1 / 13

Whole-Animal Metabolism

Whole-Animal Metabolism. Animals require chemical energy for: activity (muscular work) synthetic activities heat production (in endotherms). How can we determine how much energy an organism requires and uses for these activities?. Burn 1 mol (180g) of glucose in a calorimeter*:

ethan-strickland
Download Presentation

Whole-Animal Metabolism

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Whole-Animal Metabolism • Animals require chemical energy for: • activity (muscular work) • synthetic activities • heat production (in endotherms) How can we determine how much energy an organism requires and uses for these activities?

  2. Burn 1 mol (180g) of glucose in a calorimeter*: 1 mol glucose + 6 mol O2 6 mol CO2 + 6 mol H2O + 686 kcal (heat) Metabolize 1 mol of glucose aerobically in an animal: 1 mol glucose + 6 mol O2 + 38 mol ADP + 38 mol Pi 6 mol CO2 + 42 mol H2O + 38 mol ATP + 423 kcal heat 266 kcal Look at heat production: www.umr.edu/-gbert/animation.html

  3. Eventually, all the chemical energy in the organism will be released as heat - regardless of the food source. Therefore, Rate of heat production = Metabolic rate = Em Holds for all organisms that are not growing

  4. 1 mol glucose + 6 mol O2 + 36 mol ADP + 36 mol Pi 6 mol CO2 + 42 mol H2O + 36 mol ATP + 423 kcal Again, assuming an organism is respiring aerobically, what alternative measures might we use to approximate the metabolic rate? Hint: Answer? Oxygen consumption Carbon dioxide expiration

  5. Carbohydrates C6H12O6 + 6 O2 6 CO2 + 6 H2O Fat 2 C51H98O6 + 145 O2 102 CO2 + 98 H2O R.Q. = 0.80 Oxygen/carbon dioxide relationships Ratio of CO2 prod. / O2 consumed = respiratory quotient = R.Q. R.Q. = 6 CO2/ 6 O2 = 1.00 R.Q. = 102 CO2 / 145 O2 = 0.70 Protein

  6. 1 Joule = 0.239 cal Kcal/liter O2 ______ 5.0 4.7 4.5 if you wish, you can use 4.8 kcal • l O2-1) Assumes a mixed diet

  7. Numerous physical and behavioral factors affect metabolic rate: • size • temperature & season • hibernation & torpor • salinity • photoperiod & tidal cycle • pressure of oxygen • activity

  8. Definitions: • Basal metabolic rate (BMR) - minimal rate of metabolism • for a fasting, inactive individual (with no heat prod. • for homeotherm). • Standard metabolic rate (SMR) - rate for an individual • at rest at a given temperature. • Active metabolic rate (AMR) - rate for forced, maximal • activity at a given temperature.

  9. In humans, VO2 can increase 15-20 X during exercise • In insects, VO2 can increase 50-200 X during flight: • Activity vs. VO2 Locomotion is expensive:

  10. SMR • VO2’ activity (e.g. swimming speed)

  11. Goldfish (ml O2 • kg-1 • h-1) 280 40 AMR • VO2’ SMR 0 40 Temp. (°C) Metabolic Scope for Activity = AMR / SMR Expressed as dimensionless value (e.g., 8)

  12. VO2 liters O2 • kg-1 • h-1 C.L. = = = liters O2 • kg-1 • km-1 velocity km • h-1 Salmon C.L. 0 1 2 3 4 velocity (lengths • s-1) Cost of Locomotion

  13. running flying swimming C.L. 0.1 1 10 100 1000 10000 Body Mass (kg)

More Related