果蝇免疫反应基因表达的性别二态性

MD Mursalin Khan, Rita M. Graze
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引用次数: 0

摘要

在多种类群中都能观察到免疫的性别二态性,这被认为是雌性和雄性之间基本生活史差异的结果。在黑腹果蝇中,感染不同的病原体通常会导致不同模式的免疫性双态性,有雄性偏向或雌性偏向,这可能是由于病原体的特定致病机制以及宿主与病原体之间的相互作用造成的。研究表明,一些途径,如 IMD 和 Toll,可以解释果蝇的这些性别二态性免疫反应。然而,目前还不清楚在黑腹果蝇中观察到的免疫反应性别差异是否是保守的,即使在近缘物种中也是如此。研究免疫相关基因的性别差异表达是识别免疫反应中保守和进化的性别差异的一个窗口。在这里,我们旨在了解两个亲缘关系很近的物种--黑腹蝇和拟黑腹蝇--在先天性免疫方面是否表现出保守的性别二态性,重点研究它们在感染革兰氏阴性菌Providencia rettgeri时基因表达的相关变化。研究了存活率、细菌负荷和死亡时的细菌负荷(BLUD),以评估总体性别差异。雌性黑腹蝇和雄性黑腹蝇在存活率方面存在显著差异,而模拟黑腹蝇则没有。富集分析表明,两种性别和物种都会上调涉及类似免疫相关生物过程的基因,但下调的基因组则有所不同。我们发现了细菌感染反应途径IMD、Toll、Jak/STAT及其调控因子和其他免疫相关基因类别(如BOMs)中基因表达的保守性别差异,以及性别和物种差异。在黑腹蝇蛆中,受IMD调控的效应抗菌肽(AMPs)在雌雄个体中都有较高的上调。此外,雌性黑腹蝇还独特地启动了高水平的基因表达,这些基因参与了控制 IMD 过度刺激的负反馈机制。Toll 通路中的基因也有性别差异表达,黑腹蝇的上调水平更高。值得注意的是,通过比较不同物种的表达,我们发现D. simulans可能同时采用了传统的肽聚糖识别驱动的PRR-SPE-Spz途径和基于微生物蛋白酶识别的Psh依赖性激活Toll途径;相比之下,D. melanogaster在这种情况下似乎只依赖于PRR-SPE-Spz途径。总之,我们的研究结果表明,在这两个物种中,大多数上调基因的性别差异是一致的,而下调模式和特定基因亚群则在性别或物种之间存在明显差异。
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Sex Dimorphism in Expression of Immune Response Genes in Drosophila
Sex dimorphism in immunity is commonly observed in a wide variety of taxa and is thought to arise from fundamental life history differences between females and males. In Drosophila melanogaster, infection with different pathogens typically results in different modes of immune sex dimorphism, with male- or female-bias, likely due to specific disease-causing mechanisms of pathogens and host-pathogen interactions. Studies showed that some pathways, such as IMD and Toll, can explain these sex-dimorphic immune responses in Drosophila. However, it is unclear if sex differences in the immune response observed in D. melanogaster are conserved, even in closely related species. One window into identifying conserved and evolving sex differences in the immune response is to examine the sex-differential expression of immunity-related genes. Here, we aim to understand whether two closely related species, D. melanogaster and D. simulans, show conserved sex dimorphism in innate immunity, focusing on associated changes in gene expression in response to infection with a gram-negative bacterium, Providencia rettgeri. Survival, bacterial load, and bacterial load upon death (BLUD) were investigated to assess overall sex differences. D. melanogaster females and males differed significantly in survival, whereas D. simulans did not. Enrichment analyses revealed that both sexes and species upregulate genes involved in similar immune-related biological processes, but downregulated groups differed. We identified conserved sex differential gene expression of genes in the bacterial infection response pathways IMD, Toll, Jak/STAT, their regulators, and other immune-related gene classes (e.g., BOMs), as well as sex and species differences. In D. melanogaster, the effector antimicrobial peptides (AMPs) regulated by IMD were more highly upregulated relative to D. simulans in both sexes. Moreover, D. melanogaster females uniquely initiated high levels of gene expression that were involved in negative feedback mechanisms that controlled the overstimulation of IMD. Genes in the Toll pathway were also sex-differentially expressed with a higher level of upregulation in D. melanogaster. Remarkably, comparing expression across species, we find that D. simulans likely employs both the conventional peptidoglycan recognition-driven PRR-SPE-Spz pathway and the microbial protease recognition-based Psh-dependent activation of Toll; in contrast, D. melanogaster appears to solely rely on the PRR-SPE-Spz pathway in this context. In summary, our findings indicate that sex differences are conserved in both species for the majority of upregulated genes, while downregulation patterns and specific gene subsets show notable differences between sexes or species.
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