Carol Becker Lynch

Nesting and Fitness: Lifetime Reproductive Success in House Mice Bidirectionally Selected for Thermoregulatory Nest-Building Behavior

To test the hypothesis that large, well-built, nests are an important component of fitness, we kept 12 mating pairs of two high-selected, two control, and two low-selected lines, selected for therrnoregulatory nest-building behavior, at 22 and 4°C with access to 10 g of cotton to build a nest, for a period of 180 days. Measurements included number of litters bom per family, number of young per litter born and surviving up to 40 days of age, nest type built by the parents, and weight gain of the young from weaning (20 days of age) to 40 days of age. In all lines the production and survival of offspring was substantially decreased at 4°C compared to 22°C, but the high-selected lines produced more and better-quality offspring, surviving up to 40 days of age at both temperatures compared to the control and low-selected lines. This indicates that thermoregulatory nest-building behavior and evolutionary fitness are closely associated.

Circadian rhythms differ between selected mouse lines: A model to study the role of vasopressin neurons in the suprachiasmatic nuclei

Mice selected for differences in nest-building behavior differ in the number of arginine-vasopressin (AVP)-immunoreactive neurons in the suprachiasmatic nuclei (SCN). Although previous efforts to link AVP-immunoreactive neurons in the SCN to clock function have failed, we show that differences in several circadian parameters are associated with differences in the number of AVP-immunoreactive neurons between the selected lines. Although an alternative interpretation is discussed, we hypothesize that these neurons may relay timing information from the circadian pacemaker in the SCN for wheel-running activity. In addition, phase-response curves (PRCs) to 15-min light pulses in constant darkness also differ between the selected lines. However, these differences are not associated with the number of the AVP-immunoreactive neurons in the SCN, but are associated with the level of nest-building behavior. Compared to the Brattleboro rat, in which homozygous rats are deficient for AVP in the entire brain, our system, exhibiting a wide range of variability, has more specific utility for studying the role of the output pathways of the SCN in circadian rhythm control.

A Comparison Between House Mouse Lines Selected for Attack Latency or Nest-Building: Evidence for a Genetic Basis of Alternative Behavioral Strategies

House mouse lines bidirectionally selected for either nest-building behavior or attack latency were tested for both attack latency and nest-building behavior under identical conditions. Male mice selected for high nest-building behavior had shorter attack latencies, i.e., were more aggressive, than those selected for low nest-building behavior and their randomly bred control lines. Conversely, male wild house mice selected for short attack latency showed more nest-building behavior than those selected for long attack latency when tested at 110 days of age. These findings imply a common genetic basis for control of aggression and nesting and support earlier proposals as to how animals may exhibit fundamentally different responses to environmental challenges, either reacting actively to aversive situations (aggressive and high-nesting animals: active copers) or adopting a passive strategy (nonaggressive and low-nesting animals: passive copers).

Relationships of maternal nesting to thermoregulatory nesting in house mice (Mus musculus) at warm and cold temperatures

Abstract Thermoregulatory and maternal nesting in Mus musculus (indexed as weight of cotton pulled into the cage) was measured at 5 C and 22 C on mice representing lines from a bidirectional selection experiment for nest size at room temperature. The effects of both selection and temperature were significant across the entire experiment. Nesting on the day of parturition correlated highly with thermoregulatory nesting, and with the number of offspring that survived to weaning, indicating a common genetic basis for maternal and thermoregulatory nesting and a direct correlation of these traits with Darwinian fitness. Amount of cotton used increased soon after mating and remained high with a large amount of variability until about 10 days after parturition, and then decreased sharply. The pattern of changes in nest size during pregnancy resembled changes in progesterone levels reported previously in the literature for mice, and contrasted with models of a smooth symmetric curve peaking at parturition.

DIFFERENCES IN THE NUMBER OF ARGININE-VASOPRESSIN-IMMUNOREACTIVE NEURONS EXIST IN THE SUPRACHIASMATIC NUCLEI OF HOUSE MICE SELECTED FOR DIFFERENCES IN NEST-BUILDING BEHAVIOR

Arginine-vasopressin (AVP) is a homeostatic modulator of body temperature during fever and may also be involved in normal body temperature control. In the present study the hypothalamus of mice bi-directionally selected for thermoregulatory nest-building behavior was immunocytochemically labeled for AVP. The low-selected mice had a 1.5-fold higher number of AVP-immunoreactive neurons in the suprachiasmatic nuclei (SCN) compared to the unselected control and the high-selected mice. No differences between the selected lines could be detected in the number of AVP-immunoreactive neurons in the paraventricular nuclei (PVN). The neuroanatomical data suggest a possible role of AVP in the SCN and control of thermoregulatory nest-building behavior. Our selected mice may prove to be a model system to study the role of AVP in the SCN.

Burrowing behavior in wild house mice: Variation within and between populations

Burrowing behavior was assessed on 120 lab-reared house mice (Mus domesticus) derived from five geographic populations representing a north-south cline along the east coast of the United States. Mice were placed individually into Plexiglas containers filled with sand and peat moss, and their burrows were excavated 24 h later. Seven measures were taken and reduced by principal-components analysis to two factors for further analysis. Marked differences existed within, but not between populations, and members of full-sib families built qualitatively and quantitatively similar burrows. The lack of a geographic cline and the apparent high heritability of burrowing behavior do not lend support to its use as a major thermoregulatory adaptation.

Genetic analyses of photoresponsiveness in the Djungarian hamster,Phodopus sungorus

SummaryEndotherms living at temperate and arctic latitudes must adjust their physiology and behavior in order to survive seasonal change. The Djungarian hamster uses photoperiod to cue annual cycles of reproduction and thermoregulation, and its responses to short photoperiod include loss of body weight and change in pelage color. Some individuals do not exhibit these responses when exposed to short days.In this study individual variation in photoresponsiveness is quantified, and four lines of evidence for a genetic component to that variation are provided. First, two separate breeding stocks differed in both the percent of animals responding to a short-day lighting regimen (SD) and in the degree and timing of their response. Second, analysis of variance within and between families of full sibs for a photoresponsive index, PI (body weightloss +2 (molt index −1)) following 12 weeks in SD demonstrated a significant family resemblance (intraclass correlation of 0.36±0.03). Third, heritability estimates from regression of offspring scores on parent scores for body weight loss, molt index and PI after 12 weeks in SD were 0.34∓0.13, 0.36±0.10 and 0.37±0.12, respectively, indicating a strong additive genetic component for the three characters. Finally, a significant response occurred after one generation of artificial selection for and against photoresponsiveness.

Genetic differences influencing behavioral temperature regulation in small mammals. I. Nesting byMus musculus

Nesting behavior was found to differ for animals of five different inbred strains ofMus musculus reared in the same environment, indicating heritable differences in level of nesting byMus. For two separate crosses, hybrid animals built larger nests than did animals of the inbred parental strains. In addition, from data of one of the crosses and derived generations, a very low heritability of nesting but substantial dominance variance were found. This pattern of results is expected of characters which have been the target of natural selection. MaleMus were found to build larger nests than females of all groups tested. These findings suggest that nesting byMus musculus represents required thermoregulatory behavior.

Breaking Through Artificial Selection Limits of an Adaptive Behavior in Mice and the Consequences for Correlated Responses

Previous divergent selection for nest-building behavior at 22 ± 1°C resulted in a 40-fold difference between the high and the low lines in amount of cotton used to build a nest. Correlated responses to selection indicated positive genetic correlations with body weight, nest-building at 4 ± 1°C, and litter size and negative genetic correlations with food consumption. At generation 46, the replicate high-selected (High 1 × High 2), randomly bred control (Control 1 × Control 2), and low-selected (Low 1 × Low 2) lines were crossed and the F1 showed significant heterosis for nest-building behavior. Regression of the F3 on the F2 generation gave heritability estimates of 0.16 ± 0.10 for the high and 0.07 ± 0.10 for the low cross, revealing a potential to break the selection limit (at least in the high direction), which had been reached at about 20 generations of selection. Indeed, renewed selection resulted in responses in both the high and the low directions of nesting, yielding realized heritabilities of 0.29 ± 0.02 and 0.30 ± 0.004, respectively. Replicated renewed selection, using the F3 generation as the base population, in the high direction of nesting resulted in correlated increases in nest-building at 4 ± 1°C, litter size, and food consumption. Body weight did not change. The positive correlation with food consumption is opposite in sign compared to the original selection experiment. This indicates that the evolutionary potential of a population to adapt to a changing environment not only depends on its current genetic variability in one adaptive trait, but may be constrained by genetic correlations changing over the course of selection.

Multiple selection responses in house mice bidirectionally selected for thermoregulatory nest-building behavior: crosses of replicate lines.

Replicate high-selected, control, and low-selected lines were crossed at generation 46 of bidirectional selection for thermoregulatory nest-building behavior. Previous analysis of the lines at their limits had revealed multiple responses to uniform selection, where each of the four selected lines responded differently to reverse selection (Laffan, 1989). The reciprocal F1 crosses showed significant heterosis for nest-building behavior compared to the contemporaneous generations of the parental lines. This pattern of heterosis in all three crosses is consistent with the finding that nest-building behavior in each of the four replicate lines had a different genetic basis, in spite of the phenotypic similarity between the two replicate lines in the high and low direction of nesting. This heterosis effect and the larger number of young weaned in all three crosses compared to their respective contemporaneous generation of the parental lines also support earlier findings that larger nests are closely related to fitness.