12 HDAC genes showed variable phenotypes; the most severe phenotype was detected in insects injected with double-stranded RNA targeting HDAC1 (dsHDAC1). The dsHDAC1-injected insects showed arrested growth and development and eventually died. Application of JH analogs hydroprene to T. castaneum larvae and JH III to TcA cells suppressed HDAC1 expression. Sequencing of RNA isolated from control and dsHDAC1-injected larvae identified 1,720 differentially expressed genes, of which 1,664 were up-regulated in dsHDAC1-treated insects. The acetylation levels of core histones were increased in TcA cells exposed to dsHDAC1 or JH III. ChIP assays performed using histone H2BK5ac antibodies showed an increase in acetylation in the Kr-h1 promoter region of cells exposed to JH III or dsHDAC1. Overexpression or knockdown of HDAC1, SIN3, or both resulted in a decrease or increase in Kr-h1 mRNA levels and its promoter activity, respectively. Overexpression of the JH receptor Methoprene tolerant (Met) was unable to induce Kr-h1 in the presence of HDAC1 or SIN3. These data suggest that epigenetic modifications influence JH action by modulating acetylation levels of histones and by affecting the recruitment of proteins involved in the regulation of JH response genes.
Ribonucleic acid interference (RNAi) is a sequence-specific gene silencing mechanism induced by double-stranded RNA (dsRNA). Recently, RNAi has gained popularity as a reverse genetics tool owing to its tremendous potential in insect pest management, which includes Helicoverpa armigera. However, its efficiency is mainly governed by dsRNA concentration, frequency of application, target gene, etc. Therefore, to obtain a robust RNAi response in H. armigera, we evaluated various concentrations of dsRNA and its frequency of applications delivered through diet in silencing a midgut gene, chymotrypsin and a non-midgut gene, juvenile hormone acid methyl transferase (jhamt) of H. armigera. The extent of target gene silencing was determined by employing reverse transcription quantitative real-time polymerase chain reaction (RT-qPCR). Our study revealed four significant findings: (i) single application of dsRNA elicited a delayed and transient silencing, while multiple applications resulted in early and persistent silencing of the above genes; (ii) silencing of the non-midgut gene (jhamt) through diet delivered dsRNA revealed prevalence of systemic silencing probably due to communication of silencing signals in this pest; (iii) the extent of silencing of chymotrypsin was positively correlated with dsRNA concentration and was negatively correlated with jhamt; (iv) interestingly, over-expression (15–18 folds) of an upstream gene, farnesyl diphosphate synthase (fpps), in juvenile hormone (JH) biosynthetic pathway at higher concentrations of jhamt dsRNA was the plausible reason for lesser silencing of jhamt. This study provides an insight into RNAi response of target genes, which is essential for RNAi design and implementation as a pest management strategy.
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