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1. Human Gene Age Dating Reveals an Early and Rapid Evolutionary Construction of the Adaptive Immune System

   https://doi.org/10.1093/gbe/evad081  

   Zhang, Li ; Park, Jonathan J ; Dong, Matthew B ; Arsala, Deanna ; Xia, Shengqian ; Chen, Jianhai ; Sosa, Dylan ; Atlas, Jared E ; Long, Manyuan ; Chen, Sidi ( May 2023 , Genome Biology and Evolution)

   Alba, Mar (Ed.)

   Abstract T cells are a type of white blood cell that play a critical role in the immune response against foreign pathogens through a process called T cell adaptive immunity (TCAI). However, the evolution of the genes and nucleotide sequences involved in TCAI is not well understood. To investigate this, we performed comparative studies of gene annotations and genome assemblies of 28 vertebrate species and identified sets of human genes that are involved in TCAI, carcinogenesis, and aging. We found that these gene sets share interaction pathways, which may have contributed to the evolution of longevity in the vertebrate lineage leading to humans. Our human gene age dating analyses revealed that there was rapid origination of genes with TCAI-related functions prior to the Cretaceous eutherian radiation and these new genes mainly encode negative regulators. We identified no new TCAI-related genes after the divergence of placental mammals, but we did detect an extensive number of amino acid substitutions under strong positive selection in recently evolved human immunity genes suggesting they are coevolving with adaptive immunity. More specifically, we observed that antigen processing and presentation and checkpoint genes are significantly enriched among new genes evolving under positive selection. These observations reveal evolutionary processes of TCAI that were associated with rapid gene duplication in the early stages of vertebrates and subsequent sequence changes in TCAI-related genes. The analysis of vertebrate genomes provides evidence that a "big bang" of adaptive immune genes occurred 300-500 million years ago. These processes together suggest an early genetic construction of the vertebrate immune system and subsequent molecular adaptation to diverse antigens. 

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2. Species-specific partial gene duplication in Arabidopsis thaliana evolved novel phenotypic effects on morphological traits under strong positive selection

   https://doi.org/10.1093/plcell/koab291  

   Huang, Yuan ; Chen, Jiahui ; Dong, Chuan ; Sosa, Dylan ; Xia, Shengqian ; Ouyang, Yidan ; Fan, Chuanzhu ; Li, Dezhu ; Mortola, Emily ; Long, Manyuan ; et al ( December 2021 , The Plant Cell)

   Gene duplication is increasingly recognized as an important mechanism for the origination of new genes, as revealed by comparative genomic analysis. However, how new duplicate genes contribute to phenotypic evolution remains largely unknown, especially in plants. Here, we identified the new gene EXOV, derived from a partial gene duplication of its parental gene EXOVL in Arabidopsis thaliana. EXOV is a species-specific gene that originated within the last 3.5 million years and shows strong signals of positive selection. Unexpectedly, RNA-sequencing analyses revealed that, despite its young age, EXOV has acquired many novel direct and indirect interactions in which the parental gene does not engage. This observation is consistent with the high, selection-driven substitution rate of its encoded protein, in contrast to the slowly evolving EXOVL, suggesting an important role for EXOV in phenotypic evolution. We observed significant differentiation of morphological changes for all phenotypes assessed in genome-edited and T-DNA insertional single mutants and in double T-DNA insertion mutants in EXOV and EXOVL. We discovered a substantial divergence of phenotypic effects by principal component analyses, suggesting neofunctionalization of the new gene. These results reveal a young gene that plays critical roles in biological processes that underlie morphological evolution in A. thaliana.

    

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3. Whole‐genome assembly and annotation for the little yellow croaker ( Larimichthys polyactis ) provide insights into the evolution of hermaphroditism and gonochorism

   https://doi.org/10.1111/1755-0998.13731  

   Xie, Qing‐Ping ; Zhan, Wei ; Shi, Jian‐Zhi ; Liu, Feng ; Niu, Bao‐Long ; He, Xue ; Liu, Meng ; Wang, Jing ; Liang, Qi‐Qi ; Xie, Yue ; et al ( November 2022 , Molecular Ecology Resources)

   The evolutionary direction of gonochorism and hermaphroditism is an intriguing mystery to be solved. The special transient hermaphroditic stage makes the little yellow croaker (Larimichthys polyactis) an appealing model for studying hermaphrodite formation. However, the origin and evolutionary relationship between ofL. polyactisandLarimichthys crocea, the most famous commercial fish species in East Asia, remain unclear. Here, we report the sequence of theL. polyactisgenome, which we found is ~706 Mb long (contig N50 = 1.21 Mb and scaffold N50 = 4.52 Mb) and contains 25,233 protein‐coding genes. Phylogenomic analysis suggested thatL. polyactisdiverged from the common ancestor,L. crocea, approximately 25.4 million years ago. Our high‐quality genome assembly enabled comparative genomic analysis, which revealed several within‐chromosome rearrangements and translocations, without major chromosome fission or fusion events between the two species. Thedmrt1gene was identified as the male‐specific gene inL. polyactis. Transcriptome analysis showed that the expression ofdmrt1and its upstream regulatory gene (rnf183) were both sexually dimorphic.Rnf183, unlike its two paraloguesrnf223andrnf225, is only present inLarimichthysandLatesbut not in other teleost species, suggesting that it originated from lineage‐specific duplication or was lost in other teleosts.Phylogenetic analysis shows that the hermaphrodite stage in maleL. polyactismay be explained by the sequence evolution ofdmrt1. Decoding theL. polyactisgenome not only provides insight into the genetic underpinnings of hermaphrodite evolution, but also provides valuable information for enhancing fish aquaculture.

    

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4. A chromosome-level genome assembly and annotation of the desert horned lizard, Phrynosoma platyrhinos , provides insight into chromosomal rearrangements among reptiles

   https://doi.org/10.1093/gigascience/giab098  

   Koochekian, Nazila ; Ascanio, Alfredo ; Farleigh, Keaka ; Card, Daren C. ; Schield, Drew R. ; Castoe, Todd A. ; Jezkova, Tereza ( February 2022 , GigaScience)

   The increasing number of chromosome-level genome assemblies has advanced our knowledge and understanding of macroevolutionary processes. Here, we introduce the genome of the desert horned lizard, Phrynosoma platyrhinos, an iguanid lizard occupying extreme desert conditions of the American southwest. We conduct analysis of the chromosomal structure and composition of this species and compare these features across genomes of 12 other reptiles (5 species of lizards, 3 snakes, 3 turtles, and 1 bird).

   The desert horned lizard genome was sequenced using Illumina paired-end reads and assembled and scaffolded using Dovetail Genomics Hi-C and Chicago long-range contact data. The resulting genome assembly has a total length of 1,901.85 Mb, scaffold N50 length of 273.213 Mb, and includes 5,294 scaffolds. The chromosome-level assembly is composed of 6 macrochromosomes and 11 microchromosomes. A total of 20,764 genes were annotated in the assembly. GC content and gene density are higher for microchromosomes than macrochromosomes, while repeat element distributions show the opposite trend. Pathway analyses provide preliminary evidence that microchromosome and macrochromosome gene content are functionally distinct. Synteny analysis indicates that large microchromosome blocks are conserved among closely related species, whereas macrochromosomes show evidence of frequent fusion and fission events among reptiles, even between closely related species.

   Our results demonstrate dynamic karyotypic evolution across Reptilia, with frequent inferred splits, fusions, and rearrangements that have resulted in shuffling of chromosomal blocks between macrochromosomes and microchromosomes. Our analyses also provide new evidence for distinct gene content and chromosomal structure between microchromosomes and macrochromosomes within reptiles.

    

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5. The Complete Genome of Chelonus insularis Reveals Dynamic Arrangement of Genome Components in Parasitoid Wasps That Produce Bracoviruses

   https://doi.org/10.1128/JVI.01573-21  

   Mao, Meng ; Strand, Michael R. ; Burke, Gaelen R. ( March 2022 , Journal of Virology)

   Parrish, Colin R. (Ed.)

   ABSTRACT Bracoviruses (BVs) are endogenized nudiviruses in parasitoid wasps of the microgastroid complex (family Braconidae). Microgastroid wasps have coopted nudivirus genes to produce replication-defective virions that females use to transfer virulence genes to parasitized hosts. The microgastroid complex further consists of six subfamilies and ∼50,000 species but current understanding of BV gene inventories and organization primarily derives from analysis of two wasp species in the subfamily Microgastrinae ( Microplitis demolitor and Cotesia congregata ) that produce M. demolitor BV (MdBV) and C. congregata BV (CcBV). Notably, several genomic features of MdBV and CcBV remain conserved since divergence of M. demolitor and C. congregata ∼53 million years ago (MYA). However, it is unknown whether these conserved traits more broadly reflect BV evolution, because no complete genomes exist for any microgastroid wasps outside the Microgastrinae. In this regard, the subfamily Cheloninae is of greatest interest because it diverged earliest from the Microgastrinae (∼85 MYA) after endogenization of the nudivirus ancestor. Here, we present the complete genome of Chelonus insularis , which is an egg-larval parasitoid in the Cheloninae that produces C. insularis BV (CinsBV). We report that the inventory of nudivirus genes in C. insularis is conserved but are dissimilarly organized compared to M. demolitor and C. congregata . Reciprocally, CinsBV proviral segments share organizational features with MdBV and CcBV but virulence gene inventories exhibit almost no overlap. Altogether, our results point to the functional importance of a conserved inventory of nudivirus genes and a dynamic set of virulence genes for the successful parasitism of hosts. Our results also suggest organizational features previously identified in MdBV and CcBV are likely not essential for BV virion formation. IMPORTANCE Bracoviruses are a remarkable example of virus endogenization, because large sets of genes from a nudivirus ancestor continue to produce virions that thousands of wasp species rely upon to parasitize hosts. Understanding how these genes interact and have been coopted by wasps for novel functions is of broad interest in the study of virus evolution. This work characterizes bracovirus genome components in the parasitoid wasp Chelonus insularis , which together with existing wasp genomes captures a large portion of the diversity among wasp species that produce bracoviruses. Results provide new information about how bracovirus genome components are organized in different wasps while also providing additional insights on key features required for function. 

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