The Effects of Temperature on Political Violence: Global Evidence at the Subnational Level

A number of studies have demonstrated an empirical relationship between higher ambient temperatures and substate violence, which have been extrapolated to make predictions about the security implications of climate change. This literature rests on the untested assumption that the mechanism behind the temperature-conflict link is that disruption of agricultural production provokes local violence. Using a subnational-level dataset, this paper demonstrates that the relationship: (1) obtains globally, (2) exists at the substate level — provinces that experience positive temperature deviations see increased conflict; and (3) occurs even in regions without significant agricultural production. Diminished local farm output resulting from elevated temperatures is unlikely to account for the entire increase in substate violence. The findings encourage future research to identify additional mechanisms, including the possibility that a substantial portion of the variation is brought about by the well-documented direct effects of temperature on individuals'' propensity for violence or through macroeconomic mechanisms such as food price shocks.     

Disentangling the Evolution of Early and Late Life History Traits in Humans

Some aspects of human life history are unique among primates. Most notably, humans have a younger weaning age, a later age at first parturition, a shorter female reproductive period, and a longer lifespan than other living hominoid species. Obtaining a better understanding of when and how life history changed during human evolution is important to those studying the evolutionary developmental biology of extinct hominins, as life history traits pace developmental processes. Life history traits are thought to be linked via tradeoffs, such that changes in early life history traits directly affect those that follow later in life, and vice versa. However, it is also worth considering how changes to a single life history trait may indirectly affect other traits by way of modifying selective pressures acting on individuals and groups. For example, because they affect the size and demographic structure of a group, late life history traits (e.g., lifespan) may also affect the evolution of life history traits that occur earlier in life, but by modifying selective pressures acting on juveniles rather than by triggering a physiological tradeoff. This review marks an effort to begin to disentangle the ways in which early and late life history traits may affect each other both directly and indirectly. We concentrate on female life history characteristics. First, we review previous research on the evolution of the postmenopausal lifespan in women. Next we discuss recent findings concerning the relationship between the optimal length of the female reproductive period, mortality, and weaning age that show that selection favors a shorter female reproductive period in the presence of a younger weaning age. We discuss the implications this finding holds for understanding the evolution of life history traits that are of particular interest to developmental biologists.     

Thermal Reaction Norms and the Scale of Temperature Variation: Latitudinal Vulnerability of Intertidal Nacellid Limpets to Climate Change

The thermal reaction norms of 4 closely related intertidal Nacellid limpets, Antarctic (Nacella concinna), New Zealand (Cellana ornata), Australia (C. tramoserica) and Singapore (C. radiata), were compared across environments with different temperature magnitude, variability and predictability, to test their relative vulnerability to different scales of climate warming. Lethal limits were measured alongside a newly developed metric of “duration tenacity”, which was tested at different temperatures to calculate the thermal reaction norm of limpet adductor muscle fatigue. Except in C. tramoserica which had a wide optimum range with two break points, duration tenacity did not follow a typical aerobic capacity curve but was best described by a single break point at an optimum temperature. Thermal reaction norms were shifted to warmer temperatures in warmer environments; the optimum temperature for tenacity (T_opt) increased from 1.0°C (N. concinna) to 14.3°C (C. ornata) to 18.0°C (an average for the optimum range of C. tramoserica) to 27.6°C (C. radiata). The temperature limits for duration tenacity of the 4 species were most consistently correlated with both maximum sea surface temperature and summer maximum in situ habitat logger temperature. Tropical C. radiata, which lives in the least variable and most predictable environment, generally had the lowest warming tolerance and thermal safety margin (WT and TSM; respectively the thermal buffer of CT_max and T_opt over habitat temperature). However, the two temperate species, C. ornata and C. tramoserica, which live in a variable and seasonally unpredictable microhabitat, had the lowest TSM relative to in situ logger temperature. N. concinna which lives in the most variable, but seasonally predictable microhabitat, generally had the highest TSMs. Intertidal animals live at the highly variable interface between terrestrial and marine biomes and even small changes in the magnitude and predictability of their environment could markedly influence their future distributions.     

Molecular Evolution of Aminoacyl tRNA Synthetase Proteins in the Early History of Life

Aminoacyl-tRNA synthetases (aaRS) consist of several families of functionally conserved proteins essential for translation and protein synthesis. Like nearly all components of the translation machinery, most aaRS families are universally distributed across cellular life, being inherited from the time of the Last Universal Common Ancestor (LUCA). However, unlike the rest of the translation machinery, aaRS have undergone numerous ancient horizontal gene transfers, with several independent events detected between domains, and some possibly involving lineages diverging before the time of LUCA. These transfers reveal the complexity of molecular evolution at this early time, and the chimeric nature of genomes within cells that gave rise to the major domains. Additionally, given the role of these protein families in defining the amino acids used for protein synthesis, sequence reconstruction of their pre-LUCA ancestors can reveal the evolutionary processes at work in the origin of the genetic code. In particular, sequence reconstructions of the paralog ancestors of isoleucyl- and valyl- RS provide strong empirical evidence that at least for this divergence, the genetic code did not co-evolve with the aaRSs; rather, both amino acids were already part of the genetic code before their cognate aaRSs diverged from their common ancestor. The implications of this observation for the early evolution of RNA-directed protein biosynthesis are discussed.     

Difference between Ion Levels in the Blood of the Brown Trout Salmo trutta from Two Closely Located Rivers before Smoltification

Biology Bulletin - The concentrations of Cl–, Ca2+, Na+, and K+ in the blood of the brown trout Salmo trutta from two rivers of the Lake Ladoga basin (Alatsoya and Ulmasenjoki) are compared....     

Life at the extreme: lessons from the genome

Extremophile plants thrive in places where most plant species cannot survive. Recent developments in high-throughput technologies and comparative genomics are shedding light on the evolutionary mechanisms leading to their adaptation.     

Cholesterol Function in Plasma Membranes from Ectotherms: Membrane-Specific Roles in Adaptation to Temperature

SYNOPSIS. Cholesterol is an essential component in the plasmamembranes of animals with multiple effects on the physical propertiesof membranes including membrane order (fluidity), phase behavior,thickness, and permeability. Cholesterol also affects functionalattributes of cell membranes such as the activities of variousintegral proteins. Because cholesterol provides rigidity tofluid phase membranes, it is a likely candidate to counter someof the temperature-induced perturbations in membrane order thatwould otherwise be experienced by animals that live at variedbody temperatures. If cholesterol contributes to homeoviscousadaptation (HVA), more cholesterol is likely to be present inplasma membranes from warm-bodied animals than from cold-bodiedanimals. This prediction is generally supported by studies examiningcholesterol contents in membranes from endothermic and ectothermicanimals. Comparisons of cholesterol levels in temperature acclimated(oracclimatized) ectotherms reveal an increase in cholesterolwith temperature, no change in cholesterol content, or an increasein cholesterol with a decrease in temperature. These differentpatterns largely represent tissue and regional differences inthe membranes (membrane domains). The membranespecific natureof the cholesterol response to temperature is likely to arisefrom the multiplicity of the effects that cholesterol exertson membranes, as well as the heterogenous nature of plasma membranes.These factors also allow cholesterol to perform more than asingle role in temperature adaptation of plasma membranes inanimals.     

Animal-Bacterial Interactions in the Early Life History of Marine Invertebrates: The Euprymna scolopes/Vibrio fischeri Symbiosis

SYNOPSIS. The symbiotic association between the Hawaiian sepiolidsquid Euprymna scolopes and the marine luminous bacterium Vibriofischeri is being developed as a model system for the studyof animal-bacterial interactions during development. Changesin light organ morphology during embryogenesis foster successfulinfection of the light organ with the proper bacterial partner.These embryonic events of light organ morphogenesis includethe elaboration of an epithelial surface with a complex ciliated,microvillous field. The squid host hatches without the bacterialsymbionts, but acquires them within hours from the free-livingpopulation of the bacteria in the water column. Upon exposureto the proper symbionts, the host organ undergoes a series ofmorphogenetic changes, including loss of the ciliated, microvillousfield. The light organ then goes on to mature into a morphologicalconfiguration that serves to promotethe maintenance of a stableassociation with the bacteria and that correlates with the useof the bacterial bioluminescence in behavior of the host. Thissymbiosis is discussed in light of other cyclically transmittedanimal-bacterial associations.     

Niche Partitioning in Sympatric Gorilla and Pan from Cameroon: Implications for Life History Strategies and for Reconstructing the Evolution of Hominin Life History

Factors influencing the hominoid life histories are poorly understood, and little is known about how ecological conditions modulate the pace of their development. Yet our limited understanding of these interactions underpins life history interpretations in extinct hominins. Here we determined the synchronisation of dental mineralization/eruption with brain size in a 20^th century museum collection of sympatric Gorilla gorilla and Pan troglodytes from Central Cameroon. Using δ¹³C and δ¹⁵N of individuals’ hair, we assessed whether and how differences in diet and habitat use may have impacted on ape development. The results show that, overall, gorilla hair δ¹³C and δ¹⁵N values are more variable than those of chimpanzees, and that gorillas are consistently lower in δ¹³C and δ¹⁵N compared to chimpanzees. Within a restricted, isotopically-constrained area, gorilla brain development appears delayed relative to dental mineralization/eruption [or dental development is accelerated relative to brains]: only about 87.8% of adult brain size is attained by the time first permanent molars come into occlusion, whereas it is 92.3% in chimpanzees. Even when M1s are already in full functional occlusion, gorilla brains lag behind those of chimpanzee (91% versus 96.4%), relative to tooth development. Both bootstrap analyses and stable isotope results confirm that these results are unlikely due to sampling error. Rather, δ¹⁵N values imply that gorillas are not fully weaned (physiologically mature) until well after M1 are in full functional occlusion. In chimpanzees the transition from infant to adult feeding appears (a) more gradual and (b) earlier relative to somatic development. Taken together, the findings are consistent with life history theory that predicts delayed development when non-density dependent mortality is low, i.e. in closed habitats, and with the “risk aversion” hypothesis for frugivorous species as a means to avert starvation. Furthermore, the results highlight the complexity and plasticity of hominoid/hominin development.     

Adaptation in Toxic Environments: Arsenic Genomic Islands in the Bacterial Genus Thiomonas

Acid mine drainage (AMD) is a highly toxic environment for most living organisms due to the presence of many lethal elements including arsenic (As). Thiomonas (Tm.) bacteria are found ubiquitously in AMD and can withstand these extreme conditions, in part because they are able to oxidize arsenite. In order to further improve our knowledge concerning the adaptive capacities of these bacteria, we sequenced and assembled the genome of six isolates derived from the Carnoulès AMD, and compared them to the genomes of Tm. arsenitoxydans 3As (isolated from the same site) and Tm. intermedia K12 (isolated from a sewage pipe). A detailed analysis of the Tm. sp. CB2 genome revealed various rearrangements had occurred in comparison to what was observed in 3As and K12 and over 20 genomic islands (GEIs) were found in each of these three genomes. We performed a detailed comparison of the two arsenic-related islands found in CB2, carrying the genes required for arsenite oxidation and As resistance, with those found in K12, 3As, and five other Thiomonas strains also isolated from Carnoulès (CB1, CB3, CB6, ACO3 and ACO7). Our results suggest that these arsenic-related islands have evolved differentially in these closely related Thiomonas strains, leading to divergent capacities to survive in As rich environments.     

Local Mechanical Stimuli Regulate Bone Formation and Resorption in Mice at the Tissue Level

Bone is able to react to changing mechanical demands by adapting its internal microstructure through bone forming and resorbing cells. This process is called bone modeling and remodeling. It is evident that changes in mechanical demands at the organ level must be interpreted at the tissue level where bone (re)modeling takes place. Although assumed for a long time, the relationship between the locations of bone formation and resorption and the local mechanical environment is still under debate. The lack of suitable imaging modalities for measuring bone formation and resorption in vivo has made it difficult to assess the mechanoregulation of bone three-dimensionally by experiment. Using in vivo micro-computed tomography and high resolution finite element analysis in living mice, we show that bone formation most likely occurs at sites of high local mechanical strain (p<0.0001) and resorption at sites of low local mechanical strain (p<0.0001). Furthermore, the probability of bone resorption decreases exponentially with increasing mechanical stimulus (R² = 0.99) whereas the probability of bone formation follows an exponential growth function to a maximum value (R² = 0.99). Moreover, resorption is more strictly controlled than formation in loaded animals, and ovariectomy increases the amount of non-targeted resorption. Our experimental assessment of mechanoregulation at the tissue level does not show any evidence of a lazy zone and suggests that around 80% of all (re)modeling can be linked to the mechanical micro-environment. These findings disclose how mechanical stimuli at the tissue level contribute to the regulation of bone adaptation at the organ level.     

The Effects of Evolution are Local: Evidence from Experimental Evolution in Drosophila

One of the enduring temptations of evolutionary theory is theextrapolation from short-term to long-term, from a few speciesto all species. Unfortunately, the study of experimental evolutionreveals that extrapolation from local to general patterns ofevolution is not usually successful. The present article supportsthis conclusion using evidence from the experimental evolutionof life-history in Drosophila. The following factors demonstrablyundermine evolutionary correlations between functional characters:inbreeding, genotype-by-environment interaction, novel fociof selection, long-term selection, and alternative genetic backgrounds.The virtual certainty that at least one of these factors willarise during evolution shreds the prospects for global theoriesof the effects of adaptation. The effects of evolution apparentlydon't generalize, even though evolution is a global process.