4.6 Article

Sexual Dimorphism in Growth Rate and Gene Expression Throughout Immature Development in Wild Type Chrysomya rufifacies (Diptera: Calliphoridae) Macquart

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出版社

FRONTIERS MEDIA SA
DOI: 10.3389/fevo.2021.696638

关键词

forensic entomology; development; transcriptome; sexual dimorphism; Calliphoridae

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资金

  1. Whole Systems Genomics Initiative Catalyst
  2. Texas AgriLife Genomics Seed grants
  3. Texas A&M AgriLife Research funding
  4. Brazos Cluster at Texas AM University [NIJ: 2012-DN-BX-K024]
  5. Institute of International Education, New York, United States [2221/DR/2017-2018]
  6. TAMU Regents and Diversity Fellowships
  7. TAMU Whole Systems Genomics Initiative Student Fellowship program
  8. TAMU Dissertation Fellowship

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The reliability of forensic entomology analyses relies on understanding the arthropod populations of interest and the contributing factors to variability. Recent studies show that sexual dimorphism may play a crucial role in analyzing traits and age-related genetic markers. The Chrysomya rufifacies system is particularly suitable for studying sexual dimorphism due to its monogenic sex determination system.
Reliability of forensic entomology analyses to produce relevant information to a given case requires an understanding of the underlying arthropod population(s) of interest and the factors contributing to variability. Common traits for analyses are affected by a variety of genetic and environmental factors. One trait of interest in forensic investigations has been species-specific temperature-dependent growth rates. Recent work indicates sexual dimorphism may be important in the analysis of such traits and related genetic markers of age. However, studying sexual dimorphic patterns of gene expression throughout immature development in wild-type insects can be difficult due to a lack of genetic tools, and the limits of most sex-determination mechanisms. Chrysomya rufifacies, however, is a particularly tractable system to address these issues as it has a monogenic sex determination system, meaning females have only a single-sex of offspring throughout their life. Using modified breeding procedures (to ensure single-female egg clutches) and transcriptomics, we investigated sexual dimorphism in development rate and gene expression. Females develop slower than males (9 h difference from egg to eclosion respectively) even at 30 degrees C, with an average egg-to-eclosion time of 225 h for males and 234 h for females. Given that many key genes rely on sex-specific splicing for the development and maintenance of sexually dimorphic traits, we used a transcriptomic approach to identify different expression of gene splice variants. We find that 98.4% of assembled nodes exhibited sex-specific, stage-specific, to sex-by-stage specific patterns of expression. However, the greatest signal in the expression data is differentiation by developmental stage, indicating that sexual dimorphism in gene expression during development may not be investigatively important and that markers of age may be relatively independent of sex. Subtle differences in these gene expression patterns can be detected as early as 4 h post-oviposition, and 12 of these nodes demonstrate homology with key Drosophila sex determination genes, providing clues regarding the distinct sex determination mechanism of C. rufifacies. Finally, we validated the transcriptome analyses through qPCR and have identified five genes that are developmentally informative within and between sexes.

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