chapter 44 regulating the internal environment. thermoregulation osmoregulation excretion...
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Chapter 44
Regulating the Internal
Environment
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• Thermoregulation• Osmoregulation• Excretion
Homeostasis
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All organisms must maintain a constant internal environment to function properly• Temperature
• pH
• ion levels
• hormones
HomeostasisHomeostasis
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Body Temperature RegulationNegative Feedback
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Coping with Environmental Fluctuations
Regulating:Endotherms are thermoregulatorsFundulus-osmoregulator
Conforming:EctothermsMany inverts- nonregulator
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Regulators & Conformers
Spider crab Libinia
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Anadromous Salmon
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Heat exchange by:• Conduction- transfer of heat between objects in
direct contact with each other• Convection- heat is conducted away from an
object of high temp to low temp
- Rate varies with different materials• Radiation- transfers heat between objects not in
direct contact
- sun energy• Evaporation- change of liquid to vapor
- cooling
Four physical processes account for heat gain or loss
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Heat exchange between an organism and its environment
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Ectotherm vs Endotherm
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Advantages of Endothermy :
• Maintains stable body temp– Cooling & heating the body
cooling and heating the body• high levels of aerobic metabolism• sustains vigorous activity for much longer than
ectotherms– Long distance running– Flight
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Disadvantages of Endothermy :
Greater food consumption to meet metabolic needs
• Human metabolic mate at 200C & at rest 1,300 to 1,800 kcal per day.
• American alligator metabolic rate at 200C & at rest 60 kcal per day at 200C.
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Mechanisms for thermoregulation• Insulation
- Fur- Hair- Feathers- Fat- Blubber
• Evaporative cooling- sweating, panting, bathing
• Shivering• Nonshivering thermogenesis & brown fat• Circulation adaptations
- Countercurrent exchange- Vasodilatation (cooling)- Vasoconstriction (heat conservation)
• Behavioral responses
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Countercurrent heat exchangers
Goose leg Dolphin flipper
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Evaporative Cooling
Hippos bathing
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Brown fat- generates heat • important in neonates, small mammals in
cold environments, and animals that hibernate
• Located in neck and in inner scapula area
Non-shivering Thermogenesis• Larges amts of heat produced by oxidizing
fatty acids in the mitochondria
Brown Fat & Non-shivering Thermogenesis
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Regulating Body Temp in Humans
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Acclimatization to New Env. Temps.
• Endotherms (birds and mammals): grow a thicker fur coat in the winter and shedding it in the summer - and sometimes by varying the capacity for metabolic heat production seasonally.
• Ectotherms compensate for changes in body temperature through adjustments in physiology and temperature tolerance.
• For example, winter-acclimated catfish can only survive temperatures at high as 28oC, but summer-acclimated fish can survive temperatures to 36oC.
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• Some ectotherms that experience subzero body temperatures protect themselves by producing “antifreeze” compounds (cryoprotectants) that prevent ice formation in the cells.– In cold climates, cryoprotectants in the body
fluids let overwintering ectotherms, such as some frogs and many arthropods and their eggs, withstand body temperatures considerably below zero.
– Cyroprotectants are also found in some Arctic and Antarctic fishes, where temperatures can drop below the freezing point of unprotected body fluids (about -0.7oC).
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• Cells can often make rapid adjustments to temperature changes.– For example, marked increases in temperature
or other sources of stress induce cells grown in culture to produce stress-induced proteins, including heat-shock proteins, within minutes.
– These molecules help maintain the integrity of other proteins that would be denatured by severe heat.
– These proteins are also produced in bacteria, yeast, and plants cells, as well as other animals.
– These help prevent cell death when an organism is challenged by severe changes in the cellular environment.
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• Torpor in Ground Squirrels– Body temperature: 37oC – Metabolic rate: 85 kcal per day.– During the eight months the squirrel is in
hibernation, its body temperature is only a few degrees above burrow temperature and its metabolic rate is very low.
Hibernation: long-term torpor as an adaptation to long-term winter cold and food shortage
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Body Temperature and metabolism during hibernation of Belding’s ground squirrel
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Osmoregulation- the control of the concentration of body fluids.
Diffusion- movement of substance from an area of greater concentration to an area of lower concentration
Osmosis- diffusion of water through a semipermeable membrane
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Adaptation to Marine EnvironmentReducing salt
• Seabird and marine iguana- nasal salt secreting gland
• Sea snake- sublingual gland• Crocodile- lacrimal gland• Fish gills- chloride cells• Shark- rectal gland
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Salt Excretion in Birds
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Nitrogenous Waste Excretion
• Ammonia- toxic- Excrete directly into water- jellies- Detoxifyurea
• Urea- need lots of water to get rid of• Uric Acid- birds & reptiles
- more costly to produce than urea, but needs less water to be removed
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Strategies to remove Nitrogenous Waste
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• Osmoconformer: isoosmotic
• Osmoregulator: hyper-, hypo-,
ureoosmotic
• Euryhaline: wide tolerance range
• Stenohaline: narrow tolerance range
Balancing NaCl in Blood
Osmols- total solute concentration in moles of solute/liter of solution
Osmols- total solute concentration in moles of solute/liter of solution
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Marine Fish: hypoosmotic
H2O continually leaves body
continually drinks seawater
excretes salt through gills produces small
amts of dilute urine
Less salt than external
environment
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Freshwater Fish: hyperosmotic
H2O continually enters body
does not drinks water
produces large amts of dilute urine
More salt than external
environment
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Shark and Coelacanth: ureoosmotic
Maintains high levels of urea and TMAO in blood
excretes salt through rectal gland
coelacanth Rana cancrivora
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Hagfish: ionosmotic
nonregulator
Seawater concentration = internal concentration
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Osmolarity- measure of total solutes(dissolved particles)
Ions FW m osmol/l SW m osmol/lNa+ 1 470 Cl- 1 550Ca++ variable 10 Total 10 1000
Osmolarity in Freshwater and Saltwater
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Habitat Na+ Cl- Urea
seawater sw 478 558
hagfish (Myxine) sw 537 542
lamprey fw 120 96
Goldfish (Carassius) fw 115 107
Toadfish (Opsanus) sw 160
Crab-eating frog (Rana) sw 252 227 350
Dogfish sw 287 240 354
freshwater ray fw 150 149 <1
coelacanth sw 197 199 350
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Adaptations to Dry Environment
• Many desert animals don’t drink water
• Kangaroo rats lose so little water that they can recover 90% of the loss from metabolic water and gain the remaining 10% in their diet of seeds.
• Also have long loop of Henle
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• Most excretory systems produce a filtrate by pressure-filtering body fluids into tubules.
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• Flatworms have an excretory system called protonephridia, consisting of a branching network of dead-end tubules.– The flame bulb draws water
and solutes from the interstitial fluid, through the flame bulb, and into the tubule system.
Diverse excretory systems are variations on a tubular theme
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• Metanephridia consist of internal openings that collect body fluids from the coelom through a ciliated funnel, the nephrostome, and release the fluid through the nephridiopore.– Found in most annelids, each segment of a
worm has a pair of metanephridia.
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• Insects and other terrestrial arthropods have organs called Malpighian tubules that remove nitrogenous wastes and also function in osmoregulation.– These open into the
digestive system and dead-end at tips that are immersed in the hemolymph.
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Nephron
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Hormonal Control via Negative Feedback
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Hormonal Control