Ecological factors affect the level and scaling of avian BMR.

The basal rate of metabolism (BMR) in 533 species of birds, when examined with ANCOVA, principally correlates with body mass, most of the residual variation correlating with food habits, climate, habitat, a volant or flightless condition, use or not of torpor, and a highland or lowland distribution. Avian BMR also correlates with migratory habits, if climate and a montane distribution is excluded from the analysis, and with an occurrence on small islands if a flightless condition and migration are excluded. Residual variation correlates with membership in avian orders and families principally because these groups are behaviorally and ecologically distinctive. However, the distinction between passerines and other birds remains a significant correlate of avian BMR, even after six ecological factors are included, with other birds having BMRs that averaged 74% of the passerine mean. This combination of factors accounts for 97.7% of the variation in avian BMR. Yet, migratory species that belong to Anseriformes, Charadriiformes, Pelecaniformes, and Procellariiformes and breed in temperate or polar environments have mass-independent basal rates equal to those found in passerines. In contrast, penguins belong to an order of polar, aquatic birds that have basal rates lower than passerines because their flightless condition depresses basal rate. Passerines dominate temperate, terrestrial environments and the four orders of aquatic birds dominate temperate and polar aquatic environments because their high BMRs facilitate reproduction and migration. The low BMRs of tropical passerines may reflect a sedentary lifestyle as much as a life in a tropical climate. Birds have BMRs that are 30-40% greater than mammals because of the commitment of birds to an expensive and expansive form of flight.

An analysis of the factors that influence the level and scaling of mammalian BMR.

The factors influencing the basal rate of metabolism (BMR) in 639 species of mammals include body mass, food habits, climate, habitat, substrate, a restriction to islands or highlands, use of torpor, and type of reproduction. They collectively account for 98.8% of the variation in mammalian BMR, but often interact in complex ways. The factor with the greatest impact on BMR, as always, is body mass (accounting for 96.8% of its variation), the extent of its impact reflecting the 10(6.17)-fold range of mass in measured species. The attempt to derive mathematically the power relationship of BMR in mammals is complicated by the necessity to include all of the factors that influence BMR that are themselves correlated with body mass. BMR also correlates with taxonomic affiliation because many taxa are distinguished by their ecological and behavioral characteristics. Phylogeny, reflecting previous commitments, may influence BMR either through a restriction on the realized range of behaviors or by opening new behavioral and ecological opportunities. A new opportunity resulted from the evolution by eutherians of a type of reproduction that permitted species feeding on high quality resources to have high BMRs. These rates facilitated high rates of gas, nutrient, and waste exchange between a pregnant eutherian and her placental offspring. This pattern led to high rates of reproduction in some eutherians, a response denied all monotremes and marsupials, thereby permitting eutherians to occupy cold-temperate and polar environments and to dominate other mammals in all environments to which ecologically equivalent eutherians had access.