Project description:The most common ladybird beetle, Coccinella septempunctata L., is an excellent predator of crop pests such as aphids and white flies, and it shows a wide range of adaptability, a large appetite and a high reproductive ability. In this study, we collected female adults in three different states, i.e., non-diapause, diapause and diapause termination, for transcriptome sequencing. The experimental insects consisted of three different states as follows: Non-diapause female insects were reared at 24±1°C, with a RH of 70±10% and a 16:8 h light: dark (L: D) photoperiod and collected after their first oviposition. Female adults in diapause were reared at 18±1°C at an RH of 70±10% and a 10:14-h (L:D) photoperiod. The experimental diapause insects were collected after 30 days. Diapause-terminated adults were transferred to another climatic cabinet with the 30-day diapause insects and reared under the same conditions as the non-diapause insects. After their first oviposition, the female insects were collected and stored at -80°C. Three biological replicates per treatment (non-diapause, diapause, diapause-terminated) were sequenced using Illumina HiSeq 2500.
Project description:Investigation of gene expression level differences in Culex pipiens (SB) and C. quinquefasciatus (JHB) at three time points (8, 16, and 24 hours post-exposure) during the early pupal state in standard (25°C; 16 h light/8 h dark) and diapause-inducing (18°C; 8 h light/16 h dark) conditions. A forty-eight chip study (4 Expr12x135K slides) using cDNA from total RNA collected from two species in the Culex pipiens complex at 3 time-points during the early pupal stage to study gene expression differences between standard (25°C; 16 h light/8 h dark) and diapause-inducing (18°C; 8 h light/16 h dark) conditions, and between Culex pipiens (diapause) and C. quinquefasciatus (no diapause). Each chip measures the expression level of 18,692 protein coding genes, with 3 probes per gene and two-fold technical redundancy. Each of the 12-plex slides was used for one of four biological replicates. Probes were designed using the C.quinquefasciatus CpipJ1.2 geneset in VectorBase.
Project description:In temperate latitudes, many insects enter diapause (dormancy) during the cold season, a period during which developmental processes come to a standstill. The wood white (Leptidea sinapis) is a butterfly species distributed across western Eurasia that shows photoperiod-induced diapause with variation in critical day-length across populations at different latitudes. We assembled transcriptomes and estimated gene expression levels at different developmental stages in experimentally induced directly developing and diapausing cohorts of a single Swedish population of L. sinapis to investigate the regulatory mechanisms underpinning diapause initiation. Different day lengths resulted in expression changes of developmental genes and affected the rate of accumulation of signal molecules, suggesting that diapause induction might be controlled by increased activity of monoamine neurotransmitters in larvae reared under short-day light conditions. Expression differences between light treatment groups of two monoamine regulator genes (DDC and ST) were observed already in instar III larvae. Once developmental pathways were irreversibly set at instar V, a handful of genes related to dopamine production were differentially expressed leading to a significant decrease in expression of global metabolic genes and increase in expression of genes related to fatty acid synthesis and sequestration. This is in line with a time-dependent (hour-glass) model of diapause regulation where a gradual shift in the concentration of monoamine neurotransmitters and their metabolites during development of larvae under short-day conditions leads to increased storage of fat, decreased energy expenditures, and ultimately developmental stasis at the pupal stage.
Project description:Diapause is an environmentally programmed and hormonally regulated period of dormancy which makes an important part of the life-cycle in many species of invertebrates. In this study, using a RNAseq approach, we focused on very early stages of diapause induction in the larvae of drosophilid fly, Chymomyza costata by characterizing global patterns of gene expression associated with photoperiodic induction of diapause.
Project description:The most common ladybird beetle, Coccinella septempunctata L., is an excellent predator of crop pests such as aphids and white flies, and it shows a wide range of adaptability, a large appetite and a high reproductive ability. In this study, we collected female adults in three different states, i.e., non-diapause, diapause and diapause termination, for transcriptome sequencing.
Project description:Gene expression microarray exprement comparing differential expression between: 1) Early Diapause (ED), 2) Late Diapause (LD), 3) Non-Diapause (ND), 4) Hexane-induced diapause break (HEX). Four phenotypes (ED,ND,LD,HEX), four replicate pools of four individuals (four individuals in each replicate) in each phenotype, four competitve hybs comparing each phenotype to every other phenotype.
Project description:Embryonic diapause is a widely occurring evolutionary adaptation phenomenon in animals. Artemia is one of the classic animal models for diapause research. The current studies of Artemia diapause mainly focus on the induction and maintenance of the embryonic diapause, but there is little research on the molecular regulatory mechanism of Artemia embryonic diapause termination (EDT) and embryonic reactivation. Here the gene expression of Artemia cyst in diapause stage and 5 hours after embryonic diapause termination (EDT), which is in post-diapause stage were tested by ATAC-seq to analyze the mechanism of signal regulation involved in Artemia EDT at the molecular level.
Project description:Embryonic diapause is a widely occurring evolutionary adaptation phenomenon in animals. Artemia is one of the classic animal models for diapause research. The current studies of Artemia diapause mainly focus on the induction and maintenance of the embryonic diapause, but there is little research on the molecular regulatory mechanism of Artemia embryonic diapause termination (EDT) and embryonic reactivation. Here the gene expression of Artemia cyst in diapause stage and 5 hours after embryonic diapause termination (EDT), which is in post-diapause stage were tested by RNA-seq to analyze the mechanism of signal regulation involved in Artemia EDT at the molecular level.
Project description:Adult reproductive diapause is a powerful overwintering strategy for many continental insect species including bumblebees, which enables queens to survive several months through harsh winter conditions and then build new beehives in the following spring. There are few reports regarding the molecular regulatory mechanism of reproductive diapause in Bombus terrestris, which is an important pollinators of wild plants and crops, and our previous researches identified the conditions for reproductive diapause of year-round mass rearing. Here, we performed combined RNA sequencing transcriptomics and quantitative proteomic analyses in different development phases relate to reproductive diapause. According to the overall analysis, we found these differentially expressed proteins/genes act in the citrate cycle, insect hormone biosynthesis, insulin and mTOR signalling pathway. To get better sense of the reproductive diapause regulated mechanism, some genes regulated JH synthesis, insulin/ TOR signal pathway were detected, the BtRheb, BtTOR, BtVg and BtJHAMT had lower expression levels in diapause queens, and the JH III titers levels and some metabolic enzymes activities were significantly up-regulated in found post-diapause queens. After microinjected insulin-like peptides (ILPs) and JH analog (JHA), some indicators shows the significantly changes of hormones, cold tolerance substances, metabolic enzymes and reproduction. Along with other related researches, a reproductive diapause regulated model during B. terrestris year-round mass rearing process was establishment. This study contribute to a comprehensive view and the molecular regulate mechanism of productive diapause in eusocial insect.