Survival of cohorts in a fluctuating population of the vole Microtus townsendii

Survival patterns of cohorts are described during a population cycle of the vole Microtus townsendii near Vancouver, British Columbia, Canada. A two–year live–trapping study on both enclosed and unfenced populations showed that cohorts during the increase phase of growth lived longest and had the best survival. Smaller voles in the peak density spring cohort had poor survival, but survival increased during the peak density summer. Survival of cohorts in the decline phase breeding season was very poor. The suggestions are made that changes in spacing behaviour may cause changes in cohort survival and that the causes of rapid changes in survival need to be determined.     

Dispersal tendency and duration of life of littermates during population fluctuations of the vole Microtus townsendii

Summary In increasing and peak populations of the vole Microtus townsendii, littermates, whether they did or did not disperse, tended to have similar lifespans. Identifiable families tended to survive or disperse as a unit. Tendency to disperse from peak populations was non-randomly distributed among litters, and littermates dispersed at the same age.     

Genetic structure and colonization processes in European populations of the common vole, Microtus arvalis

The level of genetic differentiation within and between evolutionary lineages of the common vole (Microtus arvalis) in Europe was examined by analyzing mitochondrial sequences from the control region (mtDNA) and 12 nuclear microsatellite loci (nucDNA) for 338 voles from 18 populations. The distribution of evolutionary lineages and the affinity of populations to lineages were determined with additional sequence data from the mitochondrial cytochrome b gene. Our analyses demonstrated very high levels of differentiation between populations (overall FST: mtDNA 70%; nucDNA 17%). The affinity of populations to evolutionary lineages was strongly reflected in mtDNA but not in nucDNA variation. Patterns of genetic structure for both markers visualized in synthetic genetic maps suggest a postglacial range expansion of the species into the Alps, as well as a potentially more ancient colonization from the northeast to the southwest of Europe. This expansion is supported by estimates for the divergence times between evolutionary lineages and within the western European lineage, which predate the last glacial maximum (LGM). Furthermore, all measures of genetic diversity within populations increased significantly with longitude and showed a trend toward increase with latitude. We conclude that the detected patterns are difficult to explain only by range expansions from separate LGM refugia close to the Mediterranean. This suggests that some M. arvalis populations persisted during the LGM in suitable habitat further north and that the gradients in genetic diversity may represent traces of a more ancient colonization of Europe by the species.     

Spatial dynamics of Microtus vole populations in continuous and fragmented agricultural landscapes

Small mammal populations often exhibit large-scale spatial synchrony, which is purportedly caused by stochastic weather-related environmental perturbations, predation or dispersal. To elucidate the relative synchronizing effects of environmental perturbations from those of dispersal movements of small mammalian prey or their predators, we investigated the spatial dynamics of Microtus vole populations in two differently structured landscapes which experience similar patterns of weather and climatic conditions. Vole and predator abundances were monitored for three years on 28 agricultural field sites arranged into two 120-km-long transect lines in western Finland. Sites on one transect were interconnected by continuous agricultural farmland (continuous landscape), while sites on the other were isolated from one another to a varying degree by mainly forests (fragmented landscape). Vole populations exhibited large-scale (>120 km) spatial synchrony in fluctuations, which did not differ in degree between the landscapes or decline with increasing distance between trapping sites. However, spatial variation in vole population growth rates was higher in the fragmented than in the continuous landscape. Although vole-eating predators were more numerous in the continuous agricultural landscape than in the fragmented, our results suggest that predators do not exert a great influence on the degree of spatial synchrony of vole population fluctuations, but they may contribute to bringing out-of-phase prey patches towards a regional density level. The spatial dynamics of vole populations were similar in both fragmented and continuous landscapes despite inter-landscape differences in both predator abundance and possibilities of vole dispersal. This implies that the primary source of synchronization lies in a common weather-related environment.     

Size and growth characteristics of dispersing voles,Microtus townsendii

Summary In a peak population of Microtus townsendii, adults and subadults dispersed during the spring decline, and subadults and juveniles dispersed during the summer and fall. Voles born in the spring dispersed before the start of the next year's breeding season, whereas fall-born voles dispersed during the next year's breeding season. Voles under 50 g, when they dispersed, had faster growth rates than similar-sized residents, but voles over 59 g, when they dispersed, had slower growth rates than similar-sized residents. Dispersing and resident voles 50–59 g had no consistent trend in growth rates.     

Splenomegaly and reticulocytosis caused by Babesia microti infections in natural populations of the montane vole, Microtus montanus.

A survey for Babesia microti in rodents was conducted at six sites within Grand Teton National Park, Wyoming. Blood and spleen smears, hematocrits, and reticulocyte counts were made on all of the animals to evaluate parameters for the diagnosis of babesiosis. Ticks were removed for identification. Of 257 Microtus montanus, 103 were infected with B. microti. In addition, five of 12 Microtus pennsylvanicus and one of three Arvicola richardsoni were parasitized by B. microti. Peromyscus maniculatus (n = 40) were not infected. Concurrent infections by Hepatozoon sp., Trypanosoma sp., and the bacterium, Grahamella sp., were noted in blood smears from a number of M. montanus. Splenomegaly and reticulocytosis were significant parameters associated with babesiosis while decreased hematocrit was not. Ticks removed from the voles were identified as Ixodes eastoni and were the probable vectors of the B. microti.     

A comparison of paternal behaviour in the meadow vole Microtus pennsylvanicus,the pine vole M. pinetorum and the prairie vole M. cchrogaster

Paternal care in microtines has been studied infrequently and few studies have compared patterns of direct and indirect paternal investment. The paternal behaviour of three vole species, the meadow vole (Microtus pennsylvanicus), the pine vole (M. pinetorum) and the prairie vole (M. ochrogaster) was examined in a semi-natural setting. Prairie and pine voles were found to exhibit high levels of paternal care. Prairie vole males contributed the most direct care by remaining in the natal nest for long periods of time in contact with the pups. Pine voles contributed less direct care than prairie voles as they spent less time in the natal nest with their offspring. In addition, both prairie and pine vole males were observed to groom their pups and retrieve them back to the nest area. Prairie vole males also engaged in such indirect forms of care as nest construction and maintenance, while pine voles provided indirect care in the form of tunnel construction and food caching. Meadow vole males were the least paternal of the three species and rarely engaged in either direct or indirect care. These findings support predictions that M. pennsylvanicus is promiscuous and that male and female meadow voles occupy separate territories. They are also consistent with studies which indicate that prairie and pine voles are monogamous and have a structured social organization with members interacting closely with one another.     

Individual growth rates in natural field vole, Microtus agrestis, populations exhibiting cyclic population dynamics

Rodents that have multi-annual cycles of density are known to have flexible growth strategies, and the “Chitty effect”, whereby adults in the high-density phase of the cycle exhibit larger average body mass than during the low phase, is a well-documented feature of cyclic populations. Despite this, there have been no studies that have repeatedly monitored individual vole growth over time from all phases of a density cycle, in order to evaluate whether such variation in body size is due to differences in juvenile growth rates, differences in growth periods, or differential survival of particularly large or small voles. This study compares growth trajectories from voles during the peak, increase and crash phases of the cycle in order to evaluate whether voles are exhibiting fast or slow growth strategies. We found that although voles reach highest asymptotic weights in the peak phase and lowest asymptotes during the crash, initial growth rates were not significantly different. This suggests that voles attain larger body size during the peak phase as a result of growing for longer.     

Interindividual influence on diurnal rhythms of activity in cycling and noncycling populations of the field vole,Microtus agrestis L.

Summary The effects of interaction among individuals with respect to wheelrunning activity has been investigated in two geographically separated populations of the field vole Microtus agrestis L. In one of them, a northern cyclically varying population, a strictly nocturnal activity pattern is changed into a more or less short term 24 h pattern under conditions of increased contact among individuals. In the other population, south-Swedish, without population cycles, no such effects were observed. This indicates population differences in response to interindividual contact which might be of importance to the known differences in population dynamics.     

A biochemical and ecological study of plasma esterase polymorphism in natural populations of the field vole,Microtus agrestis L.

Starch gel electrophoresis of plasma from wild individuals of Microtus agrestis L., the field vole, has revealed widespread polymorphism for the presence or absence of a particular esterase, referred to as E₁. The active forms of the enzyme hydrolyze a wide range of substrates and are resistant to inhibition by eserine, the organophosphate Diazinon, and to appropriate heat treatment. Breeding tests suggest four alleles: Es-1 ^o which, when homozygous, results in complete absence of enzyme activity; Es-1 ^a andEs-1 ^b which control equal activity but differences in electrophoretic mobility; and Es-1 ^c which has double the activity of either Es-1 ^a or Es-1 ^b ,but the same mobility as Es-1 ^a .A sensitive method has been developed of measuring E₁ activity in free solution, with interfering effects of other esterases being eliminated by differential inhibition. Quantitative estimates of activity in laboratory-reared voles of known ages and genotype showed that homozygotes and heterozygotes can be separated with a fair degree of confidence. There is a small but significant negative regression of activity on age. No sex differences have been detected. There is evidence of residual variation in activity of uncertain origin. Comparison of phenotype frequency in widely separated Scottish populations suggests that the polymorphism is balanced. Phenotypic frequencies have been systematically studied in natural populations in relation to ecology, season of the year, and the cycle of population density. There is strong evidence of a population-density-dependent selection in favor of animals without E₁ enzyme activity, judged by the difference in frequency before and after the peak density. There is also evidence of selection in the opposite direction due to differences in survival during the winter. These opposing selective pressures are believed to contribute to the polymorphism, although other factors are not excluded.     

The creeping vole, Microtus oregoni: karyotype and sex-chromosome differences between two geographical populations

The G-banded karyotype of the creeping vole, Microtus oregoni, prepared from animals trapped in Oregon and Washington, is presented. The two populations had similar autosomal banding patterns but exhibited striking differences in their sex chromosomes. The X chromosome of voles captured in Oregon was 39% longer than that of voles trapped in Washington. The length difference was primarily due to an increase in size of light G-bands, which, in both populations, comprised large segments of the X chromosome. On C-banding, the X chromosome exhibited major blocks of constitutive heterochromatin corresponding to the light G-bands. In contrast, the Y chromosome of the Oregon voles was 24% shorter than that of the Washington voles and lacked the short arm and some terminal bands present in the Washington voles.     

Sperm DNA and sex chromosome differences between two geographical populations of the creeping vole, Microtus oregoni

The relative DNA content of the "O" and Y chromosome-bearing sperm is presented for the creeping vole, Microtus oregoni. The animals had been trapped in Oregon and in Washington State. The two populations had very similar autosomal chromosome relationships but differed greatly in the size of their X chromosome (which is not carried by vole sperm) and in their Y chromosome. The greater size and banding differences of the Y chromosome of the Washington State vole compared to the Oregon vole paralleled the greater differences in sperm DNA between the Y-bearing sperm and the sperm carrying no sex chromosome (O). The actual DNA differences between O and Y sperm was 12.5% for the sperm from the Washington State voles and 9.1% for sperm from the Oregon voles. The difference in sperm DNA content (12.5%) for Washington State voles was far greater than the difference shown for other voles or other mammals.