Karyotype evolution in <i>Ronderosia</i> grasshoppers (Orthoptera: Acrididae)

Castillo, Elio Rodrigo Daniel; Scattolini, María Celeste; Palacios-Gimenez, Octavio M.; Martí, Dardo A.; Cabral-de-Mello, Diogo Cavalcanti; Cigliano, Marı́a Marta

doi:10.1093/zoolinnean/zlac090

Cited by 3 publications

(1 citation statement)

References 81 publications

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“…We do know that key exceptions to the evolutionary trap model of sex chromosome evolution are driven by chromosomal fusions between sex chromosomes and autosomes (Maddison and Leduc-Robert 2013;Pennell, et al 2015;Sigeman, et al 2022;Castillo, et al 2023). These fusions can generate new sex chromosome systems and 'refresh' the sequence content of the sex-linked genome.…”

Section: Introductionmentioning

confidence: 99%

Chromosomal fusion drives sex chromosome evolution in treehoppers despite long-term X chromosome conservation

Palmer Droguett,

Fletcher,

Kocher

et al. 2024

Preprint

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Sex chromosomes follow distinct evolutionary trajectories compared to the rest of the genome. In many cases, sex chromosomes (X and Y, or Z and W) significantly differentiate from one another resulting in heteromorphic sex chromosome systems. Such heteromorphic systems are thought to act as an evolutionary trap that prevents subsequent turnover of the sex chromosome system. For old, degenerated sex chromosome systems in which turnover is unlikely, chromosomal fusion with an autosome may be one way that sex chromosomes can ‘refresh’ their sequence content. We investigated these dynamics using treehoppers (hemipteran insects of the family Membracidae), which ancestrally have XX/X0 sex chromosomes. We assembled the first chromosome-level treehopper genome fromUmbonia crassicornisand employed comparative genomic analyses of 12 additional treehopper species to analyze X chromosome variation across different evolutionary timescales. We find that the X chromosome is largely conserved, with one exception being an X-autosome fusion inCalloconophora caliginosa. We also compare the ancestral treehopper X with other X chromosomes in Auchenorrhyncha (the clade containing treehoppers, leafhoppers, spittlebugs, cicadas, and planthoppers), revealing X conservation across more than 300 million years. These findings shed light on chromosomal evolution dynamics in treehoppers and the role of chromosomal rearrangements in sex chromosome evolution.SignificanceThe evolutionary forces underlying sex chromosome stability versus turnover have been challenging to disentangle. We present the first chromosome-level treehopper genome and find evidence of long-term X chromosome conservation within treehoppers – and among treehoppers and other hemipteran insects. A key exception is the evolution of neo-XX/XY sex chromosomes via an X-autosome fusion. Sex chromosome-autosome fusions may play an important role in the evolution of otherwise ‘trapped’ (i.e., old and degenerated) sex chromosome systems.

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Section: Introductionmentioning

confidence: 99%

Chromosomal fusion drives sex chromosome evolution in treehoppers despite long-term X chromosome conservation

Palmer Droguett,

Fletcher,

Kocher

et al. 2024

Preprint

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Neo-Sex Chromosome Evolution in Treehoppers Despite Long-Term X Chromosome Conservation

Palmer Droguett,

Fletcher,

Alston

et al. 2024

Genome Biology and Evolution

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Sex chromosomes follow distinct evolutionary trajectories compared to the rest of the genome. In many cases, sex chromosomes (X and Y, or Z and W) significantly differentiate from one another resulting in heteromorphic sex chromosome systems. Such heteromorphic systems are thought to act as an evolutionary trap that prevents subsequent turnover of the sex chromosome system. For old, degenerated sex chromosome systems, chromosomal fusion with an autosome may be one way that sex chromosomes can ‘refresh’ their sequence content. We investigated these dynamics using treehoppers (hemipteran insects of the family Membracidae), which ancestrally have XX/X0 sex chromosomes. We assembled the most complete reference assembly for treehoppers to date for Umbonia crassicornis and employed comparative genomic analyses of 12 additional treehopper species to analyze X chromosome variation across different evolutionary timescales. We find that the X chromosome is largely conserved, with one exception being an X-autosome fusion in Calloconophora caliginosa. We also compare the ancestral treehopper X with other X chromosomes in Auchenorrhyncha (the clade containing treehoppers, leafhoppers, spittlebugs, cicadas, and planthoppers), revealing X conservation across more than 300 million years. These findings shed light on chromosomal evolution dynamics in treehoppers and the role of chromosomal rearrangements in sex chromosome evolution.

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A novel multiple sex chromosome system in Orthoptera, found in the tree cricket Oecanthus rubromaculatus Zefa, 2022 (Grylloidea, Oecanthidae)

ZEFA,

ACOSTA,

KRETSCHMER

et al. 2024

Zootaxa

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The X0♂/XX♀ sex chromosome system prevails in most Orthopteran species. The X chromosome stands as one of the largest chromosomes within the complement, and is characterized by its heterochromatic nature. Variations of this model were found in some species of grasshoppers, crickets, and katydids, based on X/autosome rearrangements, giving rise to new sex chromosome systems, such as neo-XY♂/XX♀ and neo-X1X2Y♂/X1X1X2X2♀. The sex chromosome system neo-X1X20♂/X1X1X2X2♀ is rare in Orthoptera, and was observed only in two cricket species. In this study, we present the first multiple chiasmatic sex chromosome system in Orthoptera, found in the tree cricket Oecanthus rubromaculatus Zefa, 2022 from two distinct locations in the State of Rio Grande do Sul, Brazil. In one location, individuals exhibited a karyotype with 2n = 12, X1X2Y1Y2♂/X1X1X2X2♀, while in the other a karyotype of 2n = 12, X1X2X3Y1Y2Y3♂/X1X1X2X2X3X3♀ was observed. We proposed a model to explain the evolutionary steps in the formation of these karyotypes, based on chromosomal information of the Neotropical Oecanthus’ species. In this context, we proposed a hypothesis to explain the chromosome reorganization in O. rubromaculatus, starting from an ancestral karyotype of 2n = 21, X0♂, like the karyotype found in Oecanthus pictus Milach & Zefa, 2015, resulting in a significant reduction to 2n = 12 in O. rubromaculatus. This reorganization has led to the emergence of the novel multiple sex chromosome system in Orthoptera.

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Karyotype evolution in Ronderosia grasshoppers (Orthoptera: Acrididae)

Cited by 3 publications

References 81 publications

Chromosomal fusion drives sex chromosome evolution in treehoppers despite long-term X chromosome conservation

Chromosomal fusion drives sex chromosome evolution in treehoppers despite long-term X chromosome conservation

Neo-Sex Chromosome Evolution in Treehoppers Despite Long-Term X Chromosome Conservation

A novel multiple sex chromosome system in Orthoptera, found in the tree cricket Oecanthus rubromaculatus Zefa, 2022 (Grylloidea, Oecanthidae)

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