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1. Cretaceous and Paleocene fossils reveal an extinct higher clade within Cornales, the dogwood order

   https://doi.org/10.1002/ajb2.16372  

   Nguyen, Austin T; Atkinson, Brian A (July 2024, American Journal of Botany)

   Characterization and phylogenetic integration of fossil angiosperms with uncertain affinities is relatively limited, which may obscure the diversity of extinct higher taxa in the flowering plant tree of life. The order Cornales contains a diversity of extinct taxa with uncertain familial affinities that make it an ideal group for studying turnover in angiosperms. Here, we describe a new extinct genus of Cornales unassignable to an extant family and conduct a series of phylogenetic analyses to reconstruct relationships of fossils across the order. Two permineralized endocarps were collected from the Cedar District Formation (Campanian, 82–80 Ma) of Sucia Island, State of Washington, United States. Fossils were sectioned with the cellulose acetate peel technique and incorporated into a morphological dataset. To assess the utility of this dataset to accurately place taxa in their respective clades, we used a series of phylogenetic pseudofossilization analyses. We then conducted a total‐evidence analysis and a scaffold‐based approach to determine relationships of fossils. Based on their unique combination of characters, the fossils represent a new genus, Fenestracarpa washingtonensis gen. nov. et sp. nov. Pseudofossilization analyses indicate that our morphological dataset can be used to accurately recover taxa at the major clade to family level, generally with moderate to high support. The total‐evidence and scaffold‐based analyses recoveredFenestracarpaand other fossil genera in an entirely extinct clade within Cornales. Our findings increase the reported diversity of extinct Cornales and indicate that the order's initial radiation likely included the divergence of an extinct higher clade that endured the end‐Cretaceous Mass extinction but perished during the Cenozoic. 

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2. Phylogenomics reveals the timescale of diversification in Amblycera

   https://doi.org/10.1111/syen.12668  

   Najer, Tomáš; Doña, Jorge; Buček, Aleš; Sweet, Andrew D; Sychra, Oldřich; Johnson, Kevin P (July 2025, Systematic Entomology)

   Abstract Recently, genomic approaches have helped to resolve phylogenetic questions in many groups of parasitic organisms, including lice (Phthiraptera). However, these approaches have still not been applied to one of the most diverse groups of lice, Amblycera. To fill this gap, we applied phylogenomic methods based on genome‐level exon sequence data to resolve the relationships within and among the families of Amblycera. Our phylogenomic trees support the monophyly of the families Ricinidae and Laemobothriidae. However, the families Trimenoponidae and Gyropidae are not monophyletic, indicating that they should be merged into a single family. The placement ofTrinotonis unstable with respect to Boopiidae and Menoponidae, and we suggest recognizing Trinotonidae as a separate family. At the genus level, the generaColpocephalum,Hohorstiella,MenacanthusandRicinuswere recovered as paraphyletic. Regarding generic complexes, the tree revealed theMenacanthuscomplex to be monophyletic, but theColpocephalumcomplex paraphyletic, including genera not traditionally placed in this group. Dating analysis suggests that the divergence among families of Amblycera occurred shortly after the Cretaceous–Paleogene boundary 66 Mya. Cophylogenetic analyses revealed many host‐switching events during the diversification of Amblycera, indicating that the evolutionary history of Amblycera does not tightly mirror that of its hosts. Ancestral host reconstructions revealed that the ancestral host of Amblycera was most likely a bird, with two host switching events to mammals. By combining phylogenomics, molecular dating and cophylogenetic analyses, we provide the first large‐scale picture of amblyceran evolution, which will serve as a basis for future studies of this group. 

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3. A genomic timescale for placental mammal evolution

   https://doi.org/10.1126/science.abl8189  

   Foley, Nicole M.; Mason, Victor C.; Harris, Andrew J.; Bredemeyer, Kevin R.; Damas, Joana; Lewin, Harris A.; Eizirik, Eduardo; Gatesy, John; Karlsson, Elinor K.; Lindblad-Toh, Kerstin; et al (April 2023, Science)

   INTRODUCTION Resolving the role that different environmental forces may have played in the apparent explosive diversification of modern placental mammals is crucial to understanding the evolutionary context of their living and extinct morphological and genomic diversity. RATIONALE Limited access to whole-genome sequence alignments that sample living mammalian biodiversity has hampered phylogenomic inference, which until now has been limited to relatively small, highly constrained sequence matrices often representing <2% of a typical mammalian genome. To eliminate this sampling bias, we used an alignment of 241 whole genomes to comprehensively identify and rigorously analyze noncoding, neutrally evolving sequence variation in coalescent and concatenation-based phylogenetic frameworks. These analyses were followed by validation with multiple classes of phylogenetically informative structural variation. This approach enabled the generation of a robust time tree for placental mammals that evaluated age variation across hundreds of genomic loci that are not restricted by protein coding annotations. RESULTS Coalescent and concatenation phylogenies inferred from multiple treatments of the data were highly congruent, including support for higher-level taxonomic groupings that unite primates+colugos with treeshrews (Euarchonta), bats+cetartiodactyls+perissodactyls+carnivorans+pangolins (Scrotifera), all scrotiferans excluding bats (Fereuungulata), and carnivorans+pangolins with perissodactyls (Zooamata). However, because these approaches infer a single best tree, they mask signatures of phylogenetic conflict that result from incomplete lineage sorting and historical hybridization. Accordingly, we also inferred phylogenies from thousands of noncoding loci distributed across chromosomes with historically contrasting recombination rates. Throughout the radiation of modern orders (such as rodents, primates, bats, and carnivores), we observed notable differences between locus trees inferred from the autosomes and the X chromosome, a pattern typical of speciation with gene flow. We show that in many cases, previously controversial phylogenetic relationships can be reconciled by examining the distribution of conflicting phylogenetic signals along chromosomes with variable historical recombination rates. Lineage divergence time estimates were notably uniform across genomic loci and robust to extensive sensitivity analyses in which the underlying data, fossil constraints, and clock models were varied. The earliest branching events in the placental phylogeny coincide with the breakup of continental landmasses and rising sea levels in the Late Cretaceous. This signature of allopatric speciation is congruent with the low genomic conflict inferred for most superordinal relationships. By contrast, we observed a second pulse of diversification immediately after the Cretaceous-Paleogene (K-Pg) extinction event superimposed on an episode of rapid land emergence. Greater geographic continuity coupled with tumultuous climatic changes and increased ecological landscape at this time provided enhanced opportunities for mammalian diversification, as depicted in the fossil record. These observations dovetail with increased phylogenetic conflict observed within clades that diversified in the Cenozoic. CONCLUSION Our genome-wide analysis of multiple classes of sequence variation provides the most comprehensive assessment of placental mammal phylogeny, resolves controversial relationships, and clarifies the timing of mammalian diversification. We propose that the combination of Cretaceous continental fragmentation and lineage isolation, followed by the direct and indirect effects of the K-Pg extinction at a time of rapid land emergence, synergistically contributed to the accelerated diversification rate of placental mammals during the early Cenozoic. The timing of placental mammal evolution. Superordinal mammalian diversification took place in the Cretaceous during periods of continental fragmentation and sea level rise with little phylogenomic discordance (pie charts: left, autosomes; right, X chromosome), which is consistent with allopatric speciation. By contrast, the Paleogene hosted intraordinal diversification in the aftermath of the K-Pg mass extinction event, when clades exhibited higher phylogenomic discordance consistent with speciation with gene flow and incomplete lineage sorting. 

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4. Testudinimyces gracilis gen. nov, sp. nov. and Astrotestudinimyces divisus gen. nov, sp. nov., two novel, deep-branching anaerobic gut fungal genera from tortoise faeces

   https://doi.org/10.1099/ijsem.0.005921  

   Pratt, Carrie J.; Chandler, Emily E.; Youssef, Noha H.; Elshahed, Mostafa S. (May 2023, International Journal of Systematic and Evolutionary Microbiology)

   The anaerobic gut fungi (AGF,Neocallimastigomycota) represent a basal zoosporic phylum within the kingdomFungi. Twenty genera are currently described, all of which were isolated from the digestive tracts of mammalian herbivores. Here, we report on the isolation and characterization of novel AGF taxa from faecal samples of tortoises. Twenty-nine fungal isolates were obtained from seven different tortoise species. Phylogenetic analysis using the D1/D2 region of the LSU rRNA gene, ribosomal internal transcribed spacer 1, and RNA polymerase II large subunit grouped all isolates into two distinct, deep-branching clades (clades T and B), with a high level of sequence divergence to their closest cultured relative (Khoyollomyces ramosus). Average amino acid identity values calculated using predicted peptides from the isolates’ transcriptomes ranged between 60.80–66.21  % (clade T), and 61.24–64.83  % (clade B) when compared to all other AGF taxa; values that are significantly below recently recommended thresholds for genus (85%) and family (75%) delineation in theNeocallimastigomycota. Both clades displayed a broader temperature growth range (20–45 °C, optimal 30 °C for clade T, and 30–42 °C, optimal 39 °C for clade B) compared to all other AGF taxa. Microscopic analysis demonstrated that strains from both clades produced filamentous hyphae, polycentric rhizoidal growth patterns, and monoflagellated zoospores. Isolates in clade T were characterized by the production of unbranched, predominantly narrow hyphae, and small zoospores, while isolates in clade B were characterized by the production of multiple sporangiophores and sporangia originating from a single central swelling resulting in large multi-sporangiated structures. Based on the unique phylogenetic positions, AAI values, and phenotypic characteristics, we propose to accommodate these isolates into two novel genera (TestudinimycesandAstrotestudinimyces), and species (T. gracilisandA. divisus) within the orderNeocallimastigales. The type species are strains T130A^T(T. gracilis) and B1.1^T(A. divisus). 

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5. 50 Shades of Red: the red-reticulate group of Goniobranchus (Heterobranchia: Nudibranchia: Chromodorididae)

   Bonomo, L; Soong, GY; Reimer, J; Gosliner, T (August 2022, World Congress of Malacology Spixiana)

   The Chromodorididae family tree has been refined in recent years via molecular phylogenetic analyses which have clarified many relationships between taxa. The genus Goniobranchus is one clade within Chromodorididae that was previously included within the genus Chromodoris. However, based on recent molecular phylogenetic results, Chromodoris was determined to be non-monophyletic and Goniobranchus was resurrected. In this study, we performed molecular and morphological analyses to resolve the internal relationships among Goniobranchus species, specifically the red-reticulate species complex of three previously described species, Goniobranchus tinctorius, G. reticulatus, and G. alderi, which display a red network of lines over a white mantle and are widely distributed across the Indo-Pacific Ocean. We sequenced two mitochondrial genes (COI and 16S) and one nuclear gene (H3) for 339 Goniobranchus specimens, and in our phylogenetic analyses the red-reticulate species group emerged as a monophyly. This current work has indicated there are at least eleven distinct species within this species complex, including the only three previously described species and another described species, G. splendidus, was added to this clade. The molecular data and the morphological differences among species will be discussed, and we present a possible way forward to clarify the taxonomy of the red-reticulate species complex. 

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