Deck 44: Osmoregulation and Excretion

A) wet rain forest
B) desert
C) prairie
D) chaparral

A) excrete large quantities of electrolytes
B) consume large quantities of water
C) excrete large quantities of water
D) take in electrolytes through simple diffusion

A) liver from NH₃ and carbon dioxide
B) liver from glycogen
C) kidneys from glycerol and fatty acids
D) bladder from uric acid and water

A) distilled water
B) blood in birds
C) blood in mammals
D) seawater in a tidal pool

A) They actively transport salt into the animal through the gills.
B) They mediate the movement of water from seawater through the gills.
C) They are involved in excretion of excess salt.
D) They allow the fish to produce dilute urine.

A) 0.0 mM sucrose
B) 0.05 mM saline
C) 0.08 mM sucrose
D) 1.0 mM saline

A) High urea and trimethylamine oxide concentrations keep shark tissues slightly hyperosmotic relative to seawater, so water is absorbed passively.
B) Sodium, chloride, and potassium do not influence water balance in shark tissues.
C) Shark blood is hypotonic to the surrounding tissues, so water always moves passively into the tissue from the blood.
D) Sharks excrete large quantities of salt through their gills in exchange for water

A) the concentration gradient; ADP
B) the concentration gradient; ATP
C) transmembrane pumps; electron transport
D) phosphorylated protein carriers; ATP

A) insoluble in water
B) the primary nitrogenous waste product of humans
C) the primary nitrogenous waste product of most birds
D) the primary nitrogenous waste product of most aquatic invertebrates

A) ammonia
B) ammonium ions
C) urea
D) uric acid

A) loss of water by osmosis from cells in vital organs resulted in cell death and organ failure
B) high amounts of salt had diffused into the fish's cells, causing them to swell and lyse
C) the kidneys were not able to keep up with the water removal necessary in this hyperosmotic environment, creating an irrevocable loss of homeostasis
D) the gills became encrusted with salt, resulting in inadequate gas exchange and a resulting asphyxiation

A) using their gills and kidneys to rid themselves of sea salts
B) monitoring dehydration at the cellular level with special gated aquaporins
C) tolerating high urea concentrations that are balanced with internal salt concentrations to seawater osmolarity
D) synthesizing trimethylamine oxide, a chemical that binds and precipitates salts inside cells

A) it is less metabolically expensive to produce compared to other waste products
B) it has a low solubility in water and is less toxic to the embryo than other forms of waste
C) it requires less energy to transport across the egg shell
D) it can be recycled by the embryo to make new protein

A) hyperosmotic; freshwater
B) hyperosmotic; seawater
C) isoosmotic; seawater
D) hypoosmotic; seawater

A) hyperosmotic
B) hypoosmotic
C) isoosmotic
D) both hyperosmotic and isoosmotic

A) The rectal gland functions in the ocean water, and chloride cells function in fresh water.
B) The salt transport mechanisms of the gill epithelia change during migration.
C) Salmon in fresh water excrete concentrated urine, and salmon in salt water secrete dilute urine.
D) Their metabolism changes in salt water to degrade electrolytes.

A) only I and III
B) only II and III
C) only I and II
D) I, II, and III

A) a condition called diabetes, where excessive urine formation occurs
B) a condition of insatiable thirst and excessive urine formation
C) gout, a painful inflammatory disease that primarily affects the joints
D) osteoarthritis, an inevitable consequence of aging

A) it was stressed and needed more time to acclimate to the new conditions
B) it was so hypertonic to the fresh water that it could not osmoregulate
C) its kidney had ruptured
D) its cells dehydrated and lost the ability to metabolize

A) large Bowman's capsule
B) absence of proximal tubule
C) limited branching of vasa recta
D) long loop of Henle

A) A
B) B
C) C
D) E

A) frogs
B) kangaroo rats
C) humans
D) freshwater bass

A) starch and cellulose
B) triglycerides and steroids
C) proteins and nucleic acids
D) phospholipids and glycolipids

A) flatworms
B) insects
C) jellyfish
D) sea stars

A) protonephridium-earthworm
B) Malpighian tubule-frog
C) flame bulb-flat worm
D) exchange across the body surface-snake

A) Potassium transport is a passive process.
B) Movement of potassium into the lumen of the Malpighian tubules is an energy-requiring process.
C) Potassium moves out of the tubules at a faster rate than it moves into the lumen of the tubules.
D) Sodium ions will follow potassium ions.

A) Water would be forced out of the lumen of the Malpighian tubules through an osmotic gradient.
B) The potassium gradient would have no effect on water movement.
C) There would be a net movement of water into the lumen of the tubules.
D) Water would be conserved, forming a hypertonic solution in the Malpighian tubules.

A) The kidneys require constant and abnormally high oxygen supply to function.
B) The renal artery delivers blood with nitrogenous waste to the kidney and the renal vein brings blood with less nitrogenous wastes away from the kidneys.
C) The kidneys require higher than normal levels of hormones.
D) The renal artery and vein are the main pathways regulating how much is produced by the kidneys.

A) results from active transport
B) transfers large molecules as easily as small ones
C) is very selective as to which sub-protein-sized molecules are transferred
D) is mainly a consequence of blood pressure in the capillaries of the glomerulus

A) protonephridia
B) metanephridia
C) Malpighian tubules
D) nephrons

A) filtration
B) reabsorption
C) active transport
D) secretion

A) Urea takes less energy to synthesize than ammonia.
B) Small, stagnant pools do not provide enough water to dilute the toxic ammonia.
C) The highly toxic urea makes the pool uninhabitable to potential competitors.
D) Urea makes lungfish tissue hypoosmotic to the pool.

A) is readily soluble in water
B) is metabolically less expensive to synthesize than other excretory products
C) requires little water for nitrogenous waste disposal, thus reducing body mass
D) can be reused by birds as a protein source

A) urea can be removed as a semi-solid paste
B) urea is less toxic than ammonia
C) urea does not affect the osmotic gradient
D) less nitrogen is removed from the body

A) the vasa recta
B) Bowman's capsule
C) the proximal tubule
D) the collecting duct

A) they have membranes of varying permeability to water
B) they operate an extensive set of active-transport ion pumps
C) they are the body's only means of shedding excess nutrients
D) they have an abundance of myogenic smooth muscle

A) flame-bulb system of flatworms
B) protonephridia of rotifers
C) Malpighian tubules of insects
D) kidneys of vertebrates

A) filtration
B) reabsorption
C) secretion
D) excretion

A) reabsorption of nutrients from a filtrate
B) selective elimination of excess ions and toxins from body fluids
C) formation of an osmotic gradient along an excretory structure
D) expulsion of urine from the body

A) increased aldosterone production
B) increased blood pressure
C) inhibited secretion of antidiuretic hormone (ADH)
D) increased reabsorption of water in the proximal tubule

A) A
B) B
C) C
D) D

A) All of these conditions contribute to the osmolarity of the medulla.
B) I, II, and III
C) I and IV
D) I, II, and IV

A) B
B) C
C) D
D) E

A) juxtamedullary nephrons
B) urinary bladders
C) ureters
D) podocytes

A) absorptive processes taking place in the loop of Henle are hormonally regulated
B) differential permeabilities of ascending and descending limbs of the loop of Henle are important in establishing an osmotic gradient
C) the loop of Henle plays an important role in detoxification
D) additional filtration takes place along the loop of Henle

A) is intimately associated with a capillary network.
B) functions in both osmoregulation and excretion.
C) receives filtrate from blood instead of coelomic fluid.
D) has a transport epithelium.

A) a river otter
B) a mouse species living in a tropical rain forest
C) a mouse species living in a temperate broadleaf forest
D) a mouse species living in a desert

A) achieves the conversion of toxic ammonia to less toxic urea
B) maintains homeostasis of pH in body fluids
C) regulates the speed of blood flow through the nephrons
D) reabsorbs urea to maintain osmotic balance

A) filtration
B) reabsorption
C) active transport
D) secretion

A) a drink with a combination of water and electrolytes
B) caffeinated beverages
C) bottled water kept at room temperature
D) bottled water that had been frozen to ensure that it would be as cold as possible

A) are the largest epithelial cells in the body
B) are not in contact with interstitial fluid
C) have plasma membranes of low permeability to water
D) are not affected by high levels of nitrogenous wastes

A) angiotensinogen
B) renin
C) antidiuretic hormone
D) atrial natriuretic peptide

A) only in B
B) only in B and D
C) in B, C, and E
D) Passive water reabsorption occurs throughout all of the nephron.

A) drinking lots of pure water
B) sweating-induced dehydration increases plasma osmolarity
C) eating a small sugary snack
D) blood pressure becomes abnormally high

A) H⁺ pumping to control pH
B) reabsorption mechanisms along the proximal tubule
C) filtration from the glomerular capillaries
D) secretion along the distal tubule

A) produce excessive antidiuretic hormone to remove more water but hold back salts
B) passively excrete excess water in order to remove the high concentration of ingested salt
C) release atrial natriuretic peptide to decrease blood pressure
D) risk becoming overhydrated within twelve hours

A) ADH regulates the osmolarity of the blood by altering renal reabsorption of water, and the RAAS maintains the osmolarity of the blood by stimulating both Na⁺ and water reabsorption.
B) ADH and the RAAS work antagonistically; ADH stimulates water reabsorption during dehydration, and the RAAS causes increased excretion of water when it is in excess in body fluids.
C) Both stimulate the adrenal gland to secrete aldosterone, which increases both blood volume and pressure via its receptors in the urinary bladder.
D) ADH and the RAAS combine at the receptor sites of proximal tubule cells, where reabsorption of essential nutrients takes place.

A) decrease, and the urine would be hypoosmotic compared to plasma
B) increase, and the urine would be isoosmotic compared to plasma
C) increase, and the urine would be hyperosmotic compared to plasma
D) decrease, and the urine would be isoosmotic compared to plasma

A) sleeping for one hour
B) severe sweating on a hot day
C) eating a pizza with olives and pepperoni
D) drinking several glasses of water

A) Urea takes less energy to synthesize than ammonia.
B) Small stagnant pools do not provide enough water to dilute ammonia, which is toxic.
C) Urea forms an insoluble precipitate.
D) Urea makes lungfish tissue hypoosmotic to the pool.

A) vampire bat
B) salmon in fresh water
C) marine bony fish
D) freshwater flatworm

A) active transport of salt from the upper region of the ascending limb.
B) the spatial arrangement of juxtamedullary nephrons.
C) diffusion of urea from the collecting duct.
D) diffusion of salt from the descending limb of the loop of Henle.

A) a river otter
B) a mouse species living in a temperate broadleaf forest
C) a mouse species living in a desert
D) a beaver