Ecosystem antifragility: beyond integrity and resilience.

We review the concept of ecosystem resilience in its relation to ecosystem integrity from an information theory approach. We summarize the literature on the subject identifying three main narratives: ecosystem properties that enable them to be more resilient; ecosystem response to perturbations; and complexity. We also include original ideas with theoretical and quantitative developments with application examples. The main contribution is a new way to rethink resilience, that is mathematically formal and easy to evaluate heuristically in real-world applications: ecosystem antifragility. An ecosystem is antifragile if it benefits from environmental variability. Antifragility therefore goes beyond robustness or resilience because while resilient/robust systems are merely perturbation-resistant, antifragile structures not only withstand stress but also benefit from it.

Environmental heterogeneity explains coarse-scale ß-diversity of terrestrial vertebrates in Mexico.

We explored the hypothesis that high ß-diversity of terrestrial vertebrates of Mexico is associated with a high environmental heterogeneity (HEH) and identify the drivers of ß-diversity at different spatial scales. We used distribution range maps of 2,513 species of amphibians, reptiles, mammals, and birds occurring in Mexico. We estimated ß-diversity for each taxon at four spatial scales (grid cells of 2°, 1°, 0.5° and 0.25°) using the multiplicative formula of Whittaker ßw. For each spatial scale, we derived 10 variables of environmental heterogeneity among cells based on raw data of temperature, precipitation, elevation, vegetation and soil. We applied conditional autoregressive models (CAR) to identify the drivers of ß-diversity for each taxon at each spatial scale. CARs increased in explanatory power from fine-to-coarse spatial scales in amphibians, reptiles and mammals. The heterogeneity in precipitation including both, coefficient of variation (CV) and range of values (ROV), resulted in the most important drivers of ß-diversity of amphibians; the heterogeneity in temperature (CV) and elevation (ROV) were the most important drivers of ß-diversity for reptiles; the heterogeneity in temperature (ROV) resulted in the most important driver in ß-diversity for mammals. For birds, CARs resulted significant at fine scales (grid cells of 0.5° and 0.25°), and the precipitation (ROV and CV), temperature (ROV), and vegetation (H) and soil (H) were heterogeneity variables retained in the model. We found support for the hypothesis of environmental heterogeneity (HEH) for terrestrial vertebrates at coarse scales (grid cell of 2°). Different variables of heterogeneity, mainly abiotic, were significant for each taxon, reflecting physiological differences among terrestrial vertebrate groups. Our study revealed the importance of mountain areas in the geographic patterns of ß-diversity of terrestrial vertebrates in Mexico. At a coarse scale, specific variables of heterogeneity can be used as a proxy of ß-diversity for amphibians and reptiles.

Diferencias intra-especie en respuesta al estrés: Hacia enfoques traslacionales / Intra-specie differences in response to stress: Looking for translational view

Resumen: El estrés produce la sobreactivación del eje HPA y sistema neuroendocrino. Se ha mostrado que existe daño en estructuras relacionadas con el procesamiento emocional (amígdala) aprendizaje (hipocampo), toma de decisiones y prospección (corteza prefrontal). Sin embargo, se generalizan los efectos del estrés sin ponderar el tipo de estrés (crónico o agudo), duración, especie, etc. Esto permite que hallazgos se contrapongan a nivel cortical, neuroquímico, hormonal y conductual. El objetivo fue evaluar los efectos del estrés crónico impredecible (ECI) en diferentes cepas de ratas y sus efectos inmediatos o a largo plazo. Se utilizaron ratas macho Wistar, Wistar Kyoto y SHR en condiciones estándar de laboratorio. Se aplicó una batería de ECI y una batería de evaluación conductual para evaluar efectos previos, agudos y crónicos. La cepa Wistar Kyoto muestra deficiencias previas a la exposición. La cepa SHR muestra mayor movilidad y sesgos atencionales, lo que produce un efecto que perdura a largo plazo. La cepa Wistar muestra una gran capacidad de adaptación ya que aunque se observaron deficiencias inmediatamente después de la exposición al estrés, éstas se recuperan e largo plazo. Se infiere que las precondiciones de los sujetos podrían funcionar como biomarcadores y poder prevenir padecimientos relacionados al estrés.

Abstract: Stress produces the over activation of the Hypothalamus Pituitary Adrenal axis (HPA) and the neuroendocrine system. It has been shown that it could damage structures related with the emotional processing (amygdala), learning and memory (Hippocampus), decision making and prospection (prefrontal cortex). However, the stress affects are generalized without weighting all the elements related with this conditions, for example the kind of stress stimuli (acute or chronic), duration, species, etc. This allowed that some findings it will go against each other in relation to cerebral cortex function, neurochemical, hormonal and behavioral. The main porpoise of this research was to evaluate the effects of the unpredictable chronic stress on several rat strains (Wistar, Wistar Kyoto and SHR) and its immediate effects or in long term so. Wistar, Wistar Kyoto and SHR rats were used. All animals were housed in standard laboratory conditions and we follow the international guide for use and care of laboratory animals. The subjects were exposed to the Chronic Unpredictable Stress Battery (CUSB) and to evaluate the stress effects all the subjects were evaluated with a Battery of Behavioral Evaluation to find the previous, immediate or the long-term effects of CUSB exposition. The Wistar Kyoto strain showed deficits before the stress exposure. Whereas the SHR rats showed more mobility and poor attention which produces a long-term effect. The Wistar strain show a high adaptation to the adverse conditions because until the animals showed strong effects immediately after the stress exposure they showed a good recovery in the long term. In conclusion we can asseverate that the preconditions in every strain plays a major role in the stress response and that preconditions it could be used as biomarkers and in that way infer if the subjects are more susceptible to suffer high stress or some other related disease.

Equilibrium of global amphibian species distributions with climate.

A common assumption in bioclimatic envelope modeling is that species distributions are in equilibrium with contemporary climate. A number of studies have measured departures from equilibrium in species distributions in particular regions, but such investigations were never carried out for a complete lineage across its entire distribution. We measure departures of equilibrium with contemporary climate for the distributions of the world amphibian species. Specifically, we fitted bioclimatic envelopes for 5544 species using three presence-only models. We then measured the proportion of the modeled envelope that is currently occupied by the species, as a metric of equilibrium of species distributions with climate. The assumption was that the greater the difference between modeled bioclimatic envelope and the occupied distribution, the greater the likelihood that species distribution would not be at equilibrium with contemporary climate. On average, amphibians occupied 30% to 57% of their potential distributions. Although patterns differed across regions, there were no significant differences among lineages. Species in the Neotropic, Afrotropics, Indo-Malay, and Palaearctic occupied a smaller proportion of their potential distributions than species in the Nearctic, Madagascar, and Australasia. We acknowledge that our models underestimate non equilibrium, and discuss potential reasons for the observed patterns. From a modeling perspective our results support the view that at global scale bioclimatic envelope models might perform similarly across lineages but differently across regions.

Habitat stability affects dispersal and the ability to track climate change.

Habitat persistence should influence dispersal ability, selecting for stronger dispersal in habitats of lower temporal stability. As standing (lentic) freshwater habitats are on average less persistent over time than running (lotic) habitats, lentic species should show higher dispersal abilities than lotic species. Assuming that climate is an important determinant of species distributions, we hypothesize that lentic species should have distributions that are closer to equilibrium with current climate, and should more rapidly track climatic changes. We tested these hypotheses using datasets from 1988 and 2006 containing all European dragon- and damselfly species. Bioclimatic envelope models showed that lentic species were closer to climatic equilibrium than lotic species. Furthermore, the models over-predicted lotic species ranges more strongly than lentic species ranges, indicating that lentic species track climatic changes more rapidly than lotic species. These results are consistent with the proposed hypothesis that habitat persistence affects the evolution of dispersal.