Redescription of the pocket gopherThomomys atrovariusfrom the Pacific coast of mainland Mexico

Multivariate analyses of skull morphology inform the taxonomy and evolution of geomyoid rodents

Morphological analyses are critical to quantify phenotypic variation, identify taxa, inform phylogenetic relationships, and shed light on evolutionary patterns. This work is particularly important in groups that display great morphological disparity. Such is the case in geomyoid rodents, a group that includes 2 of the most species-rich families of rodents in North America: the Geomyidae (pocket gophers) and the Heteromyidae (kangaroo rats, pocket mice, and their relatives). We assessed variation in skull morphology (including both shape and size) among geomyoids to test the hypothesis that there are statistically significant differences in skull measurements at the family, genus, and species levels. Our sample includes 886 specimens representing all geomyoid genera and 39 species. We used the geometric mean to compare size across taxa. We used 14 measurements of the cranium and lower jaw normalized for size to compare shape among and within taxa. Our results show that skull measurements enable the distinction of geomyoids at the family, genus, and species levels. There is a larger amount of size variation within Geomyidae than within Heteromyidae. Our phylomorphospace analysis shows that the skull shape of the common ancestor of all geomyoids was more similar to the common ancestor of heteromyids than that of geomyids. Geomyid skulls display negative allometry whereas heteromyid skulls display positive allometry. Within heteromyids, dipodomyines, and non-dipodomyines show significantly different allometric patterns. Future analyses including fossils will be necessary to test our evolutionary hypotheses.

Phylogeography and taxonomic revision of Nelson’s pocket mouse (Chaetodipus nelsoni)

Chaetodipus nelsoni occurs on rocky substrates across the Mexican Altiplano. We investigated phylogeographic diversity within the species using morphologic, karyotypic, and molecular data. Data from nuclear (AFLP) and mitochondrial DNA support three distinct genetic groups with minimal substructuring coincident with biogeographic barriers previously identified in the Chihuahuan Desert and drainage basins of the Altiplano. We examined the morphological and karyotypic data in light of the molecular data. The results support recognition of three species within the currently accepted widespread C. nelsoni: 1) C. nelsoni restricted to a distribution centered on the El Salado River Basin; 2) elevation of C. n. collis to species, with two subspecies: one centered on Trans-Pecos Texas, the other on the Mapimí Basin (new subspecies); and 3) recognition of a new species, C. durangae, centered on the Nazas Basin and upper Río Mezquital drainage.

Temporal and spatial dynamics of competitive parapatry in chewing lice

We synthesize observations from 1979 to 2016 of a contact zone involving two subspecies of pocket gophers (Thomomys bottae connectens and T. b. opulentus) and their respective chewing lice (Geomydoecus aurei and G. centralis) along the Río Grande Valley in New Mexico, U.S.A., to test predictions about the dynamics of the zone. Historically, the natural flood cycle of the Rio Grande prevented contact between the two subspecies of pocket gophers. Flood control measures completed in the 1930s permitted contact, thus establishing the hybrid zone between the pocket gophers and the contact zone between their lice (without hybridization). Since that time, the pocket gopher hybrid zone has stabilized, whereas the northern chewing louse species has replaced the southern louse species at a consistent rate of ~150 m/year. The 0.2-0.8 width of the replacement zone has remained constant, reflecting the constant rate of chewing louse species turnover on a single gopher and within a local pocket gopher population. In contrast, the full width of the replacement zone (northernmost G. centralis to southernmost G. aurei) has increased annually. By employing a variety of metrics of the species replacement zone, we are better able to understand the dynamics of interactions between and among the chewing lice and their pocket gopher hosts. This research provides an opportunity to observe active species replacement and resulting distributional shifts in a parasitic organism in its natural setting.

Phylogeographic assessment of the northern pygmy mouse, Baiomys taylori

The northern pygmy mouse, Baiomys taylori, occurs throughout the Trans-Mexican Volcanic Belt and southern Altiplano of central Mexico and extends northward in 3 projections into northern Mexico and the United States. We used mitochondrial DNA (from the cytochrome-b and NADH dehydrogenase 2 genes) and morphological data to assess diversity within B. taylori across its geographic range in relation to recognized subspecies and putative physiographic filter-barriers. Our results indicate 5 distinct mitochondrial clades despite little morphological variation across the species’ geographic range. The Sierra Madre Oriental and Sierra Madre Occidental separate clades representing the eastern (Gulf coastal lowlands), central (Altiplano), and Pacific coastal lowlands, which appear to be divided into 3 major mitochondrial clades. Based on a preliminary analysis of cranial morphology, we are able to reject the Balcones Escarpment of Texas as an impediment to the well-documented recent northern expansion of the species, while we are unable to reject a causal role of filter-barriers elsewhere in subspecific differentiation. Revision of subspecific taxonomy must await further genetic sampling, particularly along the western and southeastern portions of the species’ distribution.

El ratón pigmeo norteño, Baiomys taylori, se distribuye a través del Eje Volcánico Transmexicano y la parte sur del Altiplano del centro de México y se extiende hacia el norte de México y los Estados Unidos en tres direcciones. Utilizamos ADN mitocondrial (del citocromo-b y del gen NADH deshidrogenasa) y datos morfológicos para evaluar la diversidad dentro de B. taylori a través de su rango geográfico en relación con las subespecies reconocidas y las supuestas barreras-filtro fisiográficas. Nuestros resultados indican 5 clados mitocondriales distintos a pesar de la escasa variación morfológica a lo largo de su rango geográfico. La Sierra Madre Oriental y la Sierra Madre Occidental separan los clados representantes de las tierras bajas del este (tierras bajas del Golfo), del centro (Altiplano), y las tierras bajas del Pacífico, que parecen estar divididas en 3 clados mitocondriales principales. Basados en un análisis preliminar de la morfología craneal, pudimos rechazar el Escarpe de Balcones de Texas como un impedimento a la bien documentada expansión norteña de la especie, mientras que no fue posible rechazar el rol causal de las otras barreras-filtro en la diferenciación subespecífica. La revisión de la taxonomía subespecífica deberá esperar un mayor muestreo genético, en particular a lo largo de las porciones oeste y sureste de la distribución de la especie.