Temporally stable genetic variability and dynamic kinship structure in a fluctuating population of the root vole Microtus oeconomus

Genetic variability, kin structure and demography of a population are mutually dependent. Population genetic theory predicts that under demographically stable conditions, neutral genetic variability reaches equilibrium between gene flow and drift. However, density fluctuations and non‐random mating, resulting e.g. from kin clustering, may lead to changes in genetic composition over time. Theoretical models also predict that changes in kin structure may affect aggression level and recruitment, leading to density fluctuations. These predictions have been rarely tested in natural populations. The aim of this study was to analyse changes in genetic variability and kin structure in a local population of the root vole (Microtus oeconomus) that underwent a fourfold change in mean density over a 6‐year period. Intensive live‐trapping resulted in sampling 88% of individuals present in the study area, as estimated from mark–recapture data. Based on 642 individual genotypes at 20 microsatellite loci, we compared genetic variability and kin structure of this population between consecutive years. We found that immigration was negatively correlated with density, while the number of kin groups was positively correlated with density. This is consistent with theoretical predictions that changes in kin structure play an important role in population fluctuations. Despite the changes in density and kin structure, there was no genetic differentiation between years. Population‐level genetic diversity measures did not significantly vary in time and remained relatively high (H_E range: 0.72–0.78). These results show that a population that undergoes significant demographic and social changes may maintain high genetic variability and stable genetic composition.     

Silent Genes: Antimicrobial Resistance and Antibiotic Production

Silent genes are DNA sequences that are generally not expressed or expressed at a very low level. These genes become active as a result of mutation, recombination, or insertion. Silent genes can also be activated in laboratory conditions using pleiotropic, targeted genome-wide, or biosynthetic gene cluster approaches. Like every other gene, silent genes can spread through horizontal gene transfer. Most studies have focused on strains with phenotypic resistance, which is the most common subject. However, to fully understand the mechanism behind the spreading of antibiotic resistance, it is reasonable to study the whole resistome, including silent genes. Open in a separate window     

Conserved flanking microsatellite sequences (ReFS) differentiate between Lepidoptera species,and provide insight into microsatellite evolution

High rates of mutation and homoplasy mean that microsatellites generally are not considered to be useful molecular markers for inferring systematic relationships between species. However, an earlier pilot study suggested that conserved flanking microsatellite sequences, also known as repetitive flanking sequences (ReFS), may form a basis for a dominant marker that can differentiate between species of Lepidoptera. We present data that demonstrate that ReFS are quick and easy to use, and generate highly repeatable banding patterns from a range of Lepidoptera species. Sequence data from a subset of ReFS‐amplified bands revealed microsatellite families with flanking sequences that are more conserved within than among species: this is probably attributable to recombination‐mediated events, transposition of mobile elements or a combination of the two. Our data support the use of ReFS as dominant interspecific molecular markers, and add to the growing literature on the evolution of microsatellites in Lepidoptera.     

Visual cues collimate the trajectories of almond moth Cadra cautella males flying in wind and still air within a wind‐formed plume of pheromone

Male Cadra cautella (Walker) moths are videotaped in three dimensions in a 3‐m long wind tunnel as they fly within a 65‐cm wide plume of pheromone. Moths are presented two floor patterns, either ‘aligned’, a 25‐cm wide ‘trail’ of solid red circles along the tunnel's midline, or ‘offset’, in which the trail veers 25 cm to the left at the tunnel's midpoint. These visual patterns are presented either in a continuous airflow or airflow that is stopped before moths reach the tunnel's halfway point. Moths fly relatively straight paths over the aligned pattern in still air after the wind is stopped. With the offset pattern in wind and when the wind is stopped, moths swerve towards the offset pattern before again progressing along the plume. Prominent visual cues appear to ‘collimate’ (i.e. align with a directional cue) the moth's course as long as the moth remains in contact with pheromone. In wind, these moths appear to favour trajectories that enhance visual feedback, even if the path taken is not directly upwind. During wind lulls, this manoeuvre may enable moths to continue progress towards calling females along a visually set course. The centring of trajectory over prominent visual cues suggests that these moths favour a route that enhances visual feedback.     

Control of Seed Growth in Soya Beans [Glycine max (L.) Merrill]

The seed is the primary sink for photosynthate during reproductivegrowth and an understanding of the mechanisms controlling therate of seed growth is necessary to understand completely theyield production process. The growth rate of individual seedsof seven soya bean [Glycine max (L.) Merrill] cultivars withgenetic differences in seed size varied from 10.8 to 3.9 mgseed^–1 day^–1. The growth rates were highly correlatedwith final seed size. The growth rate of cotyledons culturedin a complete nutrient medium was highly correlated with thegrowth rate of seeds developing on the plant and with finalseed size. The number of cells per seed in the cotyledons variedfrom 10.2 to 5.7 x 10⁶ across the seven cultivars. The numberof cells per seed in the cotyledons was significantly correlatedwith final seed size and the seed growth rate both on the plantand in the culture medium. The data suggest that genetic differencesin seed growth rates are controlled by the cotyledons and thenumber of cells in the cotyledons may be the mechanism of control. Glycine max L., soya bean, seed size, growth rate, cell number, sink activity     

Junction Complexes between Sieve Tubes in the Secondary Phloem of Myrtaceae

Junction complexes of unusual structure form between neighbouringsieve tubes in the secondary phloem of Eucalyptus species. Thick-walledribs support thin-walled ‘sieve areas’. In longitudinalsections the structures have a ‘concertina’- likeappearance. They are relatively large, up to 0.2 mm in length.Electron micrographs confirmed that the structures consistedof thin-walled areas perforated with pores, supported by muchthicker ribs. The structures provide a vast surface area fortransfer of metabolites between sieve tubes compared with thatof lateral wall sieve areas of other plants. Hydrolysis of parenchymacell walls occurs during the development of the junction complexes.The structures are only found when sieve tubes are in closeproximity and it is the redifferentiation and partitioning ofintervening parenchyma cells which result in junction complexformation. A survey for the presence of the structures in thephloem of other genera in the family Myrtaceae was made andthey were found in Tristania and Angophora but were not observedin Acmena and Metrosideros. Eucalyptus, sieve tubes, lateral walls, ultrastructure