Hypothalamic regulation of the Pituitary-Thyroid Unit in the Developing Chick Embryo

SYNOPSIS. In the chick embryo, the period of 10.0 to 13.0 daysof incubation is critical in the maturation of the hypothalamic/adenohypophysealor adenohypophyseal regulation of thyroid function; the establishmentof thyroid regulation at this time is reflected in a markedincrease in thyroid function. There has been general agreementthat the "feed-forward" and the "feed-backward" loops of theadenohypophyseal-thyroid unit are established on or about day11.5, but whether these events were the result of the establishmentof pituitary-thyroid interactions alone or included hypothalamicregulation of the pituitary-thyroid unit has until quite recentlyremained problematical. Data presented in the present reviewindicate that beginning on or about day 11.5 the hypothalamuscan and does regulate the pituitary-thyroid unit. Although thehypothalamus is essential for the maintenance of normal pituitary-thyroidfunction, the data strongly suggest that the immediate eventwhich is responsible for the establishment of a functional hypothalamoadenohypophyseal-thyroid axis in the developing chick embryo is a marked increasein adenohypophyseal thyrotrophs on day 11.5.     

Trypanosoma cruzi: Correlation of Growth Kinetics to Zymodeme Type in Clones Derived from Various Sources*†

SYNOPSIS. Trypanosoma ( Schizotrypanum ) cruzi clones were derived from isolates of an acute human case of Chagas' disease (strain Esmereldo), a human case of T. cruzi infection (strain CAN-III) and from a naturally infected opossum (strain WA-250). The isoenzyme patterns and growth rates of the clones were stable during long-term cultivation, by serial passages, of the parasites in liquid medium. Both clones of strain Esmereldo were zymodeme II; the 2 clones of strain CAN-III, zymodeme III; and the 5 clones of strain WA-250, zymodeme I. The range in doubling times of the parasite populations in liquid medium were 36–49. 7 h (strain WA-250), 117.2–133.7 h (Esmereldo clones) and 169–208 h (CAN-III clones).     

Variation in rates of nitrogen fixation in termites: response to dietary nitrogen in the field and laboratory

Abstract. Termites contribute nitrogen to their habitat through the nitrogenase activity of their bacterial symbionts. Previous studies indicate that high levels of dietary nitrogen suppress nitrogen fixation in termites. We examined the effects of dietary nitrogen on fixation rates in termites in both field and laboratory experiments. Ten field cplonies of Reticulitermes were collected and assayed for nitrogenase activity in July 1993, October 1993, January 1994, and April 1994. The nitrogen content of the wood collected with each colony was determined. There was no correlation between termite nitrogen fixation rates and the amount of nitrogen in their food for any of the four collection periods. In laboratory experiments, nitrogen fixation rates decreased when termites were fed filter paper treated with 2% and 5% ammonium nitrate or a 5% mixture of the amino acids proline, tryptophan and leucine, compared to water-treated controls. By contrast, the nitrogenase activity of termites fed filter paper treated with 2% and 5% ammonium phosphate, a mixture of the amino acids histidine, serine and aspartic acid, or 2% and 5% urea did not differ from the controls. However, nitrogenase activity increased when termites were fed with 2% uric acid. No clear association exists between termite nitrogen fixation and the nitrogen content of their food.     

Berber Culture on the World Stage: From Village to Video

Berber Culture on the World Stage: From Village to Video . Jane E. Goodman. Bloomington: Indiana University Press, 2005. 239 pp.     

Behavioral Ecology and the Transition to Agriculture

Behavioral Ecology and the Transition to Agriculture . Douglas J. Kennett and Bruce Winterhalder, eds. Berkeley: University of California Press, 2006. 394 pp.     

Stable isotopes, mesocosms and gut content analysis demonstrate trophic differences in two invasive decapod crustacea

1. Improving our understanding of dietary differences among omnivorous, benthic crustacea can help to define the scope of their trophic influence in benthic food webs. In this study, we examined the trophic ecology of two non‐native decapod crustaceans, the Chinese mitten crab (Eriocheir sinensis) (CMC) and the red swamp crayfish (Procambarus clarkii) (RSC), in the San Francisco Bay ecosystem to describe their food web impacts and explore whether these species are functionally equivalent in their impacts on aquatic benthic communities. 2. We used multiple methods to maximise resolution of the diet of these species, including N and C stable isotope analysis of field data, controlled feeding experiments to estimate isotopic fractionation, mesocosm experiments, and gut content analysis (GCA). 3. In experimental enclosures, both CMC and RSC caused significant declines in terrestrially derived plant detritus (P < 0.01) and algae (P < 0.02) relative to controls, and declines in densities of the caddisfly Gumaga nigricula by >50% relative to controls. 4. Plant material dominated gut contents of both species, but several sediment‐dwelling invertebrate taxa were also found. GCA and mesocosm results indicate that CMC feed predominantly on surface‐dwelling invertebrates, suggesting that trophic impacts of this species could include a shift in invertebrate community composition towards sediment‐dwelling taxa. 5. Stable isotope analysis supported a stronger relationship between CMC and both algae and algal‐associated invertebrates than with allochthonous plant materials, while RSC was more closely aligned with terrestrially derived detritus. 6. The trophic ecology and life histories of these two invasive species translate into important differences in potential impacts on aquatic food webs. Our results suggest that the CMC differs from the RSC in exerting new pressures on autochthonous food sources and shallow‐dwelling invertebrates. The crab's wide‐ranging foraging techniques, use of intertidal habitat, and migration out of freshwater at sexual maturity increases the distribution of the impacts of this important invasive species.     

Scaling environmental change through the community-level: a trait-based response-and-effect framework for plants

Predicting ecosystem responses to global change is a major challenge in ecology. A critical step in that challenge is to understand how changing environmental conditions influence processes across levels of ecological organization. While direct scaling from individual to ecosystem dynamics can lead to robust and mechanistic predictions, new approaches are needed to appropriately translate questions through the community level. Species invasion, loss, and turnover all necessitate this scaling through community processes, but predicting how such changes may influence ecosystem function is notoriously difficult. We suggest that community‐level dynamics can be incorporated into scaling predictions using a trait‐based response–effect framework that differentiates the community response to environmental change (predicted by response traits) and the effect of that change on ecosystem processes (predicted by effect traits). We develop a response‐and‐effect functional framework, concentrating on how the relationships among species' response, effect, and abundance can lead to general predictions concerning the magnitude and direction of the influence of environmental change on function. We then detail several key research directions needed to better scale the effects of environmental change through the community level. These include (1) effect and response trait characterization, (2) linkages between response‐and‐effect traits, (3) the importance of species interactions on trait expression, and (4) incorporation of feedbacks across multiple temporal scales. Increasing rates of extinction and invasion that are modifying communities worldwide make such a research agenda imperative.