Extreme elevational migration spurred cryptic speciation in giant hummingbirds.

The ecoevolutionary drivers of species niche expansion or contraction are critical for biodiversity but challenging to infer. Niche expansion may be promoted by local adaptation or constrained by physiological performance trade-offs. For birds, evolutionary shifts in migratory behavior permit the broadening of the climatic niche by expansion into varied, seasonal environments. Broader niches can be short-lived if diversifying selection and geography promote speciation and niche subdivision across climatic gradients. To illuminate niche breadth dynamics, we can ask how "outlier" species defy constraints. Of the 363 hummingbird species, the giant hummingbird (Patagona gigas) has the broadest climatic niche by a large margin. To test the roles of migratory behavior, performance trade-offs, and genetic structure in maintaining its exceptional niche breadth, we studied its movements, respiratory traits, and population genomics. Satellite and light-level geolocator tracks revealed an >8,300-km loop migration over the Central Andean Plateau. This migration included a 3-wk, ~4,100-m ascent punctuated by upward bursts and pauses, resembling the acclimatization routines of human mountain climbers, and accompanied by surging blood-hemoglobin concentrations. Extreme migration was accompanied by deep genomic divergence from high-elevation resident populations, with decisive postzygotic barriers to gene flow. The two forms occur side-by-side but differ almost imperceptibly in size, plumage, and respiratory traits. The high-elevation resident taxon is the world's largest hummingbird, a previously undiscovered species that we describe and name here. The giant hummingbirds demonstrate evolutionary limits on niche breadth: when the ancestral niche expanded due to evolution (or loss) of an extreme migratory behavior, speciation followed.

Rapid turnover of a pea aphid superclone mediated by thermal endurance in central Chile.

Global change drivers are imposing novel conditions on Earth's ecosystems at an unprecedented rate. Among them, biological invasions and climate change are of critical concern. It is generally thought that strictly asexual populations will be more susceptible to rapid environmental alterations due to their lack of genetic variability and, thus, of adaptive responses. In this study, we evaluated the persistence of a widely distributed asexual lineage of the alfalfa race of the pea aphid, Acyrthosiphon pisum, along a latitudinal transect of approximately 600 km in central Chile after facing environmental change for a decade. Based on microsatellite markers, we found an almost total replacement of the original aphid superclone by a new variant. Considering the unprecedented warming that this region has experienced in recent years, we experimentally evaluated the reproductive performance of these two A. pisum lineages at different thermal regimes. The new variant exhibits higher rates of population increase at warmer temperatures, and computer simulations employing a representative temperature dataset suggest that it might competitively displace the original superclone. These results support the idea of a superclone turnover mediated by differential reproductive performance under changing temperatures.

Phenotypic plasticity is not a cline: Thermal physiology of an intertidal barnacle over 20° of latitude.

Our understanding of the plastic and evolutionary potential of ectothermic organisms and their populational impacts in the face of rapid global change remains limited. Studies attempting on the relationship between the magnitude of thermal variability across latitude and the degree of phenotypic plasticity exhibited by marine ectotherms are inconclusive. We state that the latter arises from the narrow range of thermal variability captured by the limited span of the latitudinal gradients studied to date. Using a mechanistic ecophysiological approach and a satellite-based assessment of the relevant environmental variables (i.e. temperature and food availability), we studied individuals of the intertidal barnacle Jehlius cirratus from seven local populations widely spread along the Humboldt current system that spanning two biogeographic regions. At the same time, we synthesized published information on the local abundance of our study species across a total of 76 sites representing 20° of latitude, and spanning from 18 to 42°S. We examined the effects of latitude and environmental variability on metabolic rate plasticity, thermal tolerance (thermal breadth and thermal safety margins) and their impacts on the abundance of this widespread marine invertebrate. We demonstrate that the phenotypic plasticity of metabolic rate in J. cirratus populations is not related to latitude. In turn, thermal breadth is explained by the temperature variability each population experiences. Furthermore, we found clinal variation with a poleward decrease of the critical thermal minimum, suggesting that episodic extreme low temperatures represent a ubiquitous selective force on the lower thermal limit for ectotherms. Across our study gradient, plasticity patterns indicate that populations at the equatorial extreme are more vulnerable to a warming climate, while populations located in the biogeographic transitional zone (i.e. high environmental heterogeneity), on the centre of the gradient, display higher levels of phenotypic plasticity and may represent a genetic buffer for the effects of ocean warming. Together, our results suggest the existence of a fitness trade-off involving the metabolic cost of plasticity and population density that is evident only across the vast latitudinal gradient examined.

Nuestro conocimiento del potencial plástico y evolutivo de organismos ectotérmicos y de los posibles impactos poblacionales a la luz del rápido cambio global sigue siendo limitado. Los estudios que relacionan la magnitud de la variabilidad térmica y el grado de plasticidad fenotípica a través de la latitud realizados en organismos ectotérmicos marinos no son concluyentes. Lo anterior creemos que es consecuencia del estrecho rango latitudinal y por consecuencia el menor rango de variabilidad térmica abarcado por los estudios previos. Utilizando un enfoque ecofisiológico mecanicista e información satelital de las variables ambientales relevantes (i.e., temperatura y disponibilidad de alimento), estudiamos individuos del cirripedio intermareal Jehlius cirratus a lo largo de siete poblaciones locales que se distribuyen ampliamente a lo largo del Sistema de la corriente de Humboldt abarcando dos regiones biogeográficas. Al mismo tiempo, sintetizamos la información publicada sobre la abundancia local de nuestro modelo de estudio en un total de 76 sitios que representan 20 grados de latitud y abarcan desde los 18° a los 42°S. Examinamos los efectos de la latitud y la variabilidad ambiental en la plasticidad de la tasa metabólica, la tolerancia térmica (i.e. amplitud térmica y márgenes de seguridad térmica) y los impactos en la abundancia de este invertebrado marino con amplia distribución geográfica. Demostramos que la plasticidad fenotípica de la tasa metabólica en poblaciones de J. cirratus no está relacionada con la latitud. A su vez, la amplitud térmica se explica por la variabilidad térmica que cada población experimenta. Además, encontramos un patrón de variación clinal con una disminución hacia los polos del crítico térmico mínimo, lo que sugiere que las temperaturas episódicas extremadamente bajas representan una fuerza selectiva ubicua en el límite térmico inferior para los ectotermos. A lo largo de nuestro gradiente estudiado, los patrones de plasticidad indican que las poblaciones en el extremo ecuatorial son más vulnerables al calentamiento, mientras que las poblaciones ubicadas en la zona de transición biogeográfica (i.e., alta heterogeneidad ambiental), en el centro del gradiente, muestran mayores niveles de plasticidad fenotípica, lo que puede representar un reservorio genético para los efectos del calentamiento de los océanos. Nuestros resultados sugieren la existencia de un compromiso en la adecuación biológica que involucra el costo metabólico de la plasticidad y la densidad de población que es sólo evidente dado el vasto gradiente latitudinal examinado.

Selfing and Drought-Stress Strategies Under Water Deficit for Two Herbaceous Species in the South American Andes.

Angiosperms are highly diverse in their reproductive systems, including predominantly selfing, exclusive outcrossing, and mixed mating systems. Even though selfing can have negative consequences on natural populations, it has been proposed that plants having a predominantly selfing strategy are also associated with fast development strategies through time limitation mechanisms that allow them to complete their life cycle before the onset of severe drought. This relationship might be affected by the challenges imposed by global change, such as a decrease in pollinator availability and the earlier and more severe onset of droughts. In this work, our aim was to investigate whether selfing is correlated with a dehydration avoidance strategy, and how this could affect drought resistance and survival in two species with different types of selfing: pollinator-independent delayed selfing (Schizanthus grahamii) and pollinator-dependent selfing (Schizanthus hookeri), representing a gradient in selfing rates. We hypothesize that delayed selfing species and highly selfing populations will show "fast" plant traits whereas we will find no pattern in more outcrossed populations of the pollinator-dependent species. However, we predicted that high selfing populations would have lower survival rates when exposed to chronic drought early in their development since fast traits imply physiological compromises that will affect their drought survival. To evaluate these hypotheses, we characterized different physiological and morphological traits in response to two contrasting treatments (moist and dry) in a total of six populations of the two species. We found a relationship between the delayed selfing species and a dehydration avoidance strategy and also with low drought survival. Our work offers evidence to support the importance of abiotic factors, such as drought, on the possible variation in selfing rates on natural populations, and the effect that this mating system could have in their ability to face new environmental conditions such as those imposed by climate change.