Variation in Intergroup Encounters in Two Populations of Japanese Macaques

The nature of intergroup encounters differed between two populations of wild Japanese macaques (Macaca fuscata): the Yakushima and Kinkazan populations. In the Yakushima population, intergroup encounters were more likely to result in the displacement of one group, intergroup agonistic interaction was common, and intergroup dominance was usually distinct. When displacement occurred at Yakushima, larger groups tended to dominate smaller ones. Conversely, in the Kinkazan population, intergroup encounters rarely resulted in displacement, intergroup agonistic interaction was rare, and intergroup dominance was usually unclear. Thus, monkeys in Yakushima appear to defend resources actively during encounters, while those in Kinkazan usually did not defend resources. The frequency of encounters was significantly higher in Yakushima than in Kinkazan. The two populations had very different group densities and traveling speeds, both of which directly influence the chance of encounters. Taking these differences into account, we compared the observed frequency with those predicted by the ideal gas model. The observed frequencies in both populations were about one-third of the number expected with the model, which suggests that the differences in encounter frequency were caused by differences in group density and traveling speed. We discuss this intraspecific variation in light of economic defendability in connection to habitat differences and the evolutionary significance of resource defense behavior.     

Genetic Studies of Membrane Excitability in Drosophila: Lethal Interaction between Two Temperature-Sensitive Paralytic Mutations

Two mutants of Drosophila melanogaster, para ^ts1 (1-53.9) and nap^ts (2-56.2) both display similar temperature-sensitive paralysis associated with blockage in the conduction of nerve action potentials, suggesting that the two gene products have a similar function. This idea is supported by the observation that the double mutant is unconditionally lethal. Genetic analysis of this synergistic interaction has revealed the following: 1) it specifically involves the para and nap loci; (2) all para alleles interact with nap^ts, but the strength of the interaction varies in an allele-dependent fashion; (3) lethality of the double mutant occurs during the first larval instar with para^ts1 but differs with other para alleles; (4) hypodosage of para ⁺ causes lethality in a nap^ts background. These results together with previous electrophysiological, behavioral and pharmacological studies of these mutants suggest that both para and nap affect sodium channels and possibly encode different subunits.     

Development Anthropology: Encounters in the Real World

Development Anthropology: Encounters in the Real World. Riall Nolan. Cambridge: Westview Press, 2002. 345 pp.     

Studies on the mechanism of thrombin. Interaction with fibrin

Fibrin monomer Sepharose was used to investigate the interactions of thrombin with fibrin. Thrombin binding was found to be reversible and saturable and to depend on the thrombin: fibrin ratio. Scatchard analysis indicated a single class of binding sites with K alpha = 4.9 X 10(5) M-1. Ca2+ ions caused rapid desorption and elution of thrombin from fibrin monomer, and the Ca2+ concentration needed for maximal desorption depended on the fibrin:thrombin ratio. Mg2+, Mn2+, and Sr2+ also released thrombin from fibrin monomer but not as efficiently as Ca2+. These results indicate that divalent metal ions induce a physical change in fibrin monomer which results in desorption of thrombin. Thrombin binding to fibrin in a gel was compared to binding to fibrin monomer. These studies showed that as fibrin monomers polymerize to form the gel network, thrombin is released. Under static conditions the released thrombin remains associated with the gel because diffusion is limited by the gel. However, the thrombin can be readily removed when buffer is allowed to flow through the gel. These results lead to the possibility that thrombin binding to fibrin monomer and its subsequent release, either by Ca2+ or by polymerization, may have important consequences for regulating the effective thrombin concentration in vivo.