A strong response to selection on mass-independent maximal metabolic rate without a correlated response in basal metabolic rate.

Metabolic rates are correlated with many aspects of ecology, but how selection on different aspects of metabolic rates affects their mutual evolution is poorly understood. Using laboratory mice, we artificially selected for high maximal mass-independent metabolic rate (MMR) without direct selection on mass-independent basal metabolic rate (BMR). Then we tested for responses to selection in MMR and correlated responses to selection in BMR. In other lines, we antagonistically selected for mice with a combination of high mass-independent MMR and low mass-independent BMR. All selection protocols and data analyses included body mass as a covariate, so effects of selection on the metabolic rates are mass adjusted (that is, independent of effects of body mass). The selection lasted eight generations. Compared with controls, MMR was significantly higher (11.2%) in lines selected for increased MMR, and BMR was slightly, but not significantly, higher (2.5%). Compared with controls, MMR was significantly higher (5.3%) in antagonistically selected lines, and BMR was slightly, but not significantly, lower (4.2%). Analysis of breeding values revealed no positive genetic trend for elevated BMR in high-MMR lines. A weak positive genetic correlation was detected between MMR and BMR. That weak positive genetic correlation supports the aerobic capacity model for the evolution of endothermy in the sense that it fails to falsify a key model assumption. Overall, the results suggest that at least in these mice there is significant capacity for independent evolution of metabolic traits. Whether that is true in the ancestral animals that evolved endothermy remains an important but unanswered question.

The expression, affinity purification and characterization of recombinant Pseudomonas exotoxin 40 (PE40) secreted from Escherichia coli.

Procedures have been devised for producing high yields of purified recombinant PE40, a protein important for the development of the anti-AIDS therapeutic, sCD4-PE40. PE40 is a truncated form of the bacterial toxin, Pseudomonas exotoxin A; it lacks the cell-binding domain, but retains domains II and III that are involved in membrane translocation and inhibition of protein synthesis in eukaryotic cells. Expression vectors in Escherichia coli encoding PE40 synthesized the product as a soluble protein under control of the T7 promoter. The expression capabilities of transformants of E. coli BL21(DE3) were highly unstable. Expression levels (secreted and total) were evaluated in shake flasks and at the 10-1 scale at 27 degrees C and 37 degrees C, and following induction by IPTG or lactose. The cell-free media from the batch process was applied directly to a Cibacron blue F3GA-chromatographic medium and PE40 was eluted by nicotinamide in high yield and purity. This purification strategy was based on the structural similarity of the blue dye to NAD, a natural substrate for domain III of PE40. Green and red dye-ligand chromatography steps removed nicotinamide as well as minor residual E. coli proteins from PE40. Reversed-phase liquid chromatography peptide maps of purified PE40 were characterized by electrospray ionization mass spectrometry to determine the sequence and verify disulfide bonding.