The potential for and constraints on the evolution of compensatory ability in Asclepias syriaca

To investigate the potential for and constraints on the evolution of compensatory ability, we performed a greenhouse experiment using Asclepias syriaca in which foliar damage and soil nutrient concentration were manipulated. Under low nutrient conditions, significant genetic variation was detected for allocation patterns and for compensatory ability. Furthermore, resource allocation to storage was positively, genetically correlated both with compensatory ability and biomass when damaged, the last two being positively, genetically correlated with each other. Thus, in the low nutrient environment, compensatory ability via resource allocation to storage provided greater biomass when damaged. A negative genetic correlation between compensatory ability and plant biomass when undamaged suggests that this mechanism entailed an allocation cost, which would constrain the evolution of greater compensatory ability when nutrients are limited. Under high nutrient conditions, neither compensatory ability nor allocation patterns predicted biomass when damaged, even though genetic variation in compensatory ability existed. Instead, plant biomass when undamaged predicted biomass when damaged. The differences in outcomes between the two nutrient treatments highlight the importance of considering the possible range of environmental conditions that a genotype may experience. Furthermore, traits that conferred compensatory ability did not necessarily contribute to biomass when damaged, demonstrating that it is critical to examine both compensatory ability and biomass when damaged to determine whether selection by herbivores can favor the evolution of increased compensation. Received: 2 April 1999 / Accepted: 21 September 1999     

Multigenic polymorphism as a source of adaptively restricted population variability

Among 400 Drosophila melanogaster flies individually analysed for nine gene–enzyme systems, a total of 160 different genotypes were found: 78 were repeatedly observed in two to 22 individuals, and 82 appeared only once. An increase in the frequency of rare alleles could be observed in such groups of genotypes that were less frequent. Among 24 most frequent genotypes (in 189 individuals) only four different combinations of five third-chromosomal genes are present, and 12 different combinations of three second-chromosomal genes. Among 82 unique genotypes these combinations were much more versatile: 29 at the third, 22 at the second, and three at the first chromosomes. The proportion of heterozygotes was increasing from most frequent toward unique genotypes (1.5–2.1 ± 0.1), primarily due to heterozygosity in five third-chromosomal loci (0.4–1.1 ± 0.06). When the number of genotypes in 100, 200, 300 and 400 sampled flies was extrapolated to larger samples, it became clear that this increase has an asymptotic character. It must be assumed that for our nine-loci model a total of approximately 200–220 different genotypes may exist in a population of a few thousands individuals, which means that adaptive variation for such a complex gene–enzyme system must be very much limited.     

Developmental costs of rapid growth in a damselfly

Abstract.  1. Developmental costs of rapid growth in terms of increased fluctuating asymmetry are expected to contribute to the widespread occurrence of growth rates below the physiological maximum, but have rarely been demonstrated. Here, these costs are studied for the first time in an invertebrate, the damselfly Lestes viridis , using a rearing experiment where early- and late-hatched larvae of both sexes were reared at decreasing or permanent water levels.
2. Late-hatched animals were more asymmetrical than early-hatched animals except for males in the drying treatment. Also, females were more asymmetrical than males except in early-hatched animals in the drying treatment.
3. The data presented suggest that in females but not in males treatment groups with higher growth rates have more asymmetrical wings. However, at the individual level no relationship between growth rate and asymmetry was present.
4. Possible reasons why the suggested trade-off between growth and developmental instability was not present at the individual level, and at the group level only in females, are discussed.     

Faunal changes and geographic crypticism indicate the occurrence of a biogeographic transition zone along the southern East Pacific Rise

Aim Deep‐sea hydrothermal vents have now been reported along all active mid‐ocean ridges and back‐arc basins, but the boundaries of biogeographic entities remain questionable owing to methodological issues. Here we examine biogeographic patterns of the vent fauna along the East Pacific Rise (EPR) and determine the relative roles of regional and local factors on the distribution of biodiversity associated with mussel beds along a poorly explored zone, the southern EPR (SEPR). Location East Pacific Rise. Methods A species list of macrobenthic invertebrates along the EPR was compiled from the literature and supplemented with data recovered during the French research cruise BIOSPEEDO carried out in 2004 along the SEPR. Biogeographic patterns were assessed by combining the identification of morphological species with a molecular barcoding approach. A multivariate regression tree (MRT) analysis was performed to identify any geographic breaks, and an empirical distribution of species richness was compared with predictions provided by a mid‐domain effect model. Macrofaunal community structure associated with mussel beds along the SEPR was analysed in relation to environmental factors using cluster and canonical redundancy analyses. Results Sequencing of the cytochrome c oxidase subunit I gene revealed the occurrence of several cryptic species complexes along the EPR, with the equator separating the southern and northern clades. Furthermore, during the BIOSPEEDO cruise at least 10 still unnamed species were collected between 7°25′ S and 21°33′ S. The shift in community structure identified by MRT analysis was located south of 17°34′ S or south of 13°59′ S, depending on the data used, suggesting that the southern part of the SEPR (17°25′–21°33′ S) constitutes a biogeographic transition zone in the vent fauna along the EPR. At a regional scale, latitude combined with the type of venting was significantly correlated with the community structure associated with mussel beds. Main conclusions Together, the molecular data, in situ observations, and the distribution of species suggest that the high diversity of vent fauna species presently observed between 17°25′ S and 21°33′ S is probably a result of the overlap of several distinct biogeographic provinces. We argue that this area thus constitutes a biogeographic vent fauna transition zone along the EPR.     

The life-history strategy of deepwater sculpin, Myoxocephalus thompsoni (Girard), in Lake Michigan: dispersal and settlement patterns during the first year of life

Deepwater sculpin, Myoxocephalus thompsoni (Girard), were sampled from six stations from the 15–100 m depth contours in Lake Michigan between April 1983 and July 1984. In south-eastern Lake Michigan M. thompsoni lay benthic eggs in offshore waters, which hatch between November and August, with peak hatching in March. Abundance of larvae in pelagic samples was higher offshore than inshore, but larval size was greater and development more advanced at inshore stations, indicating an inshore movement after hatching. Larvae reached metamorphosis at 20 mm and settled to the bottom beginning in July. Pelagic larvae 20–40 mm were found in the lower water column at all stations, but newly settled individuals were only captured with bottom trawls at inshore locations (≤60 m depth). Data from ichthyoplankton and bottom trawl samples in 1983 and 1984 indicated that locations for successful settlement of larvae to the bottom extended only as deep as the shallowest fringe of the adult population (> 50 m in 1983). In 1983, maximum density of larvae reached 0.4 individuals m⁻³ by June. Survival from the pelagic larval stage to the demersal young-of-year stage in 1983/1984 was c . 0.1–0.4%. The specific mechanism of mortality at the time of transition to a demersal habit has not been determined.     

A social learning model of conflict and cooperation in human societies

Patterns of conflict and cooperation both within and between societies may be related to the degree of cultural similarity within and between the same societies. A simple model of social learning is used to predict patterns of conflict and cooperation in hypothetical societies that differ in the roles of relatives and nonrelatives in the enculturation of children. The model is illustrated by comparing its predictions to known differences in the patterns of conflict between males inpatrilocal and matrilocal societies.     

High temperature and oxygen supplementation can mitigate the effects of hypoxia on developmental stability of bilateral traits during incubation of broiler breeder eggs

Hypoxia strongly affects embryonic development during the pre-hatch period. This study was conducted to investigate the effects of oxygen supplementation (O) and a 38.5°C high temperature (HT) at high altitude (HA, 1720 m) on morphological traits during a pre-hatch period and on relative fluctuating asymmetry (relative FA) and allometric growth during an early post-hatch period in broilers. A total of 720 eggs were obtained from a 45-week-old Ross 308 broiler breeder flock raised at sea level (2 m). The eggs were divided into six incubation condition (IC) groups and were incubated at HA. O groups were exposed to 23.5% O₂ for 1 h daily from either days 0 to 11 (O_0–11), days 12 to 21 (O_12–21) or days 18 to 21 (O_18–21) of incubation. HT groups were exposed to 38.5°C daily from either days 12 to 21 (HT_12–21) or days 18 to 21 (HT_18–21) of incubation. A control was maintained at 37.8°C and 21% O₂. The hatched chicks were raised for 6 days at HA. Embryo/chick and beak lengths and head diameter were measured during pre- and post-hatch periods. The face, middle toe and shank lengths were measured for each chick. The relative asymmetry (RA), mean RA (MRA) and allometric growth of the lengths were computed and the existence of FA was demonstrated. The IC significantly affected the embryo length, with embryos of the O_0–11 group shorter than embryos of the other O groups. Chicks were longer in the O and HT groups than those in the control, except for the O_0–11. We found significant interactions between the IC and each development period for beak length. During the post-hatch period, the head diameter of the O_0-11 was significantly smaller than that of the other groups, but not in O_12–21. The interactions among IC, age and sex were significant for the RA of the face and middle toe lengths and for MRA. All the examined bilateral traits were evaluated as allometric growth. The FA for bilateral traits was determined in both sexes. The right (R) – left (L) and IR-Ll were the lowest in females for face length and in males for shank length from the O_18–21 and in males for middle toe length from the O_0–11 and HT_18–21 groups. Therefore, the effects of factors such as HT and O₂ could mitigate the adverse effects of HA-induced hypoxia on optimal developmental stability of bilateral traits of broiler.     

Within-individual changes in developmental stability affect flight performance

Developmental stability, as measured by fluctuating asymmetry,has been purported to be an indicator of individual quality,and low asymmetry can be selected for by sexual selection processes.However, low asymmetry can also arise due to biomechanical constraintsoperating on trait design, as it is predicted that asymmetrywill decrease mechanical efficiency. Specifically, it has beenpredicted that wing length asymmetry will be negatively relatedto avian flight performance. To date, empirical investigationshave only studied the influence of increasing asymmetry beyondnaturally occurring average values. I examined the influenceof within-individual changes in primary feather developmentalstability on flight performance in European starlings by studyingasymmetry and flight before and after wing molt. Individualsthat exhibited a decrease in wing asymmetry through molt experiencedincreased aerodynamic performance in terms of both angle oftakeoff and level flapping-flight speed. Birds that increasedwing asymmetry suffered a decrease in flight performance. Takeoffspeed and the ability to negotiate an aerial obstacle coursewere unaffected by asymmetry. My data provide empirical supportfor the predicted influence of wing asymmetry on flight, eventhough the changes in asymmetry were very small (mean = 0.47%of trait size) and further indicate the importance of biomechanicalconsiderations in any study of developmental stability