Heterochronic shift in gene expression leads to ontogenetic morphological divergence between two closely related polyploid species.

Heterochrony-alteration to the rate or timing of development-is an important mechanism of trait differentiation associated with speciation. Heterochrony may explain the morphological divergence between two polyploid species, June sucker (Chasmistes liorus) and Utah sucker (Catostomus ardens). The larvae of both species have terminal mouths; however, as adults, June sucker and Utah sucker develop subterminal and ventral mouths, respectively. We document a difference in the timing of shape development and a corresponding change in the timing of gene expression, suggesting the distinctive mouth morphology in June suckers may result from paedomorphosis. Specifically, adult June suckers exhibit an intermediate mouth morphology between the larval (terminal) and ancestral (ventral) states. Endemic and sympatric Chasmistes/Catostomus pairs in two other lakes also are morphologically divergent, but genetically similar. These species pairs could have resulted from the differential expression of genes and corresponding divergence in trait development. Paedomorphosis may lead to adaptive diversification in Catostomids.

Phylogenetic relationships of three rockfish: Sebastesmelanops, Sebastesciliatus and Sebastesvariabilis (Scorpaeniformes, Scorpaenidae) based on complete mitochondrial genome sequences.

We characterise the complete mitochondrial genomes (mitogenomes) of Black rockfish (Sebastesmelanops Girard, 1856; n = 1), Dark rockfish (Sebastesciliatus Tilesius, 1813; n = 2) and Dusky rockfish (Sebastesvariabilis Pallas, 1814; n = 2). The lengths of the mitogenomes are 16,405 bp for S.melanops, 16,400 bp for both S.ciliatus and 16,400 and 16,401 bp for S.variabilis. We examine these species' phylogenetic relationships using 35 previously published rockfish mitogenomes, representing 27 species. We find that S.melanops is sister to a clade consisting of S.rubrivinctus, S.nigrocinctus, S.umbrosus and S.oculatus, whereas S.ciliatus and S.variabilis are sister to a clade consisting of S.norvegicus, S.viviparus, S.mentella and S.fasciatus. We were unable to separate S.ciliatus and S.variabilis using their complete mitogenomes.

Complete mitochondrial genomes of two rockfish: Sebastes maliger and Sebastes norvegicus (Scorpaenidae, Scorpaeniformes).

We report the complete mitochondrial genomes of two rockfish: Sebastes maliger and Sebastes norvegicus. The mitogenomes consist of 13 protein-coding regions, 22 tRNAs, two rRNAs, and one control region. Sebastes mitogenome control regions are highly variable due to the presence of repeat sequences. The mitogenomes for S. maliger and S. norvegicus are 16,403 and 16,401 bp, respectively. Using these two mitogenomes and 25 additional Sebastes mitogenomes from GenBank, we examine the phylogenetic relationships in Sebastes. Sebastes maliger is sister to a clade including S. rubrivinctus, S. nigrocinctus, S. umbrosus, and S. oculatus, while S. norvegicus is sister to S. fasciatus.

Complete mitochondrial genomes of June sucker and Utah sucker (Chasmistes liorus and Catostomus ardens).

The relationship between June sucker (Chasmistes liorus, Jordan, 1878) and Utah sucker (Catostomus ardens, Jordan & Gilbert, 1881) has been a matter of controversy since the mid 1900s. Chasmistes liorus is endemic to Utah Lake, UT and has a subterminal mouth adapted for pelagic feeding. Catostomus ardens is widely distributed throughout the Bonneville Basin and Upper Snake River Basin and has a ventral mouth adapted for benthic feeding. Chasmistes has been recognized as a separate ancient genus. Despite being morphologically distinct, no study has successfully identified residual genetic markers that separate these species. Of these studies, several have used a subset of mitochondrial genes, but no study has analyzed the complete mitochondrial genomes (mitogenomes) of these suckers (Pisces: Catostomidae). To further explore the genetic relationships between these species, we report the complete mitogenomes of Chasmistes liorus and Catostomus ardens. DNA was sequenced using an Illumina HiSeq 2500 system and mitogenomes were assembled and annotated using Geneious v. 2021.2 and MitoAnnotator, respectively. The mitogenomes of Chasmistes liorus and Catostomus ardens are both 16,623 bp and are ∼0.072% divergent. We examine the phylogenetic relationship between Chasmistes liorus and Catostomus ardens using 33 mitogenomes, representing 16 species, from Catostomidae. Our data suggest that Chasmistes liorus is sister to Catostomus ardens. Additional samples from multiple localities and/or cohorts of these species will allow us to better resolve the complicated phylogenetic relationships between these species.

Ontogenetic shape trajectory of Trichomycterus areolatus varies in response to water velocity environment.

Body and head shape among fishes both vary between environments influenced by water velocity and across ontogeny. Although the shape changes associated with variation in average water velocity and ontogeny are well documented, few studies have tested for the interaction between these two variables (i.e., does ontogenetic shape variation differ between velocity environments). We use geometric morphometrics to characterize shape differences in Trichomycterus areolatus, a freshwater catfish found in high and low-velocity environments in Chile. We identify a significant interaction between velocity environment and body size (i.e., ontogeny). Ontogenetic patterns of shape change are consistent with other studies, but velocity environment differentially affects the ontogenetic trajectory of shape development in T. areolatus. Shape change over ontogeny appears more constrained in high-velocity environments compared to low-velocity environments.

Species boundaries in the messy middle-A genome-scale validation of species delimitation in a recently diverged lineage of coastal fog desert lichen fungi.

Species delimitation among closely related species is challenging because traditional phenotype-based approaches, for example, using morphology, ecological, or chemical characteristics, may not coincide with natural groupings. With the advent of high-throughput sequencing, it has become increasingly cost-effective to acquire genome-scale data which can resolve previously ambiguous species boundaries. As the availability of genome-scale data has increased, numerous species delimitation analyses, such as BPP and SNAPP+Bayes factor delimitation (BFD*), have been developed to delimit species boundaries. However, even empirical molecular species delimitation approaches can be biased by confounding evolutionary factors, for example, hybridization/introgression and incomplete lineage sorting, and computational limitations. Here, we investigate species boundaries and the potential for micro-endemism in a lineage of lichen-forming fungi, Niebla Rundel & Bowler, in the family Ramalinaceae by analyzing single-locus and genome-scale data consisting of (a) single-locus species delimitation analysis using ASAP, (b) maximum likelihood-based phylogenetic tree inference, (c) genome-scale species delimitation models, e.g., BPP and SNAPP+BFD, and (d) species validation using the genealogical divergence index (gdi). We specifically use these methods to cross-validate results between genome-scale and single-locus datasets, differently sampled subsets of genomic data and to control for population-level genetic divergence. Our species delimitation models tend to support more speciose groupings that were inconsistent with traditional taxonomy, supporting a hypothesis of micro-endemism, which may include morphologically cryptic species. However, the models did not converge on robust, consistent species delimitations. While the results of our analysis are somewhat ambiguous in terms of species boundaries, they provide a valuable perspective on how to use these empirical species delimitation methods in a nonmodel system. This study thus highlights the challenges inherent in delimiting species, particularly in groups such as Niebla, with complex, relatively recent phylogeographic histories.