Temperature, Osmotic Regulation and the Urinary System - PowerPoint PPT Presentation

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Title: Temperature, Osmotic Regulation and the Urinary System


1
Temperature, Osmotic Regulation and the Urinary
System
  • Chapter 50

2
Classification of Organisms
  • For many years, animals were classified according
    to whether they maintained a constant body
    temperature
  • -Homeotherms Regulate their body temperature
    about a set point
  • -Also called warm-blooded
  • -Poikilotherms Allow their body temperature to
    conform to the environment
  • -Also called cold-blooded

3
Classification of Organisms
  • Limitations to this dichotomy led to another view
    based on how body heat is generated
  • -Endotherms Use metabolism to generate body
    heat and maintain temperature above ambient
    temperature
  • -Ectotherms Do not use metabolism to produce
    heat and have body temperature that conforms to
    ambient temperature

4
Ectotherms
  • Ectotherms regulate temperature using behavior

-Insects, such as moths, use a shivering reflex
to warm thoracic muscles for flight
5
Ectotherms
  • Many marine animals, such as killer whales, limit
    heat loss in cold water using countercurrent heat
    exchange
  • -Warm blood pumped from within the body in
    arteries warms the cooler blood returning from
    the skin within veins

6
Ectotherms
7
Ectotherms
  • Reptiles place themselves in varying locations of
    sunlight and shade
  • -Some can maximize the effect of behavioral
    regulation by also controlling blood flow
  • In general, ectotherms have low metabolic rates,
    which have the advantage of low energy intake
  • -However, they are not capable of sustained
    high-energy activity

8
Endotherms
  • A high metabolic rate can be used to warm the
    endotherm if it is cold
  • The simplest way to regulate body temperature is
    by the control of blood flow to the surface of
    the animal
  • -Vasodilation increases blood flow, thereby
    increasing heat dissipation
  • -Vasoconstriction decreases blood flow, thus
    limiting heat loss

9
Endotherms
  • When ambient temperatures rise, many endotherms
    take advantage of evaporative cooling in the form
    of sweating or panting
  • The advantage of endothermy is that it allows
    sustained high-energy activity
  • -The tradeoff is that the high metabolic rate
    requires constant and high energy intake (food)

10
Endotherms
  • In animal physiology, size does matter!
  • -Smaller animals have much higher metabolic
    rates per unit body mass relative to larger
    animals
  • -Small endotherms in cold environments require
    significant insulation to maintain their body
    temperature
  • -Large endotherms in hot environments usually
    have little insulation

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12
Endotherms
  • When temperatures fall below a threshold, animals
    resort to thermogenesis, or use of normal energy
    metabolism to produce heat
  • -Shivering thermogenesis uses muscles to
    generate heat, without producing useful work
  • -Nonshivering thermogenesis alters fat
    metabolism to produce heat instead of ATP
  • -Brown fat is utilized

13
Control of Body Temperature
  • Mammalian thermoregulation is controlled by the
    hypothalamus
  • -A rise in body temperature is detected by
    neurons, which stimulate the heat-losing center
    in the hypothalamus
  • -Sympathetic nerves cause dilation of
    peripheral blood vessels, and production of
    sweat from sweat glands

14
Control of Body Temperature
  • -A drop in body temperature is detected by
    neurons, which stimulate the heat-promoting
    center in the hypothalamus
  • -Sympathetic nerves cause constriction of
    peripheral blood vessels, and inhibit sweating
    to prevent evaporative cooling
  • -Hypothalamus releases hormones that stimulate
    the thyroid to produce thyroxin, which
    stimulates metabolism

15
Control of Body Temperature
16
Control of Body Temperature
  • Pyrogens are substances that cause a rise in
    temperature
  • -Act on the hypothalamus to increase the normal
    set point to a higher temperature
  • -Produce the state we call fever
  • -A normal response to infection

17
Control of Body Temperature
  • Torpor is a state of dormancy produced by a
    reduction in both metabolic rate and body
    temperature
  • -Allows an animal to reduce the need for food
    intake
  • Hibernation is an extreme state in which torpor
    lasts for weeks or months
  • -Practiced usually by mid-sized animals

18
Osmolarity and Osmotic Balance
  • To maintain osmotic balance, the extracellular
    compartment of an animals body must be able to
    take water from and excrete excess water into the
    environment
  • -Inorganic ions must also be exchanged to
    maintain homeostasis
  • -These exchanges occur across specialized
    epithelial cells, and, in most vertebrates,
    through the kidney

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20
Osmolarity and Osmotic Balance
  • Osmotic pressure is the measure of a solutions
    tendency to take in water by osmosis
  • Osmolarity is the number of osmotically active
    moles of solute per liter of solution
  • Tonicity is the measure of a solutions ability
    to change the volume of a cell by osmosis
  • -Solutions may be hypertonic, hypotonic, or
    isotonic

21
Osmolarity and Osmotic Balance
  • Osmoconformers are organisms that are in osmotic
    equilibrium with their environment
  • -Include most marine invertebrates, and
    cartilaginous fish (sharks and relatives)
  • All other vertebrates are osmoregulators
  • -Maintain a relatively constant blood osmolarity
    despite different concentrations in their
    environment

22
Osmolarity and Osmotic Balance
  • Freshwater vertebrates are hypertonic to their
    environment
  • -Have adapted to prevent water from entering
    their bodies, and to actively transport ions back
    into their bodies
  • Marine vertebrates are hypotonic to their
    environment
  • -Have adapted to retain water by drinking
    seawater and eliminating the excess ions through
    kidneys and gills

23
Osmoregulatory Organs
  • In many animals, removal of water or salts is
    coupled with removal of metabolic wastes through
    the excretory system
  • A variety of mechanisms have evolved to
    accomplish this
  • -Single-celled protists use contractile vacuoles

24
Osmoregulatory Organs
  • Invertebrates use specialized cells tubules
  • -Flatworms use protonephridia which branch into
    bulblike flame cells
  • -Open to the outside of the body, but not to
    the inside
  • -Earthworms use nephridia
  • -Open both to the inside and outside of the
    body

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27
Osmoregulatory Organs
  • Insects use Malpighian tubules, which are
    extensions of the digestive tract
  • -Waste molecules and K are secreted into
    tubules by active transport
  • -Create an osmotic gradient that draws water
    into the tubules by osmosis
  • -Most of the water and K is then
    reabsorbed into the open circulatory
    system through hindgut epithelium

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29
Osmoregulatory Organs
  • The kidneys of vertebrates consist of thousands
    of repeating units, nephrons
  • -Create a tubular fluid by filtering the blood
    under pressure through the glomerulus
  • -Filtrate contains many small molecules, in
    addition to water and waste products
  • -Most of these molecules and water are
    reabsorbed into the blood
  • -Waste products are eliminated from
    the body in the form of urine

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Evolution of the Vertebrate Kidney
  • Kidneys are thought to have evolved among the
    freshwater teleosts, or bony fishes
  • -Body fluids are hypertonic with respect to
    surrounding water, causing two problems
  • 1. Water enters body from environment
  • -Fishes do not drink water and
    excrete large amounts of dilute urine
  • 2. Solutes tend to leave the body
  • -Reabsorb ions across nephrons

32
Evolution of the Vertebrate Kidney
  • In contrast, marine bony fishes have body fluids
    that are hypotonic to seawater
  • -Water tends to leave their bodies by osmosis
    across their gills
  • -Drink large amounts of seawater
  • -Actively transport monovalent ions out of the
    blood across the gill surfaces
  • -Excrete urine isotonic to body fluids
  • -Contains divalent cations

33
Evolution of the Vertebrate Kidney
34
Evolution of the Vertebrate Kidney
  • Cartilaginous fish, including sharks and rays,
    reabsorb urea from the nephron tubules
  • -Maintain a blood urea concentration that is 100
    times higher than that of mammals
  • -Blood is isotonic to surrounding sea
  • -These fishes do not need to drink seawater or
    remove large amounts of ions from their bodies

35
Evolution of the Vertebrate Kidney
  • The amphibian kidney is identical to that of
    freshwater fish
  • The kidneys of reptiles are very diverse
  • -Marine reptiles drink seawater and excrete an
    isotonic urine
  • -Eliminate excess salt via salt glands
  • -Terrestrial reptiles reabsorb much of the salt
    and water in their nephron tubules
  • -Dont excrete urine, but empty it into cloaca

36
Evolution of the Vertebrate Kidney
  • Mammals and birds are the only vertebrates that
    can produce urine that is hypertonic to body
    fluids
  • -Accomplished by the loop of Henle
  • Birds have relatively few or no nephrons with
    long loops, and so cannot produce urine as
    concentrated as that of mammals
  • -Marine birds excrete excess salt from salt
    glands near the eyes

37
Evolution of the Vertebrate Kidney
38
Nitrogenous Wastes
  • When amino acids and nucleic acids are
    catabolized, they produce nitrogenous wastes that
    must be eliminated from the body
  • -First step is the removal of the amino
    (-NH2) group, and its combination with H to form
    ammonia (NH3) in the liver
  • -Toxic to cells, and thus it is only safe in
    dilute concentrations

39
Nitrogenous Wastes
  • Bony fishes and amphibian tadpoles eliminate most
    of the ammonia by diffusion via gills
  • Elasmobranchs, adult amphibians, and mammals
    convert ammonia into urea, which is soluble in
    water
  • Birds, terrestrial reptiles, and insects convert
    ammonia into the water-insoluble uric acid
  • -Costs most energy, but saves most water
  • Mammals also produce uric acid, but from
    degradation of purines, not amino acids
  • -Most have an enzyme called uricase, which
    convert uric acid into a more soluble derivative
    called allantoin

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41
The Mammalian Kidney
  • Each kidney receives blood from a renal artery,
    and produces urine
  • -Urine drains from each kidney through a ureter
    into a urinary bladder
  • Within the kidney, the mouth of the ureter flares
    open to form the renal pelvis
  • -Receives urine from the renal tissue
  • -Divided into an outer renal cortex and inner
    renal medulla

42
The Mammalian Kidney
43
The Mammalian Kidney
  • The kidney has three basic functions
  • -Filtration Fluid in the blood is filtered out
    of the glomerulus into the tubule system
  • -Reabsorption Selective movement of solutes
    out of the filtrate back into the blood via
    peritubular capillaries
  • -Secretion Movement of substances from the
    blood into the extracellular fluid, then into the
    filtrate in the tubular system

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The Mammalian Kidney
  • Each kidney is made up of about 1 million
    functioning nephrons
  • Blood is carried by an afferent arteriole to a
    tuft of capillaries in cortex, the glomerulus
  • -Blood is filtered as it is forced through
    porous capillary walls

46
The Mammalian Kidney
  • Blood components that are not filtered drain into
    an efferent arteriole, which empties into
    peritubular capillaries
  • Glomerular filtrate enters the first region of
    the nephron tubules, Bowmans capsule
  • -Goes into the proximal convoluted tubule
  • -Then moves down the medulla and back up into
    cortex in the loop of Henle

47
The Mammalian Kidney
  • After leaving the loop, the fluid is delivered to
    a distal convoluted tubule in the cortex
  • -Drains into a collecting duct
  • -Merges with other collecting ducts to empty
    its contents, now called urine, into the renal
    pelvis

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49
Reabsorption and Secretion
  • Most of the water and dissolved solutes that
    enter the glomerular filtrate must be returned to
    the blood by reabsorption
  • -Water is reabsorbed by the proximal convoluted
    tubule
  • -Reabsorption of glucose and amino acids is
    driven by active transport carriers
  • Secretion of waste products involves transport
    across capillary membranes and kidney tubules
    into the filtrate

50
Excretion
  • A major function of the kidney is elimination of
    a variety of potentially harmful substances that
    animals eat and drink
  • -In addition, urine contains nitrogenous wastes,
    and may contain excess K, H and other ions that
    are removed from blood
  • Kidneys are critically involved in maintaining
    homeostasis

51
Transport in the Nephron
  • A mechanism is needed to create an osmotic
    gradient between the glomerular filtrate and the
    blood, to allow reabsorption of water
  • -Virtually all nutrient molecules in the
    filtrate, and two-thirds of the NaCl and water,
    are reabsorbed by proximal convoluted tubule
  • -Active transport of Na out of proximal
    tubule is followed by passive movement of K
    and water

52
Transport in the Nephron
  • The function of the loop of Henle is to create a
    gradient of increasing osmolarity from the cortex
    to the medulla
  • -Active extrusion of NaCl from the ascending
    loop creates an osmotic gradient
  • -Allows reabsorption of water from descending
    loop and collecting duct

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Transport in the Nephron
  • Filtrate that reaches distal convoluted tubule
    and enters the collecting duct is hypotonic
  • -The hypertonic interstitial fluid of the renal
    medulla pulls water out of the collecting duct
    and into the surrounding blood vessels
  • Kidneys also regulate electrolyte balance in the
    blood by reabsorption and secretion
  • -K, H, and HCO3

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56
Hormones Control Osmoregulation
  • Kidneys maintain relatively constant levels of
    blood volume, pressure, and osmolarity
  • -Also regulate the plasma K and Na
    concentrations and blood pH within narrow limits
  • -These homeostatic functions of kidneys are
    coordinated primarily by hormones

57
Hormones Control Osmoregulation
  • Antidiuretic hormone (ADH) is produced by the
    hypothalamus and secreted by the posterior
    pituitary gland
  • -Stimulated by an increase in the osmolarity of
    blood
  • -Causes walls of distal tubule and collecting
    ducts to become more permeable to water
  • -Increases reabsorption of water

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Hormones Control Osmoregulation
  • Aldosterone is secreted by the adrenal cortex
  • -Stimulated by low levels of Na the blood
  • -Causes distal tubule and collecting ducts to
    reabsorb Na
  • -Reabsorption of Cl and water follows
  • Low levels of Na the blood are accompanied by a
    decrease in blood volume
  • -Renin-angiotensin-aldosterone system is
    activated

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