Colour scales with climate in North American ratsnakes: a test of the thermal melanism hypothesis using community science images.

Animal colour is a complex trait shaped by multiple selection pressures that can vary across geography. The thermal melanism hypothesis predicts that darker coloration is beneficial to animals in colder regions because it allows for more rapid solar absorption. Here, we use community science images of three closely related species of North American ratsnakes (genus Pantherophis) to examine if climate predicts colour variation across range-wide scales. We predicted that darker individuals are found in colder regions and higher elevations, in accordance with the thermal melanism hypothesis. Using an unprecedented dataset of over 8000 images, we found strong support for temperature as a key predictor of darker colour, supporting thermal melanism. We also found that elevation and precipitation are predictive of colour, but the direction and magnitude of these effects were more variable across species. Our study is the first to quantify colour variation in Pantherophis ratsnakes, highlighting the value of community science images for studying range-wide colour variation.

Chromosome-level reference genomes of two imperiled desert fishes: spikedace (Meda fulgida) and loach minnow (Tiaroga cobitis).

North American minnows (Cypriniformes: Leuciscidae) comprise a diverse taxonomic group, but many members, particularly those inhabiting deserts, face elevated extinction risks. Despite conservation concerns, leuciscids remain under sampled for reference assemblies relative to other groups of freshwater fishes. Here, we present 2 chromosome-scale reference genome assemblies spikedace (Meda fulgida) and loach minnow (Tiaroga cobitis) using PacBio, Illumina and Omni-C technologies. The complete assembly for spikedace was 882.1 Mb in total length comprised of 83 scaffolds with N50 = 34.8 Mb, L50 = 11, N75 = 32.3 Mb, and L75 = 18. The complete assembly for loach minnow was 1.3 Gb in total length comprised of 550 scaffolds with N50 = 48.6 Mb, L50 = 13, N75 = 42.3 Mb, and L75 = 20. Completeness assessed via Benchmarking Universal Single-Copy Orthologues (BUSCO) metrics using the Actinopterygii BUSCO database showed ∼97% for spikedace and ∼98% for loach minnow of complete BUSCO proportions. Annotation revealed approximately 32.58 and 29.04% of spikedace and loach minnow total genome lengths to be comprised of protein-coding genes, respectively. Comparative genomic analyses of these endangered and co-distributed fishes revealed widespread structural variants, gene family expansions, and evidence of positive selection in both genomes.

The complete mitochondrial genomes of three imperiled cyprinid fishes Bonytail (Gila elegans), Rio Grande Silvery Minnow (Hybognathus amarus) and Loach Minnow (Tiaroga cobitis).

Gila elegans, Hybognathus amarus, and Tiaroga cobitis (Family Cyprinidae, Order Cypriniformes) are endemic and endangered fishes in the southwestern United States. We present complete mitochondrial genomes for each species. Each mitochondrion consisted of 13 protein-coding genes, 2 ribosomal (rRNA) genes, 22 transfer RNA (tRNA) genes, and a single control region (D-loop), and gene order was consistent with other cyprinid fishes. Total genome lengths were 16,593 base pairs (bp) for G. elegans, 16,705 bp for H. amarus, and 16,802 for T. cobitis. The GC content in G. elegans and H. amarus was 44%, but higher in T. cobitis at 48%. Phylogenetic trees were generated to confirm relationships inferred via novel mitogenomes, and best-supported trees were consistent with previous research.

Assessment of intra and interregional genetic variation in the Eastern Red-backed Salamander, Plethodon cinereus, via analysis of novel microsatellite markers.

The red-backed salamander (Plethodon cinereus) has long-served as a model system in ecology, evolution, and behavior, and studies surveying molecular variation in this species have become increasingly common over the past decade. However, difficulties are commonly encountered when extending microsatellite markers to populations that are unstudied from a genetic perspective due to high levels of genetic differentiation across this species' range. To ameliorate this issue, we used 454 pyrosequencing to identify hundreds of microsatellite loci. We then screened 40 of our top candidate loci in populations in Virginia, Pennsylvania, and Ohio-including an isolated island population ~ 4.5 km off the shore of Lake Erie (South Bass Island). We identified 25 loci that are polymorphic in a well-studied region of Virginia and 11 of these loci were polymorphic in populations located in the genetically unstudied regions of Ohio and Pennsylvania. Use of these loci to examine patterns of variation within populations revealed that South Bass Island has low diversity in comparison to other sites. However, neither South Bass Island nor isolated populations around Cleveland are inbred. Assessment of variation between populations revealed three well defined genetic clusters corresponding to Virginia, mainland Ohio/Pennsylvania, and South Bass Island. Comparisons of our results to those of others working in various parts of the range are consistent with the idea that differentiation is lower in regions that were once glaciated. However, these comparisons also suggest that well differentiated isolated populations in the formerly glaciated portion of the range are not uncommon. This work provides novel genetic resources that will facilitate population genetic studies in a part of the red-backed salamander's range that has not previously been studied in this manner. Moreover, this work refines our understanding of how neutral variation is distributed in this ecologically important organism.