Irradiation induced inversions suppress recombination between the M locus and morphological markers in Aedes aegypti.

IF 2.9 Q2 Biochemistry, Genetics and Molecular Biology

BMC Genetics Pub Date : 2020-12-18 DOI:10.1186/s12863-020-00949-w

Antonios A Augustinos, Muhammad Misbah-Ul-Haq, Danilo O Carvalho, Lucia Duran de la Fuente, Panagiota Koskinioti, Kostas Bourtzis

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Abstract

Background: Aedes aegypti is the primary vector of arthropod-borne viruses and one of the most widespread and invasive mosquito species. Due to the lack of efficient specific drugs or vaccination strategies, vector population control methods, such as the sterile insect technique, are receiving renewed interest. However, availability of a reliable genetic sexing strategy is crucial, since there is almost zero tolerance for accidentally released females. Development of genetic sexing strains through classical genetics is hindered by genetic recombination that is not suppressed in males as is the case in many Diptera. Isolation of naturally-occurring or irradiation-induced inversions can enhance the genetic stability of genetic sexing strains developed through genetically linking desirable phenotypes with the male determining region.

Results: For the induction and isolation of inversions through irradiation, 200 male pupae of the 'BRA' wild type strain were irradiated at 30 Gy and 100 isomale lines were set up by crossing with homozygous 'red-eye' (re) mutant females. Recombination between re and the M locus and the white (w) gene (causing a recessive white eye phenotype when mutated) and the M locus was tested in 45 and 32 lines, respectively. One inversion (Inv35) reduced recombination between both re and the M locus, and wand the M locus, consistent with the presence of a rather extended inversion between the two morphological mutations, that includes the M locus. Another inversion (Inv5) reduced recombination only between w and the M locus. In search of naturally-occurring, recombination-suppressing inversions, homozygous females from the red eye and the white eye strains were crossed with seventeen and fourteen wild type strains collected worldwide, representing either recently colonized or long-established laboratory populations. Despite evidence of varying frequencies of recombination, no combination led to the elimination or substantial reduction of recombination.

Conclusion: Inducing inversions through irradiation is a feasible strategy to isolate recombination suppressors either on the M or the m chromosome for Aedes aegypti. Such inversions can be incorporated in genetic sexing strains developed through classical genetics to enhance their genetic stability and support SIT or other approaches that aim to population suppression through male-delivered sterility.

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辐照诱导的倒位抑制了埃及伊蚊 M 基因座与形态标记之间的重组。

背景：埃及伊蚊是节肢动物传播病毒的主要媒介，也是最广泛和最具入侵性的蚊子物种之一。由于缺乏有效的特效药物或疫苗接种策略，昆虫不育技术等病媒种群控制方法再次受到关注。然而，由于对意外释放的雌蚊的容忍度几乎为零，因此可靠的基因性别化策略的可用性至关重要。通过经典遗传学开发基因性别品系的工作受到基因重组的阻碍，因为雄性的基因重组不会像许多双翅目昆虫那样受到抑制。分离自然发生的或辐照诱导的倒位，可以通过将理想的表型与雄性决定区基因联系起来，提高遗传性别品系的遗传稳定性：为了通过辐照诱导和分离倒位，对'BRA'野生型品系的 200 个雄蛹进行了 30 Gy 的辐照，并通过与同卵'红眼'（re）突变雌性杂交建立了 100 个等雄品系。分别在 45 个品系和 32 个品系中测试了 re 基因与 M 基因座之间的重组，以及白（w）基因（突变时导致隐性白眼表型）与 M 基因座之间的重组。一个反转（Inv35）减少了 re 和 M 基因座之间的重组，也减少了 M 基因座的游走，这与两个形态突变之间存在一个相当扩展的反转（包括 M 基因座）是一致的。另一种反转（Inv5）只减少了 w 和 M 基因座之间的重组。为了寻找自然发生的抑制重组的倒位，红眼和白眼品系的同源雌性分别与在世界各地收集到的 17 个和 14 个野生型品系杂交，这些野生型品系代表了新近定居或长期定居的实验室种群。尽管有证据表明重组频率各不相同，但没有一种组合能消除或大幅减少重组：结论：通过辐照诱导倒位是在埃及伊蚊的 M 或 m 染色体上分离重组抑制因子的可行策略。这种倒位可纳入通过经典遗传学开发的基因性别株中，以提高其遗传稳定性，并支持SIT或其他旨在通过雄性不育抑制种群的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

BMC Genetics 生物-遗传学

CiteScore

4.30

自引率

0.00%

发文量

审稿时长

4-8 weeks

期刊介绍： BMC Genetics is an open access, peer-reviewed journal that considers articles on all aspects of inheritance and variation in individuals and among populations.