Non-linear scaling of oxygen consumption and heart rate in a very large cockroach species (Gromphadorhina portentosa): Correlated changes with body size and temperature Article

Streicher, JW, Cox, CL, Birchard, GF. (2012). Non-linear scaling of oxygen consumption and heart rate in a very large cockroach species (Gromphadorhina portentosa): Correlated changes with body size and temperature . JOURNAL OF EXPERIMENTAL BIOLOGY, 215(7), 1137-1143. 10.1242/jeb.061143

cited authors

  • Streicher, JW; Cox, CL; Birchard, GF

authors

abstract

  • Although well documented in vertebrates, correlated changes between metabolic rate and cardiovascular function of insects have rarely been described. Using the very large cockroach species Gromphadorhina portentosa, we examined oxygen consumption and heart rate across a range of body sizes and temperatures. Metabolic rate scaled positively and heart rate negatively with body size, but neither scaled linearly. The response of these two variables to temperature was similar. This correlated response to endogenous (body mass) and exogenous (temperature) variables is likely explained by a mutual dependence on similar metabolic substrate use and/or coupled regulatory pathways. The intraspecific scaling for oxygen consumption rate showed an apparent plateauing at body masses greater than about 3 g. An examination of cuticle mass across all instars revealed isometric scaling with no evidence of an ontogenetic shift towards proportionally larger cuticles. Published oxygen consumption rates of other Blattodea species were also examined and, as in our intraspecific examination of G. portentosa, the scaling relationship was found to be non-linear with a decreasing slope at larger body masses. The decreasing slope at very large body masses in both intraspecific and interspecific comparisons may have important implications for future investigations of the relationship between oxygen transport and maximum body size in insects. © 2012. Published by The Company of Biologists Ltd.

publication date

  • April 1, 2012

published in

Digital Object Identifier (DOI)

start page

  • 1137

end page

  • 1143

volume

  • 215

issue

  • 7