Deck 44: Osmoregulation and Excretion

A) osmoregulate without using a transport epithelium for this purpose.
B) drink seawater and secrete excess ions through their kidneys only.
C) drink seawater and secrete excess ions mainly through their nasal salt glands.
D) have plasma that is isoosmotic to ocean water.
E) obtain water by eating only osmoregulating prey.

A) hyperosmotic; freshwater
B) isotonic; freshwater
C) hyperosmotic; saltwater
D) isoosmotic; saltwater
E) hypoosmotic; saltwater

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

A) is made in the kidneys and immediately excreted.
B) is added to the air in the lungs to be exhaled, along with carbon dioxide.
C) is made in the liver by combining two ammonia molecules with one carbon dioxide.
D) is made in the pancreas and added to the intestinal contents, along with bile salts, for excretion.
E) is rarely the nitrogenous waste of choice.

A) is soluble in water.
B) can be stored in the body as a precipitate.
C) has low toxicity relative to urea.
D) is metabolically more expensive to synthesize than urea.
E) is the major nitrogenous waste excreted by insects.

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.
E) brain cells lysed as a result of increased osmotic pressure in this hyperosmotic environment, leading to death by loss of autonomic function.

A) will thrive under such conditions, as long as he has lived at the ocean most of his life.
B) will excrete more water molecules than taken in, because of the high load of ion ingestion.
C) will develop structural changes in the kidneys to accommodate the salt overload.
D) will find that drinking saltwater satiates his thirst.
E) will risk becoming overhydrated within 12 hours.

A) distilled water.
B) plasma in birds.
C) plasma in mammals.
D) seawater in a tidal pool.
E) estuarine water.

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) the absence of urea in the urine.
E) osteoarthritis, an inevitable consequence of aging.

A) by migrating to freshwater rivers to drink fresh water.
B) via osmosis, as their body cells are slightly hyperosmotic to seawater.
C) via active transport of water across the cells on their gills.
D) by water diffusion from seawater, which is hyperosmotic to the fluids in their cells.
E) by selective transport of water molecules across the wall of the gut.

A) it was stressed and needed more time to acclimate to the new conditions.
B) it was so hyperosmotic to the fresh water that it could not osmoregulate.
C) the sea star's kidneys could not handle the change in ionic content presented by the fresh water.
D) its contractile vacuoles ruptured.
E) its cells dehydrated and lost the ability to metabolize.

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

A) liver from NH₃ and CO₂.
B) liver from glycogen.
C) kidneys from glucose.
D) kidneys from glycerol and fatty acids.
E) bladder from uric acid and H₂O.

A) urea can be exchanged for Na⁺.
B) urea is less toxic than ammonia.
C) urea requires more water for excretion than ammonia.
D) urea does not affect the osmolar gradient.
E) less nitrogen is removed from the body.

A) found in freshwater lakes and streams.
B) marine.
C) amphibious.
D) found in arid terrestrial environments.
E) found in terrestrial environments with adequate moisture.

A) loss of water through the gills.
B) gain of salt through the gills.
C) loss of water in the urine.
D) no drinking of water.
E) gain of water through food.

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 balance internal salt concentrations to seawater osmolarity.
D) synthesizing trimethylamine oxide, a chemical that binds and precipitates salts inside cells.
E) possessing a special adaptation that allows their cells to operate at an extraordinarily high salt concentration.

A) insoluble in water.
B) more toxic to human cells than ammonia.
C) the primary nitrogenous waste product of humans.
D) the primary nitrogenous waste product of most birds.
E) the primary nitrogenous waste product of most aquatic invertebrates.

A) lots of fresh water flowing across the gills of a fish.
B) lots of seawater, such as a bird living in a marine environment.
C) lots of seawater, such as a marine mammal (e.g., a polar bear).
D) a terrestrial environment, such as that supporting crickets.
E) a moist system of burrows, such as those of naked mole rats.

A) protonephridia.
B) metanephridia.
C) Malpighian tubules.
D) nephrons.
E) ananephredia.

A) the vasa recta.
B) Bowman's capsule.
C) the loop of Henle.
D) the proximal tubule.
E) the collecting duct.

A) of high solute concentration, in order to conserve body fluids.
B) of very low volume, in order to conserve body fluids.
C) of high solute concentration and very low volume, in order to conserve body fluids.
D) of high solute concentration and of high volume, matching their normal fluid uptake.
E) of low solute concentration and of high volume, matching their normal fluid uptake.

A) mice and birds
B) insects and birds
C) lions and horses
D) humans and frogs
E) fish and turtles

A) bicarbonate ions.
B) sodium ions.
C) glucose.
D) ammonia.
E) NaOH.

A) ammonia.
B) nitrate.
C) nitrite.
D) urea.
E) uric acid.

A) flatworms.
B) earthworms.
C) insects.
D) vertebrates.
E) cnidarians.

A) amino acids
B) urea
C) uric acid
D) ammonia
E) nitrogen gas

A) earthworms.
B) flatworms.
C) insects.
D) jellyfish.
E) sea stars.

A) the loop of Henle.
B) the collecting duct.
C) Bowman's capsule.
D) the proximal tubule.
E) the glomerulus.

A) frogs.
B) kangaroo rats.
C) humans.
D) desert tortoises.
E) birds.

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

A) flame bulb system of flatworms.
B) protonephridia of rotifers.
C) metanephridia of earthworms.
D) Malpighian tubules of insects.
E) kidneys of vertebrates.

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) excretion allows birds to live in desert environments.

A) protonephridia.
B) metanephridia.
C) Malpighian tubules.
D) nephrons.
E) ananephredia.

A) metanephridium-flatworm
B) Malpighian tubule-frog
C) kidney-insect
D) flame bulb-snake
E) direct cellular exchange-marine invertebrate

A) starch and cellulose.
B) triglycerides and steroids.
C) proteins and nucleic acids.
D) phospholipids and glycolipids.
E) fatty acids and glycerol.

A) results from active transport.
B) transfers large molecules as easily as small ones.
C) is very selective as to which subprotein-sized molecules are transferred.
D) is mainly a consequence of blood pressure in the capillaries of the glomerulus.
E) usually includes the transfer of red blood cells into Bowman's capsule.

A) filtration
B) ultrafiltration
C) selective reabsorption
D) secretion
E) active transport

A) protonephridia.
B) metanephridia.
C) Malpighian tubules.
D) nephrons.
E) ananephredia.

A) ions.
B) glucose.
C) plasma proteins.
D) amino acids.
E) dissolved gasses.

A) 30 mosm/L.
B) 100 mosm/L.
C) 200 mosm/L.
D) 300 mosm/L.
E) 500 mosm/L.

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

A) loops of Henle.
B) distal convoluted tubules.
C) Bowman's capsules.
D) proximal convoluted tubules.
E) glomeruli.

A) juxtamedullary nephrons.
B) Bowman's capsules.
C) ureters.
D) podocytes.
E) urinary bladders.

A) can be four times as great as normal osmolarity of human plasma.
B) is always exactly equal to plasma osmolarity.
C) is always less than plasma osmolarity.
D) is always greater than plasma osmolarity.
E) is determined primarily by the concentration of glucose.

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

A) increased aldosterone production.
B) increased blood pressure.
C) inhibited secretion of antidiuretic hormone (ADH).
D) increased reabsorption of water in the proximal tubule.
E) the osmoregulator cells of the brain increasing their activity.

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

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) have 50% of their cell mass made of smooth endoplasmic reticulum.
E) are not affected by high levels of nitrogenous wastes.

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

A) hydrogen ions are actively moved into the filtrate.
B) the sodium transporter exchanges one hydrogen ion for each sodium ion.
C) excreted plasma proteins are nearly all acidic ions.
D) excreted amino acids are in abundance.
E) potassium and sodium exchange generates lots of acidity.

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

A) drinking lots of pure water.
B) sweating-induced dehydration increases plasma osmolarity.
C) ingestion of ethanol (drinking alcoholic drinks).
D) eating a small sugary snack.
E) blood pressure is abnormally high.

A) stimulating the reabsorption of glucose through channel proteins.
B) triggering the synthesis of an enzyme that makes the phospholipid bilayer more permeable to water.
C) causing membranes to include more phospholipids that have unsaturated fatty acids.
D) causing an increase in the number of aquaporin molecules of collecting duct cells.
E) decreasing the speed at which filtrate flows through the nephron, leading to increased reabsorption of water.

A) fatty acids.
B) glucose.
C) salts.
D) erythrocytes.
E) vitamins.

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

A) the loop of Henle.
B) the collecting duct.
C) Bowman's capsule.
D) the proximal tubule.
E) the distal tubule.

A) it stores the body's excess fats.
B) it has membranes of varying permeability to water.
C) it operates an extensive set of active-transport ion pumps.
D) it is the body's only means of shedding excess nutrients.
E) it has an abundance of myogenic smooth muscle.

A) come to a complete halt.
B) decrease, and the urine would be hypoosmotic compared to plasma.
C) increase, and the urine would be isoosmotic compared to plasma.
D) increase, and the urine would be hyperosmotic compared to plasma.
E) decrease, and the urine would be isoosmotic compared to plasma.

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
E) a beaver

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

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

A) Beer drinkers have the most; salt solution drinkers have the least.
B) Salt solution drinkers have the most; water drinkers have the least.
C) Water drinkers have the most; beer drinkers have the least.
D) Beer drinkers have the most; water drinkers have the least.
E) There will be no significant difference between these groups.

A) filtration
B) reabsorption
C) active transport
D) secretion
E) salt pumping by the loop of Henle

A) a vampire bat
B) a salmon in fresh water
C) a marine bony fish
D) a freshwater bony fish
E) a shark inhabiting freshwater Lake Nicaragua

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

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 forms an insoluble precipitate.
E) Urea makes lungfish tissue hypoosmotic to the pool.

A) is intimately associated with a capillary network.
B) forms urine by changing fluid composition inside a tubule.
C) functions in both osmoregulation and excretion.
D) receives filtrate from blood instead of coelomic fluid.
E) has a transport epithelium.