Post on 21-Dec-2015
Lecture 25, 02 Dec 2003Chapter 15, Feeding and Digestion
Chapter 16, Energy Expenditure, Body Size
Vertebrate PhysiologyECOL 437
University of ArizonaFall 2003
instr: Kevin Boninet.a.: Bret Pasch
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Vertebrate Physiology 437
1. Feeding and Digestion (CH15)
2. ~Energy Expenditure (CH16)
3. Announcements… - Term paper 04 Dec. - Seminar write-up 09 Dec. - Powerpoint (file to us on 09 Dec.) - Oral Presentations 10 Dec. (8min) - Movie and Thanksgiving Assgt due Wed - Read Ch17 for Thurs lecture - Friday Physiology Seminar (calcium regulation in endothelial cells)
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ABSORPTION:
-Across epithelium of brush border (microvilli)-Glycocalyx has enzymes for final cleavage disaccharidases, aminopeptidases, phosphatases-Simple Diffusion
1 fat-soluble substances2 small water soluble substances through
regulated aquaporins3 down concentration or electrochemical
gradients-Facilitated Diffusion
1 monosaccharides and amino acids2 transporter proteins3 down conc. gradient or4 coupled to Na+ gradient (Na/K-
ATPase)
3
(15-37)
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ABSORPTION
-Active Transport-amino acids with ~specific
transporters coupled to Na+-Lipids
-products cross into epithelial cells (monoglycerides, fatty acids,
glycerol)-reconstructed into triglycerides-formed into chylomicrons using
cholesterol and phospholipids-chylomicrons exocytosed-taken into central lacteal and into
lymph system
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(15-38)
Lipids6
ER
Golgi
Lacteal
Nutrient Transport in Blood
-lipids (chylomicrons) into blood from lymph at thoracic duct
-sugars and amino acids into capillaries of villi-to liver via hepatic portal vein
sugars converted to glycogen for storage
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Water and Electrolyte Balance in Gut
-Lots of water and electrolytes secreted into lumen
-Need to recover
-Most via lower small intestine (ileum)-Osmotic gradient b/c absorb salts, carbos, amino acids
-Tips of villi
-Countercurrent exchange with high Na+ (Cl- follows) to facilitate water reabsorption
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(15-39)
Secretions etc.
=
9
ileum
Nu
trit
ional R
eq
uir
em
ents
… (
Ess
enti
al?
)
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Chapter 16
Energy Expenditure-temperature-size-activity
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Metabolism
-Chemical reactions in the body-Temperature dependent rates-Not 100% efficient, energy lost as heat
(not ‘lost’ if used to maintain Tb)
1. Anabolic-creation, assembly, repair, growth (positive nitrogen balance)
2. Catabolic-energy release from complex molecules (carbos, fats, proteins)-energy storage in phosphate bonds (ATP) and metabolic intermediates (glucose, lactate)
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Chemical Energy
(16-1)
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Metabolic Rate
-measurable conversion of chemical energy into heat
-used to understand:-energy budgets-dietary needs-body size implications-habitat effects-costs of various activities-mode of locomotion-cost of reproduction
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Metabolic Rates
-Basal Metabolic Rate, BMR-minimal environmental and physiological
stress (appropriate ambient temperature, post-digestive, resting etc.)
-Standard Metabolic Rate, SMR-similar to BMR, but at a given Tb
-Field Metabolic Rate, FMR-average metabolic rate of animal in natural
setting-hard to measure
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Metabolic Rates
Basal Metabolic Rate, BMR-important components:
1. Membrane form and functionmaintenance of electrochemical gradients-proton pumps in mitochondrial membranes-Na/K-ATPase pumps in plasma membrane
2. Protein synthesis
3. ATP formation
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Specific Dynamic Action (SDA)
-Metabolic Rate increases during digestion-2-3x resting metabolism in ectotherms
Think about infrequently feeding snakes...
(16-5)
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Measuring Metabolism
Direct Calorimetry-measure heat produced-known mass of water surrounding chamber-not often used (maybe for small birds,
mammals)Indirect Calorimetry
1. Bomb calorimetry (food and waste)
2. Radioisotopesdeuterium or tritium (H3) labelled wateroxygen radioisotopes (O18)(doubly-labelled water)
-measure loss of CO2 and water over time-can be used in the field-measure metabolism and water flux
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4kJ = 1kcal
Power (W)=J/s
Measuring Metabolism
Respirometry-measure O2 consumption and CO2
production-assumes primarily aerobic metabolism-closed vs. open
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4kJ = 1kcal
Power (W)=J/s
(16-3)
gills
lungs
skin
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RQ, Respiratory Quotient
RQ = Rate of CO2 production
Rate of O2 consumption
Value depends on substrate oxidized:
Energy Storage
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4kJ = 1kcal
Power (W)=J/s
RE, Respiratory Exchange Ratio
RE = instantaneous ratio of O2 consumption and CO2 production
(16-4)
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Metabolic Scope
Aerobic Metabolic Scope= max sustainable metabolic rate / BMR
-usually measured as O2 consumption-often = 10-15 x BMR-does not include anaerobic contributions-best measured at steady-state, sustainable levels
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Aerobic ScopeMammal MAS (max aerobic speed)
7.5x that of Lizard MAS (of similar body size)
Anaerobic ScopeMammal and Lizard maximal speed
equivalent at a given body mass
-ecological implications?
-both tend to increase with increasing body mass
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(16-2)
Oxygen Debt-repay anaerobic contribution to elevated
metabolism-oxidize anaerobic products (e.g., lactate)
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VO2 Measurement - Before, during, and after exercise
Thomas Hancock: data and slides
Desert Iguana
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VO
2
Time (min)
0 15 30 45
EXERCISE RECOVERY
EPOC: Excess Post-exercise Oxygen Consumption
Activity and Associated Oxygen Consumption
EEOC: Excess Exercise Oxygen Consumption
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VO
2
Time (min)
0 15 30 45
EXERCISE RECOVERY
EPOC
EEOC
TEOC = Total Excess Oxygen Consumption = EEOC + EPOC
Activity and Associated Oxygen Consumption28
Muscle Lactate
0
10
20
30
40
50
Lac
tate
(m
M)
0 2 4 6 8 10 12 14 16
Recovery Time (min)
WIF
RIF
Gastrocnemius
60
Exercise,
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Energy Budget Implications
Costs for Exercise and Recovery:- A Single Bout: 15 seconds at Maximum intensity
• Traditional Estimates: 0.7% of daily energy expenditure
• Inclusion of EPOC:4.6% of daily energy expenditure
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VO
2
Time (min)
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Length of Bout is Important:
VO
2
Time (min)
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VO
2
Time (min)
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VO
2
Time (min)
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VO
2
Time (min)
EPOC is now a large fraction of the net metabolic expenditure.
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Phylogenetic Effects
FMR (kJ/day)
(Nagy, Girard, Brown 1999)
100g mammal
100g reptile
100g bird
11.8
142
242
Energy Budgets…Ecological Role…
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Scaling Effects
Allometry - changes in body proportions as animals get larger (mouse vs. elephant)
Metabolic Rate - mass-specific metabolic rate decreases with increasing body mass
(16-6)
linear
squared
cubed
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Knut Schmidt_Nielsen 1972
(a) = elephant freaked out and died (1960’s)
-What is the correct dose?
-Importance of Scaling!
0.1mg/kg
0.2mg for 70 kg
(16-8)
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Scaling
Power Functions:
How do morphology and metabolism change with body mass?
MR = aMb
Metabolicrate
Y-intercept (of log-log plot)
Body mass
Scaling exponent
logMR = loga + b(logM)
Can look at mass-specific rates by dividing through by M
Take log of both sides
(Linearizes)
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(16-8)
MR = aMbb = 0.75(slope) logMR = loga +
b(logM)
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(16-7)
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END
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