Different transformations underlie blowhole and nasal passage development in a toothed whale (Odontoceti: Stenella attenuata) and a baleen whale (Mysticeti: Balaenoptera physalus).

Reorientation of the nasal passage away from the anteroposterior axis has evolved rarely in mammals. Unlike other mammals, cetaceans (e.g., whales, dolphins, and porpoises) have evolved a "blowhole": posteriorly repositioned nares that open dorsad. Accompanying the evolution of the blowhole, the nasal passage has rotated dorsally. Neonatal cetaceans possess a blowhole, but early in development, cetacean embryos exhibit head morphologies that resemble those of other mammals. Previous workers have proposed two developmental models for how the nasal passage reorients during prenatal ontogeny. In one model, which focused on external changes in the whole body, dorsad rotation of the head relative to the body results in dorsad rotation of the nasal passage relative to the body. A second model, based on details of the cartilaginous nasal skull, describes dorsad rotation of the nasal passage itself relative to the palate and longitudinal axis of the skull. To integrate and revise these models, we characterized both external and internal prenatal changes in a longitudinal plane that are relevant to nasal passage orientation in the body and head of the pantropical spotted dolphin (Odontoceti: Stenella attenuata). These changes were then compared to those in a prenatal series of a baleen whale, the fin whale (Mysticeti: Balaenoptera physalus), to determine if they were representative of both extant cetacean suborders. In both species, the angle between the nasal passage and the sagittal axis of the foramen magnum decreased with age. In S. attenuata, this was associated with basicranial retroflexion and midfacial lordosis: the skull appeared to fold dorsad with the presphenoid as the vertex of the angle. In contrast, in B. physalus, alignment of the nasal passage and the sagittal axis of the plane of the foramen magnum was associated with angular changes within the posterior skull (specifically, the orientations of the supraoccipital and foramen magnum relative to the posterior basicranium). With these results, we propose a new developmental model for prenatal reorientation of the odontocete nasal passage and discuss ways in which mysticetes likely deviate from this model.

Cetacean Skull Telescoping Brings Evolution of Cranial Sutures into Focus.

Many modifications to the mammalian bauplan associated with the obligate aquatic lives of cetaceans-fusiform bodies, flukes, flippers, and blowholes-are evident at a glance. But among the most strikingly unusual and divergent features of modern cetacean anatomy are the arrangements of their cranial bones: (1) bones that are situated at opposite ends of the skull in other mammals are positioned close together, their proximity resulting from (2) these bones extensively overlapping the bones that ordinarily would separate them. The term "telescoping" is commonly used to describe the odd anatomy of modern cetacean skulls, yet its usage and the particular skull features to which it refers vary widely. Placing the term in historical and biological context, this review offers an explicit definition of telescoping that includes the two criteria enumerated above. Defining telescoping in this way draws attention to many specific biological questions that are raised by the unusual anatomy of cetacean skulls; highlights the central role of sutures as the locus for changes in the sizes, shapes, mechanical properties, and connectivity of cranial bones; and emphasizes the importance of sutures in skull development and evolution. The unusual arrangements of cranial bones and sutures referred to as telescoping are not easily explained by what is known about cranial development in more conventional mammals. Discovering the evolutionary-developmental processes that produce the extensive overlap characteristic of cetacean telescoping will give insights into both cetacean evolution and the "rules" that more generally govern mammalian skull function, development, and evolution. Anat Rec, 302:1055-1073, 2019. © 2019 Wiley Periodicals, Inc.

Biodiversity and Topographic Complexity: Modern and Geohistorical Perspectives.

Topographically complex regions on land and in the oceans feature hotspots of biodiversity that reflect geological influences on ecological and evolutionary processes. Over geologic time, topographic diversity gradients wax and wane over millions of years, tracking tectonic or climatic history. Topographic diversity gradients from the present day and the past can result from the generation of species by vicariance or from the accumulation of species from dispersal into a region with strong environmental gradients. Biological and geological approaches must be integrated to test alternative models of diversification along topographic gradients. Reciprocal illumination among phylogenetic, phylogeographic, ecological, paleontological, tectonic, and climatic perspectives is an emerging frontier of biogeographic research.

The impact of large terrestrial carnivores on Pleistocene ecosystems.

Large mammalian terrestrial herbivores, such as elephants, have dramatic effects on the ecosystems they inhabit and at high population densities their environmental impacts can be devastating. Pleistocene terrestrial ecosystems included a much greater diversity of megaherbivores (e.g., mammoths, mastodons, giant ground sloths) and thus a greater potential for widespread habitat degradation if population sizes were not limited. Nevertheless, based on modern observations, it is generally believed that populations of megaherbivores (>800 kg) are largely immune to the effects of predation and this perception has been extended into the Pleistocene. However, as shown here, the species richness of big carnivores was greater in the Pleistocene and many of them were significantly larger than their modern counterparts. Fossil evidence suggests that interspecific competition among carnivores was relatively intense and reveals that some individuals specialized in consuming megaherbivores. To estimate the potential impact of Pleistocene large carnivores, we use both historic and modern data on predator-prey body mass relationships to predict size ranges of their typical and maximum prey when hunting as individuals and in groups. These prey size ranges are then compared with estimates of juvenile and subadult proboscidean body sizes derived from extant elephant growth data. Young proboscideans at their most vulnerable age fall within the predicted prey size ranges of many of the Pleistocene carnivores. Predation on juveniles can have a greater impact on megaherbivores because of their long interbirth intervals, and consequently, we argue that Pleistocene carnivores had the capacity to, and likely did, limit megaherbivore population sizes.

Mainland size variation informs predictive models of exceptional insular body size change in rodents.

The tendency for island populations of mammalian taxa to diverge in body size from their mainland counterparts consistently in particular directions is both impressive for its regularity and, especially among rodents, troublesome for its exceptions. However, previous studies have largely ignored mainland body size variation, treating size differences of any magnitude as equally noteworthy. Here, we use distributions of mainland population body sizes to identify island populations as 'extremely' big or small, and we compare traits of extreme populations and their islands with those of island populations more typical in body size. We find that although insular rodents vary in the directions of body size change, 'extreme' populations tend towards gigantism. With classification tree methods, we develop a predictive model, which points to resource limitations as major drivers in the few cases of insular dwarfism. Highly successful in classifying our dataset, our model also successfully predicts change in untested cases.

Tempo of trophic evolution and its impact on mammalian diversification.

Mammals are characterized by the complex adaptations of their dentition, which are an indication that diet has played a critical role in their evolutionary history. Although much attention has focused on diet and the adaptations of specific taxa, the role of diet in large-scale diversification patterns remains unresolved. Contradictory hypotheses have been proposed, making prediction of the expected relationship difficult. We show that net diversification rate (the cumulative effect of speciation and extinction), differs significantly among living mammals, depending upon trophic strategy. Herbivores diversify fastest, carnivores are intermediate, and omnivores are slowest. The tempo of transitions between the trophic strategies is also highly biased: the fastest rates occur into omnivory from herbivory and carnivory and the lowest transition rates are between herbivory and carnivory. Extant herbivore and carnivore diversity arose primarily through diversification within lineages, whereas omnivore diversity evolved by transitions into the strategy. The ability to specialize and subdivide the trophic niche allowed herbivores and carnivores to evolve greater diversity than omnivores.

Classification tree methods provide a multifactorial approach to predicting insular body size evolution in rodents.

Many hypotheses have been proposed to explain size changes in insular mammals, but no single variable suffices to explain the diversity of responses, particularly within Rodentia. Here in a data set on insular rodents, we observe strong consistency in the direction of size change within islands and within species but (outside of Heteromyidae) little consistency at broader taxonomic scales. Using traits of islands and of species in a classification tree analysis, we find the most important factor predicting direction of change to be mainland body mass (large rodents decrease, small ones increase); other variables (island climate, number of rodent species, and area) were significant, although their roles as revealed by the classification tree were context dependent. Ecological interactions appear relatively uninformative, and on any given island, the largest and smallest rodent species converged or diverged in size with equal frequency. Our approach provides a promising framework for continuing examination of insular body size evolution.

RNase 1 genes from the family Sciuridae define a novel rodent ribonuclease cluster.

The RNase A ribonucleases are a complex group of functionally diverse secretory proteins with conserved enzymatic activity. We have identified novel RNase 1 genes from four species of squirrel (order Rodentia, family Sciuridae). Squirrel RNase 1 genes encode typical RNase A ribonucleases, each with eight cysteines, a conserved CKXXNTF signature motif, and a canonical His(12)-Lys(41)-His(119) catalytic triad. Two alleles encode Callosciurus prevostii RNase 1, which include a Ser(18)<-->Pro, analogous to the sequence polymorphisms found among the RNase 1 duplications in the genome of Rattus exulans. Interestingly, although the squirrel RNase 1 genes are closely related to one another (77-95% amino acid sequence identity), the cluster as a whole is distinct and divergent from the clusters including RNase 1 genes from other rodent species. We examined the specific sites at which Sciuridae RNase 1s diverge from Muridae/Cricetidae RNase 1s and determined that the divergent sites are located on the external surface, with complete sparing of the catalytic crevice. The full significance of these findings awaits a more complete understanding of biological role of mammalian RNase 1s.

The effects of Cenozoic global change on squirrel phylogeny.

By modifying habitats and creating bridges and barriers between landmasses, climate change and tectonic events are believed to have important consequences for diversification of terrestrial organisms. Such consequences should be most evident in phylogenetic histories of groups that are ancient, widespread, and diverse. The squirrel family (Sciuridae) is one of very few mammalian families endemic to Eurasia, Africa, and North and South America and is ideal for examining these issues. Through phylogenetic and molecular-clock analyses, we infer that arrival and diversification of squirrels in Africa, on Sunda Shelf islands, across Beringea, and across the Panamanian isthmus coincide in timing and location with multiple well-documented sea-level, tectonic, and paleontological events. These precise correspondences point to an important role for global change in the diversification of a major group of mammals.