Meeting Abstract
85.2 Sunday, Jan. 6 Temperature dependent variation in respiratory patterns and spiracular control in Rhodnius prolixus HEINRICH, EC*; BRADLEY, TJ; Univ. of California, Irvine; Univ. of California, Irvine eheinric@uci.edu
Our current understanding of insect respiratory control indicates that spiracular activity is regulated by two interacting feedback loops which monitor and respond to changes in internal pCO2 and pO2. Spiracles open when pCO2 reaches a critically high threshold (2-6 kPa) or when pO2 becomes critically low (4-5 kPa). Given that the spiracles open in response to a specific pCO2, the volume of CO2 released in a burst by a discontinuously respiring insect should remain constant independent of metabolic rate. However, previous studies which manipulated metabolic rate via temperature found that burst volume decreases at higher temperatures. We used Rhodnius prolixus to determine if this variation is caused by changes in metabolic rate or by an effect of temperature on spiracular control. We increased metabolic rate by either increasing ambient temperature or by feeding Rhodnius a bloodmeal. Burst volume decreased significantly as temperature increased from 18°C to 38°C (ANOVA, F=89.58, p<0.001) but showed no relationship to metabolic rate in fed animals measured at 24°C (BV= -0.0016MR + 0.0243, R2=0.0015). Burst duration and time between bursts decreased in both treatment groups. Additionally, insects that experienced temperature variation abandoned discontinuous respiration at lower metabolic rates than those in the fed treatment group. Our study suggests that the set point at which the spiracles open in response to CO2 is dependent on ambient temperature. It is clear that the respiratory patterns produced by insects are influenced by both temperature and metabolic rate. These results provide a window for examining the mechanisms by which insects sense and respond to pCO2 and pO2. This work was supported by the NSF grant IOS-0920683 (TJB).