Protein biophysics explains why highly abundant proteins evolve slowly

The consistent observation across all kingdoms of life that highly abundant proteins evolve slowly demonstrates that cellular abundance is a key determinant of protein evolutionary rate. However, other empirical findings, such as the broad distribution of evolutionary rates, suggest that additional variables determine the rate of protein evolution. Here, we report that under the global selection against the cytotoxic effects of misfolded proteins, folding stability (ΔG), simultaneous with abundance, is a causal variable of evolutionary rate. Using both theoretical analysis and multiscale simulations, we demonstrate that the anticorrelation between the premutation ΔG and the arising mutational effect (ΔΔG), purely biophysical in origin, is a necessary requirement for abundance-evolutionary rate covariation. Additionally, we predict and demonstrate in bacteria that the strength of abundance-evolutionary rate correlation depends on the divergence time separating reference genomes. Altogether, these results highlight the intrinsic role of protein biophysics in the emerging universal patterns of molecular evolution.     

Extended lifespan traded for diapause in Daphnia

1. Most freshwater crustaceans of the genus Daphnia are cyclically parthenogenetic organisms that are well adapted to unstable habitats due to their short life cycle, wide phenotypic plasticity, and the ability to produce protective diapausing eggs in anticipation of environmental deterioration. Short lifespan and heterogonic reproduction are typical features of Daphnia in a broad spectrum of freshwater habitats, from small temporary pools to large permanent lakes. However, in some locations, departures may be observed from this typical life history pattern to obligate asexuality or extended lifespan. 2. A 3‐year field study in a deep ultraoligotrophic fish‐free alpine‐type lake (Czarny Staw in the Tatra mountains in southern Poland) revealed the coexistence of two closely related asexual lineages of Daphnia of the pulex complex, which differ in body colour (transparent versus orange) and in their strategies for surviving long winters. 3. The ‘transparent’ clone of European origin exhibits an ephemeral lifestyle. It completes its life cycle within a single season, forming two generations of active specimens during the short summer and producing diapausing eggs late in the season. Transparent individuals live no longer than 5–6 months in this cold lake and survive winter exclusively in the form of diapausing eggs. 4. Individuals of the ‘orange’ lineage, which are closely related to eastern Nearctic Daphnia pulicaria, exhibit a biennial lifestyle unique to this genus. They do not form diapausing eggs or produce them only occasionally. Instead, they are active throughout the year and live for up to 13–14 months. Reproduction is postponed until the second year of life when food conditions have improved. Rich lipid reserves accumulated in the first season fuel them during the long winter and permit early reproduction the following spring. 5. Possible reasons for the evolution of obligatory parthenogenesis and long lifespan in Daphnia are discussed.     

Daily changes in the sensitivity of wax-moth larvae, Galleria mellonella, to cooling stress

ABSTRACT. Sensitivity to cooling stress in the last instar larvae of Galleria mellonella was measured as (a) the number of extra larval moults, (b) the number of larvae retaining the ability to secrete silk, and (c) the number showing arrested development. With respect to (a) and (b) there were considerable differences in sensitivity across the day. A relationship was observed between the number of additional larval moults induced by chilling and the ability of prepupal larvae to spin silk: the periods during the 24 h when the most larvae passed through additional larval moults were periods characterized by the smallest number of larvae capable of spinning, and vice versa. These daily changes were apparently partly independent of developmental age. Daily variations in sensitivity also occurred when larvae of the same age were cooled at different times of day. It is suggested that these rhythms in cold-sensitivity are related to a cold-sensitive rhythm in juvenile hormone secretion, or hormone sensitivity in the tissues.     

How sympatric is speciation in the Howea palms of Lord Howe Island?

The two species of the palm genus Howea (Arecaceae) from Lord Howe Island, a minute volcanic island in the Tasman Sea, are now regarded as one of the most compelling examples of sympatric speciation, although this view is still disputed by some authors. Population genetic and ecological data are necessary to provide a more coherent and comprehensive understanding of this emerging model system. Here, we analyse data on abundance, juvenile recruitment, pollination mode and genetic variation and structure in both species. We find that Howea forsteriana is less abundant than Howea belmoreana . The genetic data based on amplified fragment length polymorphisms markers indicate similar levels of variation in the two species, despite the estimated census population size of H. belmoreana being three times larger than that of H. forsteriana . Genetic structure within species is low although some weak isolation by distance is detectable. Gene flow between species appears to be extremely limited and restricted to early-generation hybrids – only three admixed individuals, classified as F2s or first generation backcrosses to a parental species, were found among sampled palms. We conclude that speciation in Howea was indeed sympatric, although under certain strict definitions it may be called parapatric.     

Positively Selected Sites in Cetacean Myoglobins Contribute to Protein Stability

Since divergence ∼50 Ma ago from their terrestrial ancestors, cetaceans underwent a series of adaptations such as a ∼10–20 fold increase in myoglobin (Mb) concentration in skeletal muscle, critical for increasing oxygen storage capacity and prolonging dive time. Whereas the O₂-binding affinity of Mbs is not significantly different among mammals (with typical oxygenation constants of ∼0.8–1.2 µM⁻¹), folding stabilities of cetacean Mbs are ∼2–4 kcal/mol higher than for terrestrial Mbs. Using ancestral sequence reconstruction, maximum likelihood and Bayesian tests to describe the evolution of cetacean Mbs, and experimentally calibrated computation of stability effects of mutations, we observe accelerated evolution in cetaceans and identify seven positively selected sites in Mb. Overall, these sites contribute to Mb stabilization with a conditional probability of 0.8. We observe a correlation between Mb folding stability and protein abundance, suggesting that a selection pressure for stability acts proportionally to higher expression. We also identify a major divergence event leading to the common ancestor of whales, during which major stabilization occurred. Most of the positively selected sites that occur later act against other destabilizing mutations to maintain stability across the clade, except for the shallow divers, where late stability relaxation occurs, probably due to the shorter aerobic dive limits of these species. The three main positively selected sites 66, 5, and 35 undergo changes that favor hydrophobic folding, structural integrity, and intra-helical hydrogen bonds.