Competition at the Mouse t Complex: Rare Alleles Are Inherently Favored

We investigate the competition between alleles at a segregation distorter locus. The focus is on the invasion prospects of rare mutant distorter alleles in a population in which a wildtype and a resident distorter allele are present. The parameters are chosen to reflect the situation at the t complex of the house mouse, one of the best-studied examples of segregation distortion. By analyzing the invasion chances of rare alleles, we provide an analytical justification of earlier simulation results. We show that a new distorter allele can successfully invade even if it is inferior both at the gamete and at the individual level. In fact, newly arising distorter alleles have an inherent rareness advantage if their negative fitness consequences are restricted to homozygous condition. Likewise, rare mutant wildtype alleles may often invade even if their viability or fertility is reduced. As a consequence, the competition between alleles at a segregation distorter locus should lead to a high degree of polymorphism. We discuss the implications of this conclusion for the t complex of the house mouse and for the evolutionary stability of “honest” Mendelian segregation.     

Size-dependent sex change can be the ESS without any size advantage of reproduction when mortality is size-dependent

Almost all models of sex change evolution assume that reproductive rate increases with body size. However, size-dependent sex changing plants often show size-independent reproductive success, presumably due to pollen limitation. Can the observed size-dependent sex change pattern be the ESS in this case? To answer this question, we analyze a game model of size-dependent sex expression in plants. We assume: (1) reproductive rate is perfectly independent of size; (2) mortality decreases with size in the same way for both sexes; (3) growth rates decrease at maturity, more for females than males. We show that the ESS is size-dependent sex expression: small individuals are vegetative, intermediate individuals are male, and large individuals are female. These results demonstrate that mortality is important in size-dependent sex allocation even when mortality rate is independent of sex. They also offer an explanation of why we see populations in poor environments to have sex ratios more biased toward the first sex relative to high quality environments.     

Use of Social and Ecological Information in Tamarin Foraging Decisions

A major consequence of group living is that foragers may rely on social information in addition to ecological information to locate feeding sites. Although conspecifics can provide cues as to the spatial location of food patches, individual foraging decisions also must include some assessment of the likelihood of obtaining access to a resource other group members seek. This likelihood differs in the 2 models generally proposed to explain intragroup social foraging: the information-sharing model and the producer-scrounger model. We conducted an experimental field study on wild groups of emperor (Saguinus imperator) and saddleback (S. fuscicollis) tamarins to determine the foraging strategies adopted by individual group members and their relationship to social rank, food intake, and the ability to use ecological and social information in making intra-patch foraging decisions. Individual tamarins applied different behavioral strategies compatible with a finder-joiner paradigm to solve foraging problems. About half of the individuals in each study group initiated 74%–90% of all food searches and acted as finders. Most alpha individuals adopted a joiner strategy by monitoring the activities of others' to obtain a reward. The individual arriving first at a reward platform enjoyed a finder's advantage. Despite differences in search effort, both finders and joiners presented similar abilities in learning to associate ecological cues with the presence of food rewards at our experimental feeding stations. We conclude that within a group foraging context, tamarins integrate social and ecological information in decision-making.     

Early male reproductive advantage,multiple paternity and sperm storage in an amphibian aggregate breeder

We tested whether the order in which males encounter females affects reproductive fitness in spotted salamanders (Ambystoma maculatum). Using mating chambers in the field, we allowed one male access to a female before a second male. We then used four microsatellite markers in paternity analyses of the resulting larvae. First males sired a significantly larger number of offspring than second males, suggesting that male reproductive success is greatly enhanced by early arrival at breeding ponds. Multiple paternity was common among clutches, and frequently larvae were assigned to unidentified males that had not been in the chambers. Sperm from these males had either been stored by females for a year or obtained more recently at other breeding sites.     

Adaptative Value of a PKC–PKI55 Feedback Loop of Inhibition That Prevents the Kinase’s Deregulation

A 168-bp amplification product was obtained in RT-PCR experiments using a degenerate oligonucleotide designed on a five-amino acid sequence of IN, a 7-kDa protein, previously characterized as a PKC inhibitor. It was included in the coding ORF of the 1530-bp-long IMAGE clone ID 38900 (accession numbers R51337 and R51448) that produces a translation product of 6.5 kDa. The translation of the ORF conceptual reading frame allowed the preparation of the synthetic protein PKI55, which was found to inhibit and degrade both untreated nPKC d isozymes and activated cPKC isozymes. The PKI55 gene is localized in chromosome 2q35. The Repeat Maskers output showed a 533-bp-long LTR32/ERVL segment that included the PKI55 coding sequence and a complete regulatory region. The coding sequence and the structure of PKI55 were detected in a brain cDNA of Macaca fascicularis (diverged from human lineages about 25 Myr ago). Three other human genes with over 60% identities with PKI55 were identified in three different loci (i.e., chromosomes 10, 15, and 20.) Synthesis of PKI55 was stimulated by PKC activation. A feedback loop of inhibition is established. When the PKCs are overactivated, PKI55 induces degradation of the enzyme and prevents the isozyme overexpression implicated in a number of important diseases including cancer, diabetes, and disorders of the immune system. The presence of the PKI55 sequence in Macaca fascicularis as well as in human chromosomes 10, 15, and 20 indicates a selective advantage for the PKI55 sequence and the adaptive value of the feedback mechanism. Rita Selvatici, Center of Neuroscience, University of Ferrara, Ferrara, Italy Accession Numbers: human chromosome 10 clone RP11-36N22, AL356865; human chromosome 15 clone RP11-57P19, AC009432; human chromosome 20 clone RP4-697P8, AL050403; Macaca fascicularis brain cDNA clone QnpA-21012, AB050412; cDNA clone DKFZp434H1419, AL137534; human chromosome 2q35 BAC clone RPCI11-1064L18, AC008123; IMAGE clone ID 38900, R51337 and R51448. BLAST amino acid query sequence from TBLASTN program 2.2.1 ( ).     

Critical comment on “Revisiting the Asian second-generation advantage”

This critical comment notes an important error of inference in Tran, Lee, and Huang (2019). Results reported in Tran, Lee, and Huang (2019) do not permit the inference that any of the second-generation Asian groups in the study—Chinese, Indians, Filipinos, Vietnamese, and Koreans—face a “bamboo ceiling” disadvantage relative to native Whites in attaining managerial or professional occupations in the U.S. labor market, controlling for educational attainment, age and age squared, gender, and region.     

The growth advantage in stationary-phase (GASP) phenomenon in mixed cultures of enterobacteria

Growth advantage in stationary phase (GASP) is the term used to describe the ability of mutants with an increased fitness from 10-day-old enterobacteria culture to out-compete 1-day-old cells of the same initial strain during a prolonged stationary phase, although the aged cells are introduced as a minority. We studied this bacterial trait in mixed cultures of two enterobacterial species, Escherichia coli and Salmonella enterica, wild type in addition to derived mutants from both strains that contain chromosomal-encoded resistance to either nalidixic acid or streptomycin. The strong GASP phenotype was obtained in mixed cultures with the aged mutant strains, but not when the isogenic antibiotic-sensitive strains were used. This phenomenon was associated with chromosomal rearrangements in 10-day-old bacterial antibiotic-resistant mutated cells.     

Testing the enemy release hypothesis: a review and meta-analysis

One of the most cited hypotheses explaining the inordinate success of a small proportion of introduced plants that become pests is the ‘natural enemies hypothesis’. This states that invasive introduced plants spread rapidly because they are liberated from their co-evolved natural enemies. This hypothesis had not been properly tested until recently. Previous reviews on this topic have been narrative and vote counting in nature. In this review, we carried out quantitative synthesis and meta-analysis using existing literature on plants and their herbivores to test the different components of the enemy release hypothesis. We found supporting evidence in that (1) insect herbivore fauna richness is significantly greater in the native than introduced ranges, and the reduction is skewed disproportionally towards specialists and insects feeding on reproductive parts; and (2) herbivore damage levels are greater on native plants than on introduced invasive congeners. However, herbivore damage levels are only marginally greater for plants in native than in introduced ranges, probably due to the small numbers of this type of study. Studies quantifying herbivore impacts on plant population dynamics are too scarce to make conclusions for either comparison of plants in native vs introduced ranges or of co-occurring native and introduced congeners. For future research, we advocate that more than two-way comparisons between plants in native and introduced ranges, or native and introduced congeners are needed. In addition, the use of herbivore exclusions to quantify the impacts of herbivory on complete sets of population vital rates of native vs introduced species are highly desirable. Furthermore, three-way comparisons among congeners of native plants, introduced invasive, and introduced non-invasive plants can also shed light on the importance of enemy release. Finally, simultaneously testing the enemy release hypothesis and other competing hypotheses will provide significant insights into the mechanisms governing the undesirable success of invasive species.     

Resource defense in a group-foraging context

When foraging in groups, animals frequently use either scrambleor contest tactics to obtain food at clumps found by others.The question of which competitive tactic should be used hasbeen addressed from two different perspectives: a simple optimalityapproach and a game theoretic approach. Surprisingly, both approachesmake strikingly different predictions about how per-capita frequencyof aggression within groups should change as a function of foodabundance and competitor density. Resource defense theory typicallypredicts dome-shaped relationships between the per-capita frequencyof aggression and both food abundance and competitor density,whereas game theoretic models predict an increase in aggressionwith competitor density and a decline in aggression with increasedfood abundance. We developed a game theoretic model to explorewhether the predictions of resource defense theory and the gametheoretic approach can be reconciled. Our model assumes thatplayers have different competitive abilities and can adopt rolesof either finder or joiner that affect the quantity of foodthat can be gained from a food clump. In accordance with earliergame theoretic models, we predict an increase in aggressionwith competitor density when animals compete by pair-wise contests.However, when food clumps can be challenged by more than onecompetitor, both the costs and benefits of defending increasewith competitor density, which results in a dome-shaped relationshipbetween the two variables. Our model predicts that aggressionshould always decrease as the density of food clumps increases.