Deck 23: Integration and Hormonal Regulation of Mammalian Metabolism

A)epinephrine.
B)retinoic acid.
C)testosterone.
D)thromboxane.
E)thyroxine.

A)Amino acids are incorporated into new proteins.
B)Nitrogen equivalents from amino acids are converted to urea.
C)Carbon equivalents from amino acids are converted to glucose.
D)Amino acids are stored for later use.
E)Amino acids serve as precursors to nucleotide biosynthesis.

A)catecholamine
B)eicosanoid
C)paracrine
D)peptide
E)steroid

A)antibodies for binding to a hormone.
B)antibodies for binding to a receptor.
C)hormone for binding to a receptor.
D)hormone for binding to an antibody.
E)receptor for binding to a hormone.

A)tyrosine;arginine
B)tryptophan;lysine
C)tyrosine;histidine
D)tryptophan;arginine
E)histidine;lysine

A)anterior pituitary.
B)hypothalamus.
C)ovaries.
D)pancreas.
E)posterior pituitary.

A)Fatty acids are oxidized to generate ATP.
B)Fatty acids are converted to ketone bodies.
C)Fatty acids can be converted to cholesterol.
D)Fatty acids are stored for later use.
E)Fatty acids are converted to glucose.

A)adrenal cortex $\rightarrow$ hypothalamus $\rightarrow$ anterior pituitary.
B)anterior pituitary $\rightarrow$ adrenal cortex $\rightarrow$ hypothalamus.
C)anterior pituitary $\rightarrow$ hypothalamus $\rightarrow$ adrenal cortex.
D)hypothalamus $\rightarrow$ adrenal cortex $\rightarrow$ anterior pituitary.
E)hypothalamus $\rightarrow$ anterior pituitary $\rightarrow$ adrenal cortex.

A)amino acids are an essential fuel.
B)at rest,fatty acids are the preferred fuel.
C)large quantities of triacylglycerol are stored as fuel.
D)phosphocreatine can substitute for ATP as the direct source of energy for muscle contraction.
E)stored muscle glycogen can be converted to glucose and released to replenish blood glucose.

A)the conversion of lactate to pyruvate in skeletal muscle to drive glycogen synthesis.
B)the interconversion between glycogen and glucose l-phosphate.
C)the production of lactate from glucose in peripheral tissues with the resynthesis of glucose from lactate in liver.
D)the synthesis of alanine from pyruvate in skeletal muscle and the synthesis of pyruvate from alanine in liver.
E)the synthesis of urea in liver and degradation of urea to carbon dioxide and ammonia by bacteria in the gut.

A)catecholamine
B)eicosanoid
C)paracrine
D)peptide
E)steroid

A)act through nonspecific receptors,whereas steroid hormones act through specific receptors.
B)are generally water-insoluble,whereas steroid hormones are water soluble.
C)are more stable than steroid hormones.
D)bind to cell surface receptors,whereas steroid hormones bind to nuclear receptors.
E)bind to their receptors with high affinity,whereas steroid hormones bind with low affinity.

A)epinephrine.
B)retinoic acid.
C)testosterone.
D)thromboxane.
E)thyroxine.

A)epinephrine.
B)insulin.
C)progesterone.
D)releasing factors.
E)thyroxine.

A)Most plasma lipoproteins are synthesized in the liver.
B)The enzymatic complement of liver tissue changes in response to changes in the diet.
C)The liver synthesizes most of the urea produced in the body.
D)The presence of glucose 6-phosphatase makes liver uniquely able to release glucose into the bloodstream.
E)Under certain conditions,most of the functions of the liver can be performed by other organs.

A)acts in the conversion of liver glycogen to glucose 1-phosphate.
B)converts fructose-6-phosphate to glucose-6-phosphate
C)converts glucose 6-phosphate to fructose 6-phosphate.
D)is a hexokinase isozyme found in liver hepatocytes.
E)is found in all mammalian tissues.

A)white adipose tissue stores fatty acids as triacylglycerols.
B)brown adipose tissue degrades fatty acids via the citric acid cycle.
C)brown adipose tissue contains thermogenin.
D)white adipose tissue contains adipocytes.
E)white adipose tissue responds to hormone signals.

A)acetylation.
B)oxidation.
C)phosphorylation.
D)proteolysis.
E)reduction.

A)1
B)2
C)3
D)4
E)32

A)Grehlin
B)Insulin
C)Adiponectin
D)Both A and B
E)Both A and C

A)epinephrine.
B)glucagon.
C)glucose.
D)insulin.
E)trypsin.

A)The brain prefers glucose as an energy source,but can use ketone bodies.
B)Muscle cannot use fatty acids as an energy source.
C)In a well-fed human,about equal amounts of energy are stored as glycogen and as triacylglycerol.
D)Fatty acids cannot be used as an energy source in humans because humans lack the enzymes of the glyoxylate cycle.
E)Amino acids are a preferable energy source over fatty acids.

A)Reduced efflux through ATP-gated K⁺-channels
B)Increased concentrations of ATP
C)cAMP-dependent phosphorylation of lipase
D)Phosphorylation of glucose to glucose-6-phosphate
E)Increased Ca²⁺ levels

A)Increased synthesis of uncoupler protein thermogenin
B)Decreased activity of the enzyme 5´-AMP-activated protein kinase (AMPK)
C)Increased activity of the sympathetic nervous system
D)Increased $\beta$ -oxidation
E)Decreased desire to eat

A)increases;increases
B)increases;decreases
C)decreases;increases
D)decreases;decreases
E)has no effect on;has no effect on

A)activation of hexokinase.
B)activation of phosphofructokinase-1.
C)conversion of glycogen phosphorylase a to glycogen phosphorylase b.
D)inhibition of the Cori cycle
E)the Pasteur effect.

A)inhibits glucose uptake by the liver.
B)inhibits glycogen synthesis in the liver and muscle.
C)results from a below-normal blood glucose level.
D)stimulates glycogen breakdown in liver.
E)stimulates synthesis of fatty acids and triacylglycerols in the liver.

A)fatty acid mobilization in adipose tissue.
B)gluconeogenesis in liver.
C)glycogen breakdown in muscle.
D)glycogen synthesis in liver.
E)glycolysis in muscle.

A)epinephrine.
B)glucagon.
C)glucose.
D)insulin.
E)trypsin.

A)ATP in all tissues.
B)blood glucose.
C)liver glycogen.
D)muscle glycogen.
E)triacylglycerols in adipose tissue.

A)enhances fatty acid synthesis in liver cells.
B)increases the rate of $\beta$ -oxidation of fatty acids in muscle cells.
C)inhibits glucose uptake and catabolism in muscle and liver cells.
D)reduces the transport of fatty acids into muscle cells.
E)stimulates gluconeogenesis in liver cells.

A)adiposin.
B)hypothalmin.
C)leptin.
D)obesin.
E)testosterone.

A)Grehlin
B)Insulin
C)Adiponectin
D)PPAR $\gamma$
E)PYY_3-36

A)Increasing TAG by weight loss
B)Activating AMPK through exercise
C)Activating AMPK by taking metformins
D)Activating PPAR $\gamma$ through rosiglitazone
E)Stimulating insulin secretion by taking sulfonylureas