Advances in genome sequencing reveal changes in gene content that contribute to arthropod macroevolution.

Current sequencing technology allows for the relatively affordable generation of highly contiguous genomes. Technological advances have made it possible for researchers to investigate the consequences of diverse sorts of genomic variants, such as gene gain and loss. With the extraordinary number of high-quality genomes now available, we take stock of how these genomic variants impact phenotypic evolution. We take care to point out that the identification of genomic variants of interest is only the first step in understanding their impact. Painstaking lab or fieldwork is still required to establish causal relationships between genomic variants and phenotypic evolution. We focus mostly on arthropod research, as this phylum has an impressive degree of phenotypic diversity and is also the subject of much evolutionary genetics research. This article is intended to both highlight recent advances in the field and also to be a primer for learning about evolutionary genetics and genomics.

Experimental Entomology in the Age of Video.

ARTICLES DISCUSSED: Smodis Skerl, M. I. Histology basics and cell death detection in honeybee tissue. Journal of Visualized Experiments. (185), e64141 (2022). Fine, J. D., Torres, K. M., Martin, J., Robinson, G. E. Assessing agrochemical risk to mated honey bee queens. Journal of Visualized Experiments. (169), e62316 (2022). Topitzhofer, E., Lucas, H., Carlson, E., Chakrabarti, P., Sagili, R. Collection and identification of pollen from honey bee colonies. Journal of Visualized Experiments. (167), e62064 (2022). Nogueira, B. R., de Oliveira, A. A., Silva, D., Pereira da Silva, J., Bueno, O. C. Collection and long-term maintenance of leaf-cutting ants (Atta) in laboratory conditions. Journal of Visualized Experiments. (186), e64154 (2022).

Segmental expression of two ecdysone pathway genes during embryogenesis of hemimetabolous insects.

Signaling networks are redeployed across different developmental times and places to generate phenotypic diversity from a limited genetic toolkit. Hormone signaling networks in particular have well-studied roles in multiple developmental processes. In insects, the ecdysone pathway controls critical events in late embryogenesis and throughout post-embryonic development. While this pathway has not been shown to function in the earliest stage of embryonic development in the model insect Drosophila melanogaster, one component of the network, the nuclear receptor E75A, is necessary for proper segment generation in the milkweed bug Oncopeltus fasciatus. Published expression data from several other species suggests possible conservation of this role across hundreds of millions of years of insect evolution. Previous work also demonstrates a second nuclear receptor in the ecdysone pathway, Ftz-F1, plays a role in segmentation in multiple insect species. Here we report tightly linked expression patterns of ftz-F1 and E75A in two hemimetabolous insect species, the German cockroach Blattella germanica and the two-spotted cricket Gryllus bimaculatus. In both species, the genes are expressed segmentally in adjacent cells, but they are never co-expressed. Using parental RNAi, we show the two genes have distinct roles in early embryogenesis. E75A appears necessary for abdominal segmentation in B. germanica, while ftz-F1 is essential for proper germband formation. Our results suggest that the ecdysone network is critical for early embryogenesis in hemimetabolous insects.

The X chromosome of the German cockroach, Blattella germanica, is homologous to a fly X chromosome despite 400 million years divergence.

BACKGROUND: Sex chromosome evolution is a dynamic process that can proceed at varying rates across lineages. For example, different chromosomes can be sex-linked between closely related species, whereas other sex chromosomes have been conserved for > 100 million years. Cases of long-term sex chromosome conservation could be informative of factors that constrain sex chromosome evolution. Cytological similarities between the X chromosomes of the German cockroach (Blattella germanica) and most flies suggest that they may be homologous-possibly representing an extreme case of long-term conservation. RESULTS: To test the hypothesis that the cockroach and fly X chromosomes are homologous, we analyzed whole-genome sequence data from cockroaches. We found evidence in both sequencing coverage and heterozygosity that a significant excess of the same genes are on both the cockroach and fly X chromosomes. We also present evidence that the candidate X-linked cockroach genes may be dosage compensated in hemizygous males. Consistent with this hypothesis, three regulators of transcription and chromatin on the fly X chromosome are conserved in the cockroach genome. CONCLUSIONS: Our results support our hypothesis that the German cockroach shares the same X chromosome as most flies. This may represent the convergent evolution of the X chromosome in the lineages leading to cockroaches and flies. Alternatively, the common ancestor of most insects may have had an X chromosome that resembled the extant cockroach and fly X. Cockroaches and flies diverged ∼ 400 million years ago, which would be the longest documented conservation of a sex chromosome. Cockroaches and flies have different mechanisms of sex determination, raising the possibility that the X chromosome was conserved despite the evolution of the sex determination pathway.

Hemimetabolous insects elucidate the origin of sexual development via alternative splicing.

Insects are the only known animals in which sexual differentiation is controlled by sex-specific splicing. The doublesex transcription factor produces distinct male and female isoforms, which are both essential for sex-specific development. dsx splicing depends on transformer, which is also alternatively spliced such that functional Tra is only present in females. This pathway has evolved from an ancestral mechanism where dsx was independent of tra and expressed and required only in males. To reconstruct this transition, we examined three basal, hemimetabolous insect orders: Hemiptera, Phthiraptera, and Blattodea. We show that tra and dsx have distinct functions in these insects, reflecting different stages in the changeover from a transcription-based to a splicing-based mode of sexual differentiation. We propose that the canonical insect tra-dsx pathway evolved via merger between expanding dsx function (from males to both sexes) and narrowing tra function (from a general splicing factor to dedicated regulator of dsx).

Pan-metazoan phylogeny of the DMRT gene family: a framework for functional studies.

The family of Doublesex-Mab-3 Related Transcription factors (DMRTs) includes key regulators of sexual differentiation and neurogenesis. To help understand the functional diversification of this gene family, we examined DMRT gene complements from the whole genome sequences and predicted gene models of 32 animal species representing 12 different phyla and from several non-metazoan outgroups. DMRTs are present in all animals except the sponge Amphimedon queenslandica, but are not found in any of the outgroups, indicating that this gene family is specific to animals and has an ancient pre-eumetazoan origin. Our analyses suggest that DMRT genes diversified independently in bilaterian and non-bilaterian animals. Most clades in the DMRT gene tree, including those containing the well-characterized DMRT1 and doublesex genes, have phylogenetically limited distributions.