Juvenile hormone (JH) prevents ecdysone-induced metamorphosis in insects. However, our knowledge of the molecular mechanisms of JH action is still fragmented. Krüppel homolog 1 (Kr-h1) is a JH-inducible transcription factor in Drosophila melanogaster (Minakuchi, C., Zhou, X., Riddiford, L.M., 2008b. Krüppel homolog 1 (Kr-h1) mediates juvenile hormone action during metamorphosis of Drosophila melanogaster. Mech. Dev. 125, 91-105). Analysis of expression of the homologous gene (TcKr-h1) in the beetle Tribolium castaneum showed that its transcript was continuously present in the larval stage but absent in the pupal stage. Artificial suppression of JH biosynthesis in the larval stage caused a precocious larval-pupal transition and a down-regulation of TcKr-h1 mRNA. RNAi-mediated knockdown of TcKr-h1 in the larval stage induced a precocious larval-pupal transition. In the early pupal stage, treatment with an exogenous JH mimic (JHM) caused formation of a second pupa, and a rapid and large induction of TcKr-h1 transcription. JHM-induced formation of a second pupa was counteracted by the knockdown of TcKr-h1. RNAi experiments in combination with JHM treatment demonstrated that in the larval stage TcKr-h1 works downstream of the putative JH receptor Methoprene-tolerant (TcMet), and in the pupal stage it works downstream of TcMet and upstream of the pupal specifier broad (Tcbr). Therefore, TcKr-h1 is an early JH-response gene that mediates JH action linking TcMet and Tcbr.
The Krüppel homolog 1 gene (Kr-h1) has been proposed to play a key role in the repression of insect metamorphosis. Kr-h1 is assumed to be induced by juvenile hormone (JH) via a JH receptor, methoprene-tolerant (Met), but the mechanism of induction is unclear. To elucidate the molecular mechanism of Kr-h1 induction, we first cloned cDNAs encoding Kr-h1 (BmKr-h1) and Met (BmMet1 and BmMet2) homologs from Bombyx mori. In a B. mori cell line, BmKrh1 was rapidly induced by subnanomolar levels of natural JHs. Reporter assays identified a JH response element (kJHRE), comprising 141 nucleotides, located ∼2 kb upstream from the BmKr-h1 transcription start site. The core region of kJHRE (GGCCTCCACGTG) contains a canonical E-box sequence to which Met, a basic helix-loophelix Per-ARNT-Sim (bHLH-PAS) transcription factor, is likely to bind. In mammalian HEK293 cells, which lack an intrinsic JH receptor, ectopic expression of BmMet2 fused with Gal4DBD induced JHdependent activity of an upstream activation sequence reporter. Meanwhile, the kJHRE reporter was activated JH-dependently in HEK293 cells only when cotransfected with BmMet2 and BmSRC, another bHLH-PAS family member, suggesting that BmMet2 and BmSRC jointly interact with kJHRE. We also found that the interaction between BmMet2 and BmSRC is dependent on JH. Therefore, we propose the following hypothesis for the mechanism of JHmediated induction of BmKr-h1: BmMet2 accepts JH as a ligand, JH-liganded BmMet2 interacts with BmSRC, and the JH/BmMet2/ BmSRC complex activates BmKr-h1 by interacting with kJHRE. development | insecticide | steroid receptor coactivator
Juvenile hormone (JH) given at pupariation inhibits bristle formation and causes pupal cuticle formation in the abdomen of Drosophila melanogaster due to its prolongation of expression of the transcription factor Broad (BR). In a microarray analysis of JH-induced gene expression in abdominal integument, we found that Krüppel homolog 1 (Kr-h1) was up-regulated during most of adult development. Quantitative real-time PCR analyses showed that Kr-h1 up-regulation began at 10h after puparium formation (APF), and Kr-h1 up-regulation occurred in imaginal epidermal cells, persisting larval muscles, and larval oenocytes. Ectopic expression of Kr-h1 in abdominal epidermis using T155-Gal4 to drive UAS-Kr-h1 resulted in missing or short bristles in the dorsal midline. This phenotype was similar to that seen after a low dose of JH or after misexpression of br between 21 and 30 h APF. Ectopic expression of Kr-h1 prolonged the expression of BR protein in the pleura and the dorsal tergite. No Kr-h1 was seen after misexpression of br. Thus, Kr-h1 mediates some of the JH signaling in the adult abdominal epidermis and is upstream of br in this pathway. We also show for the first time that the JH-mediated maintenance of br expression in this epidermis is patterned and that JH delays the fusion of the imaginal cells and the disappearance of Dpp in the dorsal midline.
Insect juvenile hormone (JH) is a multifunctional hormone that controls a variety of physiological events, e.g. growth and development, reproduction, diapause and caste determination in social insects [1]. The most prominent role of JH is the control of insect metamorphosis, which has been studied extensively in many species [2]. In holometabolous insects, for example, larvae do not initiate larval-pupal metamorphosis until JH in the hemolymph declines at the end of the larval stage. If JH in the hemolymph is precociously eliminated by surgical removal of the corpora allata (CA), the specialized endocrine organs that secrete JH into the hemolymph, precocious metamorphic change occurs. In contrast, application of a JH mimic (JHM) at the onset of larval-pupal metamorphosis prevents metamorphosis and causes an extra larval moult in Juvenile hormone controls the timing of insect metamorphosis. As a final step of juvenile hormone biosynthesis, juvenile hormone acid O-methyltransferase (JHAMT) transfers the methyl group from S-adenosyl-l-methionine to the carboxyl group of farnesoic acid and juvenile hormone acid. The developmental expression profiles of JHAMT mRNA in the silkworm Bombyx mori and the fruitfly Drosophila melanogaster suggest that the suppression of JHAMT transcription is critical for the induction of larvalpupal metamorphosis, but genetic evidence for JHAMT function in vivo is missing. In this study, we identified three methyltransferase genes in the red flour beetle Tribolium castaneum (TcMT1, TcMT2 and TcMT3) that are homologous to JHAMT of Bombyx and Drosophila. Of these three methyltransferase genes, TcMT3 mRNA was present continuously from the embryonic stage to the final larval instar, became undetectable before pupation, and increased again in the adult stage. TcMT3 mRNA was localized in the larval corpora allata. Recombinant TcMT3 protein methylated farnesoic acid and juvenile hormone III acid, but TcMT1 and TcMT2 proteins did not. Furthermore, RNA interference-mediated knockdown of TcMT3 in the larval stage resulted in precocious larval-pupal metamorphosis, whereas knockdown of either TcMT1 or TcMT2 showed no visible effects on metamorphosis. Importantly, precocious metamorphosis caused by TcMT3 RNA interference was rescued by an application of a juvenile hormone mimic, methoprene. Together, these results demonstrate that TcMT3 encodes a functional JHAMT gene that is essential for juvenile hormone biosynthesis and for the maintenance of larval status.
The growth of insects progresses via unique physiological events such as molting and metamorphosis. Those processes are strictly regulated by two peripheral hormones, molting hormone (20-hydroxyecdysone; 20E) and juvenile hormone (JH). 20E controls transcription of target genes by interacting with molting hormone receptor proteins, which bind to ecdysone response elements (EcREs) located upstream of the target genes. The transcriptional activation by 20E triggers signal cascades, and the development is accomplished via complex regulatory mechanisms [1]. The heterodimer of two nuclear receptors, ecdysone receptor (EcR) and ultraspiracle (USP), functions as a molting hormone receptor, and 20E is known to be a ligand for EcR. USP is the homologue of vertebrate RXR [2,3]. Amino-acid sequences of EcR and USP were first determined in the dipteran fruit fly Drosophila melanogaster [4][5][6], and subsequently determined in other insects [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25], as well as a crustacean [26] and a tick [27,28]. These receptor proteins consist of regions
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