The effect of trait type and strength of selection on heritability and evolvability in an island bird population

The heritability (h²) of fitness traits is often low. Although this has been attributed to directional selection having eroded genetic variation in direct proportion to the strength of selection, heritability does not necessarily reflect a trait's additive genetic variance and evolutionary potential (“evolvability”). Recent studies suggest that the low h² of fitness traits in wild populations is caused not by a paucity of additive genetic variance (V_A) but by greater environmental or nonadditive genetic variance (V_R). We examined the relationship between h² and variance‐standardized selection intensities (i or β_σ), and between evolvability (I_A:V_A divided by squared phenotypic trait mean) and mean‐standardized selection gradients (β_μ). Using 24 years of data from an island population of Savannah sparrows, we show that, across diverse traits, h² declines with the strength of selection, whereas I_A and I_R (V_R divided by squared trait mean) are independent of the strength of selection. Within trait types (morphological, reproductive, life‐history), h², I_A, and I_R are all independent of the strength of selection. This indicates that certain traits have low heritability because of increased residual variance due to the age at which they are expressed or the multiple factors influencing their expression, rather than their association with fitness.     

Whole-body angular momentum during stair walking using passive and powered lower-limb prostheses*

Individuals with a unilateral transtibial amputation have a greater risk of falling compared to able-bodied individuals, and falling on stairs can lead to serious injuries. Individuals with transtibial amputations have lost ankle plantarflexor muscle function, which is critical for regulating whole-body angular momentum to maintain dynamic balance. Recently, powered prostheses have been designed to provide active ankle power generation with the goal of restoring biological ankle function. However, the effects of using a powered prosthesis on the regulation of whole-body angular momentum are unknown. The purpose of this study was to use angular momentum to evaluate dynamic balance in individuals with a transtibial amputation using powered and passive prostheses relative to able-bodied individuals during stair ascent and descent. Ground reaction forces, external moment arms, and joint powers were also investigated to interpret the angular momentum results. A key result was that individuals with an amputation had a larger range of sagittal-plane angular momentum during prosthetic limb stance compared to able-bodied individuals during stair ascent. There were no significant differences in the frontal, transverse, or sagittal-plane ranges of angular momentum or maximum magnitude of the angular momentum vector between the passive and powered prostheses during stair ascent or descent. These results indicate that individuals with an amputation have altered angular momentum trajectories during stair walking compared to able-bodied individuals, which may contribute to an increased fall risk. The results also suggest that a powered prosthesis provides no distinct advantage over a passive prosthesis in maintaining dynamic balance during stair walking.     

Iron Regulatory Protein-1 Protects against Mitoferrin-1-deficient Porphyria

Mitochondrial iron is essential for the biosynthesis of heme and iron-sulfur ([Fe-S]) clusters in mammalian cells. In developing erythrocytes, iron is imported into the mitochondria by MFRN1 (mitoferrin-1, SLC25A37). Although loss of MFRN1 in zebrafish and mice leads to profound anemia, mutant animals showed no overt signs of porphyria, suggesting that mitochondrial iron deficiency does not result in an accumulation of protoporphyrins. Here, we developed a gene trap model to provide in vitro and in vivo evidence that iron regulatory protein-1 (IRP1) inhibits protoporphyrin accumulation. Mfrn1^+/gt;Irp1^−/− erythroid cells exhibit a significant increase in protoporphyrin levels. IRP1 attenuates protoporphyrin biosynthesis by binding to the 5′-iron response element (IRE) of alas2 mRNA, inhibiting its translation. Ectopic expression of alas2 harboring a mutant IRE, preventing IRP1 binding, in Mfrn1^gt/gt cells mimics Irp1 deficiency. Together, our data support a model whereby impaired mitochondrial [Fe-S] cluster biogenesis in Mfrn1^gt/gt cells results in elevated IRP1 RNA-binding that attenuates ALAS2 mRNA translation and protoporphyrin accumulation.     

Mismatch Recognition Protein MutS�� Does Not Hijack (CAG)n Hairpin Repair in Vitro

CAG repeats form stable hairpin structures, which are believed to be responsible for CAG repeat expansions associated with certain human neurological diseases. Human cells possess an accurate DNA hairpin repair system that prevents expansion of disease-associated CAG repeats. Based on transgenic animal studies, it is suggested that (CAG)_n expansion is caused by abnormal binding of the MutSβ mismatch recognition protein to (CAG)_n hairpins, leading to hijacking mismatch repair function during (CAG)_n hairpin repair. We demonstrate here that MutSβ displays identical biochemical and biophysical activities (including ATP-provoked conformational change, ATPase, ATP binding, and ADP binding) when interacting with a (CAG)_n hairpin and a mismatch. More importantly, our in vitro functional hairpin repair assays reveal that excess MutSβ does not inhibit (CAG)_n hairpin repair in HeLa nuclear extracts. Evidence presented here provides a novel view as to whether or not MutSβ is involved in CAG repeat instability in humans.Expansion of trinucleotide repeats (TNRs)³ causes hereditary neurological disorders such as Huntington disease and myotonic dystrophy, whose clinical symptoms are directly linked to expansion of CAG and CTG repeats, respectively (1–3). The precise mechanisms by which TNR expansion occurs and the factors that promote it are not fully understood. It has been proposed that CAG and CTG repeats form thermostable hairpins that include A-A and T-T mispairs in the hairpin stem (4, 5). Therefore, cellular mechanisms that process DNA hairpin/loop structures and/or A-A or T-T mispairs may influence TNR stability.Recent studies have identified and characterized a DNA hairpin repair (HPR) system in human cells that promotes CAG/CTG repeat stability (6, 7). The mechanism of human HPR involves incision and removal of CAG/CTG repeat hairpins in a nick-directed and proliferating cell nuclear antigen-dependent manner, followed by DNA resynthesis using the continuous strand as a template (6). In addition to human HPR, the human mismatch repair (MMR) system is well known for its role in stabilizing simple repetitive sequences called microsatellites, which are prone to forming small loops or insertion/deletion (ID) mispairs. In human cells, MutSα (MSH2–MSH6) and MutSβ (MSH2–MSH3) both bind to 1–2-nt ID mispairs, but MutSβ has higher affinity for these small loops (8). Defects in MMR genes cause microsatellite instability and predisposition to cancer (9), demonstrating that MMR is essential for genetic stability in human cells. Surprisingly, genetic studies in mice suggest that MutSβ promotes (CAG)_n expansion and TNR instability. These studies show that expansion of a heterologous (CAG)_n tract occurs in wild type and MSH6^−/− mice but that expansion of the (CAG)_n tract is suppressed in MSH2^−/− and MSH3^−/− mice (10, 11). Recently, Owens et al. (11) reported that binding to a (CAG)_n hairpin influences the protein conformation, nucleotide binding, and hydrolysis activities of MutSβ so that they are different from what has been reported for MutSα during mismatch recognition. It is therefore hypothesized that (CAG)_n hairpins, through their ability to alter the biochemical properties of MutSβ, hijack the MMR process, leading to CAG repeat expansion instead of CAG hairpin removal (11). However, it is not clear why MMR, a major genome maintenance system, would promote TNR instability instead of TNR stability. We, therefore, have developed a novel functional assay and examined the validity of this hypothesis. Our results reveal that MutSβ displays normal biochemical activities when binding to CAG hairpins and does not inhibit (CAG)_n hairpin repair. The observations presented here provide novel thoughts on whether or not or how MutSβ is involved in CAG repeat instability in human cells.     

Combinatorial discovery of fluorophores and fluorescent probes

The properties of organic fluorophores are difficult to predict, even in simple cases. Fluorescent probes--which combine fluorescent properties with the equally challenging problem of molecular recognition--are even more difficult to develop. Combinatorial approaches to the development of such molecules are a new but promising endeavor, and reviewing the state of the art delineates the near-and long-term possibilities.     

The genetics and genomics of the drought response in Populus

The genetic nature of tree adaptation to drought stress was examined by utilizing variation in the drought response of a full-sib second generation (F(2)) mapping population from a cross between Populus trichocarpa (93-968) and P. deltoides Bart (ILL-129) and known to be highly divergent for a vast range of phenotypic traits. We combined phenotyping, quantitative trait loci (QTL) analysis and microarray experiments to demonstrate that 'genetical genomics' can be used to provide information on adaptation at the species level. The grandparents and F(2) population were subjected to soil drying, and contrasting responses to drought across genotypes, including leaf coloration, expansion and abscission, were observed, and QTL for these traits mapped. A subset of extreme genotypes exhibiting extreme sensitivity and insensitivity to drought on the basis of leaf abscission were defined, and microarray experiments conducted on these genotypes and the grandparent species. The extreme genotype groups induced a different set of genes: 215 and 125 genes differed in their expression response between groups in control and drought, respectively, suggesting species adaptation at the gene expression level. Co-location of differentially expressed genes with drought-specific and drought-responsive QTLs was examined, and these may represent candidate genes contributing to the variation in drought response.     

The prototoxin lynx1 acts on nicotinic acetylcholine receptors to balance neuronal activity and survival in vivo

Nicotinic acetylcholine receptors (nAChRs) affect a wide array of biological processes, including learning and memory, attention, and addiction. lynx1, the founding member of a family of mammalian prototoxins, modulates nAChR function in vitro by altering agonist sensitivity and desensitization kinetics. Here we demonstrate, through the generation of lynx1 null mutant mice, that lynx1 modulates nAChR signaling in vivo. Its loss decreases the EC(50) for nicotine by approximately 10-fold, decreases receptor desensitization, elevates intracellular calcium levels in response to nicotine, and enhances synaptic efficacy. lynx1 null mutant mice exhibit enhanced performance in specific tests of learning and memory. Consistent with reports that mutations resulting in hyperactivation of nAChRs can lead to neurodegeneration, aging lynx1 null mutant mice exhibit a vacuolating degeneration that is exacerbated by nicotine and ameliorated by null mutations in nAChRs. We conclude that lynx1 functions as an allosteric modulator of nAChR function in vivo, balancing neuronal activity and survival in the CNS.     

Genetic similarity, extrapair paternity, and offspring quality in Savannah sparrows (Passerculus sandwichensis)

The occurrence of extrapair paternity (EPP) in birds is oftenattributed to the action of good-genes sexual selection wherebyfemales "trade up" on male genetic quality by allocating fertilizationsto males with better genes than those possessed by their socialmate. To date, most studies of EPP in birds focus on absolutemeasures of male quality as a criterion for female choice, althoughmultiple mating by females in other taxa is more commonly ascribedto benefits associated with the individual optimization of offspringgenotypes. Here, we examine whether the genetic similarity ofsocial mates predicts female mating patterns in a populationof Savannah sparrows (Passerculus sandwichensis) where as manyas 70% of adults produce extrapair young (EPY). We considerthe influence of genetic similarity across all stages of a female'sdecision-making process, from pair formation through the decisionto produce EPY, to the allocation of fertilizations to specificextrapair sires. In a 4-year study of 175 males, 206 females,and 506 offspring, females were more likely to produce EPY whenpaired to genetically similar males, but they did not appearto be influenced by the size, age, mass, individual heterozygosity,and genetic diversity of their social mates. In paired comparisons,females were almost twice as likely to decrease their geneticsimilarity to males when producing EPY as they were to increaseit. Nonetheless, females did not select especially dissimilarmales when mating outside the pair-bond nor did they pair disassortativelywith respect to genetic similarity. Relative measures of malequality may influence mating patterns in birds, but only atsome points in a female's decision-making process.