Project description:GENETIC INDEPENDENCE BETWEEN TRAITS SEPARATED BY METAMORPHOSIS IS WIDESPREAD BUT VARIES WITH BIOLOGICAL FUNCTION

Project description:Drosophila melanogaster undergoes a complete metamorphosis, during which time the larval male and female forms transition into sexually dimorphic, reproductive adult forms. To understand this complex morphogenetic process at a molecular-genetic level, we performed whole genome microarray analyses. Genes were identified that were expressed during metamorphosis in both somatic and germline tissues of males and females. Additionally, genes were identified that display sex-specific differences in abundance in both of these tissues at discrete times during metamorphosis. Keywords: time course; wild type; genetic modification; Gene expression was examined at five time points during metamorphosis: 0, 24, 48, 71, and 96 hr After Puparium Formation (APF). Gene expression was examined separately in males and females for both wild type pupae and tudor (tud) progeny. tud progeny have genetically ablated germline tissues. All samples were labeled with Cy5 and compared against a common reference sample labeled with Cy3. The reference sample contained male and female wild type pupae from all stages of metamorphosis. All experiments were conducted in triplicate.

Project description:RNA-seq of larval stages around molting and metamorphosis

Project description:Larval settlement and metamorphosis is a vital transition period for marine invertebrates and can have far-reaching effects on the ecology and evolution of a species. To explore the molecular mechanisms of this critical process in a non-model organism, the tropical abalone Haliotis asinina, we employed cDNA microarray methods. By comparing gene expression profiles through mid to late larval development and metamorphosis, we identified 144 genes as likely candidates for a role in competence and/or metamorphosis. Gene characterization showed that ~60% of these were significantly similar to previously described genes from other taxa, while ~40% had no significant similarities to any known genes. A high 49.3% of genes were gastropod- or abalone-specific, but none appear to be Lophotrochozoan-specific, despite the fact that metamorphosis is thought to have had a separate origin in this group. Based on temporal expression profiles, the differentially expressed larval and postlarval genes can be clustered into 5 categories that reveal there are strikingly different transcriptional patterns occurring during this phase of development. Some classes of gene activation are contingent upon exogenous cues and correlate with the initiation of settlement and metamorphosis. Importantly, there is also extensive gene activity associated with the endogenous attainment of competence, which occurs prior to, and independent of, the exogenous induction of settlement. Our results show that as the haliotid veliger larva matures, it requires the coordinated regulation of temporally different batteries of genes involved in a wide range of physiological and developmental processes associated with colonisation of the benthos. Although the signalling pathways operating at metamorphosis may be conserved across the animal kingdom, it appears they are regulating the expression of novel genes specific to abalone, gastropods and molluscs during H. asinina metamorphosis. Keywords: timecourse; metamorphosis; marine ecology Each microarray slide contained a different combination of 2 of the 9 developmental stages used in the experiment (66 hpf, 78 hpf, 90 hpf, 108 hpf, 120 hpf, 144 hpf, 12 hpi, 24 hpi, 48 hpi). Each developmental stage was subjected to 4 hybridisations – amounting to 4 technical replicates per stage - in a loop design (Churchill 2002; Oleksiak et al. 2002). This design led to raw data consisting of 72 measurements - 9 stages with 8 replicates (including 2 replicates per chip) - for each of 5541 spots.

Project description:Drosophila melanogaster undergoes a complete metamorphosis, during which time the larval male and female forms transition into sexually dimorphic, reproductive adult forms. To understand this complex morphogenetic process at a molecular-genetic level, we performed whole genome microarray analyses. Genes were identified that were expressed during metamorphosis in both somatic and germline tissues of males and females. Additionally, genes were identified that display sex-specific differences in abundance in both of these tissues at discrete times during metamorphosis. Keywords: time course; wild type; genetic modification;

Project description:The monitoring of global transcription patterns during development is a useful first step to understand mechanisms underlying growth, differentiation and patterning in a given species. However such large scale developmental studies are so far only available from a few selected model organisms such as mouse, Drosophila and the nematode C. elegans. Genomic scale information from the lophotrochozoa is now emerging. The recently characterized neuronal transcriptome of the sea hare Aplysia californica (~200’000 ESTs and ~40,000 unique non-redundant sequences representing about 55-70% of all neuronal transcripts including splice forms and non-coding RNAs) provides new insights and opportunities into problems of molluscan development and specifically neurogenesis. Regulatory genes used in development are recruited for the functions of adult nervous systems such as synaptogenesis, specific wiring in networks and structural changes underlying synaptic plasticity. While this similarity reflects a basic concept in biology, namely the recruitment of the same genes for different functions, it has never been tested on a large scale genomic level. We used representative oligo-arrays constructed from transcripts obtained from the Aplysia nervous system to explore the following two questions: 1) What neuronal genes are differentially expressed during embryonic development of the sea hare Aplysia. 2) What gene expression changes can be observed in correlation with gastrulation, metamorphosis, and larval neurogenesis. For this purpose we hybridized RNA from 3 embryonic (64 cells, gastrula, trochophore) and 4 larval stages (pre-hatching, post-hatching, pre-metamorphosis, postmetamorphosis) against a reference sample consisting of equal contributions from all stages. Our analysis revealed that all embryonic and larval stages can be distinguished based on their transcription profiles. A comparison of the Aplysia atlas with similar studies in Drosophila and mouse reveals interesting differences. We identified several new transcription factors which are differentially expressed during early embryonic development. Various other transcripts involved in metabolism and differentiation were characterized. These genes can be candidate targets for understanding neuronal growth, synaptogenesis and memory mechanisms. We conclude that the microarray technology provides us with a powerful tool for efficient survey and functional annotation of the neuronal transcriptome in Aplysia. We used a reference design for this study where we hybridized each of the 8 developmental stages of Aplysia (cleavage, gastrula, trochophore, first veliger, hatching veliger, pre-metamorphosis (stage 6), post-metamorphosis (stage 7), post-metamorphosis 60 hours (pm60)

Project description:Larval settlement and metamorphosis is a vital transition period for marine invertebrates and can have far-reaching effects on the ecology and evolution of a species. To explore the molecular mechanisms of this critical process in a non-model organism, the tropical abalone Haliotis asinina, we employed cDNA microarray methods. By comparing gene expression profiles through mid to late larval development and metamorphosis, we identified 144 genes as likely candidates for a role in competence and/or metamorphosis. Gene characterization showed that ~60% of these were significantly similar to previously described genes from other taxa, while ~40% had no significant similarities to any known genes. A high 49.3% of genes were gastropod- or abalone-specific, but none appear to be Lophotrochozoan-specific, despite the fact that metamorphosis is thought to have had a separate origin in this group. Based on temporal expression profiles, the differentially expressed larval and postlarval genes can be clustered into 5 categories that reveal there are strikingly different transcriptional patterns occurring during this phase of development. Some classes of gene activation are contingent upon exogenous cues and correlate with the initiation of settlement and metamorphosis. Importantly, there is also extensive gene activity associated with the endogenous attainment of competence, which occurs prior to, and independent of, the exogenous induction of settlement. Our results show that as the haliotid veliger larva matures, it requires the coordinated regulation of temporally different batteries of genes involved in a wide range of physiological and developmental processes associated with colonisation of the benthos. Although the signalling pathways operating at metamorphosis may be conserved across the animal kingdom, it appears they are regulating the expression of novel genes specific to abalone, gastropods and molluscs during H. asinina metamorphosis. Keywords: timecourse; metamorphosis; marine ecology

Project description:We analyzed the proteomes of competent Rapna venosa larvae and post-larvae, resulting in the identification of 5,312 proteins, including 470 that were down-regulated and 668 that were up-regulated after metamorphosis. The differentially expressed proteins reflected multiple processes involved in metamorphosis, including cytoskeleton and cell adhesion, ingestion and digestion, stress response and immunity, as well as specific tissue development. Our data improve understanding of the physiological traits controlling R. venosa metamorphosis and provide a solid basis for further study.

Project description:Molting is an essential biological process occurring characteristic times throughout the life cycle of holometabolous insects. However, it is not clear how insects determine whether the direction of molting is to remain status quo or to initiate metamorphosis. Here, we used liquid chromatography-mass spectrometry to identify the molecules involved in larval and metamorphic molting, and compare the differentially expressed proteins (DEPs) in the two processes, to explore the functional factors that determine the direction of molts. There were 322 and 1140 DEPs identified in larval and metamorphic molting process, respectively. Bioinformatics analyses show that the amino sugar pathway was up-regulated in both processes. The up-regulated protease contributed to the metamorphosis. In addition, several proteins with different expression patterns in larval-larval and larval-pupal transitions, including Endochitinase, GRIM-19 (Genes associated with retinoid-IFN-induced mortality-19), IDE (Insulin-degrading enzyme), Sorcin (Soluble resistance related calcium binding protein), OBP (Odorant-binding protein-2 precursor), TRAP1(Tumor necrosis factor receptor associated protein-1), etc., were further identified by parallel reaction monitoring, which may play diverse functions in the determination of molting properties. These results provide a proteomic insight into molecules involved in larval and metamorphic molts, and will likely improve the current understanding of determination of direction of molts.

Project description:The genomic distribution of trait-associated SNPs (TASs) discovered in genome-wide association studies (GWAS) can provide insight into the genetic architecture of complex traits and the design of future studies. Here we report on a maize GWAS that identified TASs underlying five quantitative traits measured across a large panel of samples and examine the characteristics of these TASs. A set of SNPs obtained via RNA sequencing (RNA-seq), most of which are located within annotated genes (~87%) were complemented with additional SNPs from the maize HapMap Project that contains approximately equal proportions of intragenic and intergenic SNPs. TASs were identified via a genome scan while controlling for polygenic background effects. The diverse functions of TAS-containing candidate genes indicate that complex genetic networks shape these traits. The vast majority of the TAS-containing candidate genes have dynamic expression levels among developmental stages. Overall, TASs explain 44~54% of the total phenotypic variation for these traits, with equal contributions from intra- and inter-genic TASs. Association of ligueless2 with upper leaf angle was implicated by two intragenic TASs; rough sheath1 was associated with leaf width by an upstream intergenic TAS; and Zea agamous5 was associated with days to silking by both intra- and inter-genic TASs. A large proportion (82%) of these TASs comes from noncoding regions, similar to findings from human diseases and traits. However, TASs were enriched in both intergenic (53%) and promoter 5kb (24%) regions, but under-represented in a set of nonsynonymous SNPs.