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1. Independent and repeated acquisition of Sodalis endosymbiotic bacteria across the diversification of feather lice

   https://doi.org/10.1098/rsos.251220  

   Soto-Patiño, Juliana; Walden, Kimberly_K O; Doña, Jorge; D'Alessio, Lorenzo Mario; Bush, Sarah E; Clayton, Dale H; Dale, Colin; Johnson, Kevin P (September 2025, Royal Society Open Science)

   Many parasitic insects, including lice, form close relationships with endosymbiotic bacteria that are crucial for their survival. In this study, we used genomic sequencing to investigate the distribution and evolutionary history of the bacterial genusSodalisacross a broad range of feather louse species spanning 140 genera. Phylogenomic analysis revealed significant diversity amongSodalislineages in feather lice and robust evidence for their independent and repeated acquisition by different louse clades throughout their radiation. Among the 1020 louse genomes analysed, at least 22% containedSodalis, distributed across 57 louse genera. Cophylogenetic analyses between theSodalisand feather louse phylogenies indicated considerable mismatch. This phylogenetic incongruence between lice andSodalis, along with the presence of distantly relatedSodalislineages in otherwise closely related louse species, strongly indicates repeated independent acquisition of this endosymbiont. Additionally, evidence of cospeciation among a few closely related louse species, coupled with frequent acquisition of these endosymbionts from free-living bacteria, further highlights the diverse evolutionary processes shapingSodalisendosymbiosis in feather lice. 

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2. Genome content reorganization in the non-model ciliate Chilodonella uncinata : insights into nuclear architecture, DNA content, and chromosome fragmentation during macronuclear development

   https://doi.org/10.1128/msphere.00075-25  

   Ahsan, Ragib; Maurer-Alcalá, Xyrus X; Katz, Laura A (June 2025, mSphere)

   Ciliates are a model lineage for studies of genome architecture given their unusual genome structures. All ciliates have both somatic macronuclei (MAC) and germline micronuclei (MIC), both of which develop from a zygotic nucleus following sex (i.e., conjugation). Nuclear developmental stages are not well documented among non-model ciliates, includingChilodonella uncinata(class Phyllopharyngea), the focus of our work. Here, we characterize nuclear architecture and genome dynamics inC. uncinataby combining 4′,6-diamidino-2-phenylindole (DAPI) staining and fluorescencein situhybridization (FISH) techniques with confocal microscopy. We developed a telomere probe for staining, which alongside DAPI allows for the identification of fragmented somatic chromosomes among the total DNA in the nuclei. We quantify both total DNA and telomere-bound signals from more than 250 nuclei sampled from 116 individual cells, and analyze changes in DNA content and nuclear architecture acrossChilodonella’s nuclear life cycle. Specifically, we find that MAC developmental stages in the ciliateC. uncinataare different from those reported from other ciliate species. These data provide insights into nuclear dynamics during development and enrich our understanding of genome evolution in non-model ciliates. IMPORTANCECiliates are a clade of diverse single-celled eukaryotic microorganisms that contain at least one somatic macronucleus (MAC) and germline micronucleus (MIC) within each cell/organism. Ciliates rely on complex genome rearrangements to generate somatic genomes from a zygotic nucleus. However, the development of somatic nuclei has only been documented for a few model ciliate genera, includingParamecium,Tetrahymena, andOxytricha. Here, we study the MAC developmental process in the non-model ciliate,C. uncinata. We analyze both total DNA and the generation of gene-sized somatic chromosomes using a laser scanning confocal microscope to describeC. uncinata’s nuclear life cycle. We show that DNA content changes dramatically during their life cycle and in a manner that differs from previous studies on model ciliates. Our study expands knowledge of genome dynamics in ciliates and among eukaryotes more broadly. 

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3. Genomic, transcriptomic and epigenomic signatures of ageing and cold adaptation in the Antarctic clam Laternula elliptica

   https://doi.org/10.1098/rsob.250009  

   Sleight, Victoria A; Clark, Melody S; Yap-Chiongco, Meghan K; Turner, Frances; Kocot, Kevin M (May 2025, Open Biology)

   Genomic data are lacking for most Antarctic marine invertebrates, predicating our ability to understand physiological adaptation and specific life-history traits, such as longevity. The environmental stress response of the Antarctic infaunal clamLaternula ellipticais much diminished in older adult animals compared with younger juvenile individuals. However, the mechanism underlying this reduced capacity is unknown. In this study, we describe and analyse the genome ofL. ellipticaand use it as a tool to understand transcriptomic responses to shell damage across different age cohorts. Gene expression data were combined with reduced representation enzymic methyl sequencing to identify if methylation was acting as an epigenetic mechanism driving age-dependent transcriptional profiles. Our transcriptomic results demonstrated a clear bipartite molecular response inL. elliptica, associated with a rapid growth phase in juveniles and a stabilization phase in reproductively mature adults. Genes active in the response to damage repair in juvenile animals are silent in adults but can be reactivated after several months following damage stimulus; however, these genes were not methylated. Hence, the trigger for this critical and imprinted change in physiological state is, as yet, unknown. While epigenetics is likely involved in this process, the mechanism is unlikely to be methylation. 

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4. Haloferax volcanii : a versatile model for studying archaeal biology

   https://doi.org/10.1128/jb.00062-25  

   Pohlschroder, Mechthild; Schulze, Stefan; Pfeiffer, Friedhelm; Hong, Yirui (June 2025, Journal of Bacteriology)

   Maupin-Furlow, Julie A (Ed.)

   ABSTRACT Archaea, once thought limited to extreme environments, are now recognized as ubiquitous and fundamental players in global ecosystems. While morphologically similar to bacteria, they are a distinct domain of life and are evolutionarily closer to eukaryotes. The development of model archaeal systems has facilitated studies that have underscored unique physiological, biochemical, and genetic characteristics of archaea.Haloferax volcaniistands out as a model archaeon due to its ease of culturing, ability to grow on defined media, amenability to genetic and biochemical methods, as well as the support from a highly collaborative community. This haloarchaeon has been instrumental in exploring diverse aspects of archaeal biology, ranging from polyploidy, replication origins, and post-translational modifications to cell surface biogenesis, metabolism, and adaptation to high-salt environments. The extensive use ofHfx. volcaniifurther catalyzed the development of new technologies and databases, facilitating discovery-driven research that offers significant implications for biotechnology, biomedicine, and core biological questions. 

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5. Euprymna berryi as a comparative model host for Vibrio fischeri light organ symbiosis

   https://doi.org/10.1128/aem.00001-25  

   Imes, Avery M; Pavelsky, Morgan N; Badal, Klodia; Kamp, Derrick L; Briseño, John L; Sakmar, Taylor; Vogt, Miranda A; Nyholm, Spencer V; Heath-Heckman, Elizabeth_A C; Grasse, Bret; et al (July 2025, Applied and Environmental Microbiology)

   Rudi, Knut (Ed.)

   ABSTRACT Functional studies of host-microbe interactions benefit from natural model systems that enable the exploration of molecular mechanisms at the host-microbe interface. BioluminescentVibrio fischericolonize the light organ of the Hawaiian bobtail squid,Euprymna scolopes, and this binary model has enabled advances in understanding host-microbe communication, colonization specificity,in vivobiofilms, intraspecific competition, and quorum sensing. The hummingbird bobtail squid,Euprymna berryi,can be generationally bred and maintained in lab settings and has had multiple genes deleted by CRISPR approaches. The prospect of expanding the utility of the light organ model system by producing multigenerational host lines led us to determine the extent to which theE. berryilight organ symbiosis parallels known processes inE. scolopes. However, the nature of theE. berryilight organ, including its microbial constituency and specificity for microbial partners, has not been examined. In this report, we isolated bacteria fromE. berryianimals and tank water. Assays of bacterial behaviors required in the host, as well as host responses to bacterial colonization, illustrate largely parallel phenotypes inE. berryiandE. scolopeshatchlings. This study revealsE. berryito be a valuable comparative model to complement studies inE. scolopes.IMPORTANCEMicrobiome studies have been substantially advanced by model systems that enable functional interrogation of the roles of the partners and the molecular communication between those partners. TheEuprymna scolopes-Vibrio fischerisystem has contributed foundational knowledge, revealing key roles for bacterial quorum sensing broadly and in animal hosts, for bacteria in stimulating animal development, for bacterial motility in accessing host sites, and forin vivobiofilm formation in development and specificity of an animal’s microbiome.Euprymna berryiis a second bobtail squid host, and one that has recently been shown to be robust to laboratory husbandry and amenable to gene knockout. This study identifiesE. berryias a strong symbiosis model host due to features that are conserved with those ofE. scolopes, which will enable the extension of functional studies in bobtail squid symbioses. 

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