Deck 17: Amino Acid Metabolism

A) It is harder to break the nitrogen triple bond than expected and requires more energy input.
B) Extra energy is required to produce H_2.
C) To regenerate the MoFe protein requires the input of ATP.
D) To keep the nitrogenase complex associated requires an input of 4 ATP.

A) nitrification
B) ammonia assimilation
C) nitrogen fixation
D) nitrogen assimilation

A) NO_2.
B) NO₂ ^- .
C) NO ^- .
D) NO₃ ^- .

A) by reducing nitrogen
B) by combining nitrogen with carbon
C) through the ATP-dependent process catalyzed by nitrogenase complex
D) through the NADH-dependent process catalyzed by glutamate dehydrogenase

A) through the oceans that break the triple bond of nitrogen and allow for the combination with water
B) through clouds that allow for nitrogen to combine with oxygen
C) in the soil by bacteria that reduce nitrogen to ammonia
D) through lightning that breaks the triple bond of nitrogen and allows for the combination with oxygen

A) NAD⁺.
B) nitrate.
C) ammonia.
D) nitrite.

A) "Glutamate + ADP + P_i + NADP⁺ $\rightarrow$$\alpha$ -Ketoglutarate + NH₄⁺ + ATP + NADPH + H⁺"
B) " $\alpha$ -Ketoglutarate + NH₄⁺ + ATP + NADPH + H⁺ $\rightarrow$ Glutamate + ADP + P_i + NADP⁺
C) " $\alpha$ -Ketoglutarate + NH₄⁺ + ADP + NADPH + H⁺ $\rightarrow$ Glutamate + ATP + P_i + NADP⁺"
D) " $\alpha$ -Ketoglutarate + NH₄⁺ + ATP + NADP⁺ + H⁺ $\rightarrow$ Glutamate + ADP + P_i + NADPH"

A) aerobic conditions
B) anaerobic conditions
C) high pressure
D) high temperature

A) ammonia
B) nitrate
C) nitrogen gas
D) bacteria

A) fumerate and malate; additional NH₃
B) fumerate and malate; ATP
C) ATP; amino acids
D) NADH; ATP

A) low temperatures and atmospheric pressure
B) low pressures and recycling unreacted nitrogen
C) high pressures and recycling nitrogen
D) high pressures and high concentrations of nitrogen

A) ammonia; nitrite
B) nitrite; nitrate
C) nitrate; nitrite
D) nitrite; ammonia

A) common
B) essential
C) optional
D) degradation

A) be able to produce more nucleotides.
B) no longer be able to produce other amino acids.
C) not be able to complete glycolysis.
D) be able to produce more ATP.

A) nitrogenase synthetase, glutamine complex, glutamate synthase, glutamate dehydrogenase
B) nitrogenase complex, glutamine synthetase, glutamate synthase, glutamate dehydrogenase
C) glutamine synthetase, glutamate synthase, glutamate dehydrogenase, glutamate oxidase
D) nitrogenase complex, glutamine synthetase, glycine synthase, glutamine dehydrogenase

A) glutamine synthase, glutamate synthetase, glutamate hydrogenase
B) glutamine synthetase, glutamate synthase, glutamate dehydrogenase
C) glutamine oxidase, glutamate reductase, glutamate dehydrogenase
D) glutamine dehydrogenase, glutamate synthase, glutamate oxidase

A) decomposition of organic material by invertebrates.
B) from the atmosphere.
C) through denitrification.
D) by leghemoglobin.

A) NO₂
B) NO₃ ^-
C) NO₄ ^-
D) NO₂ ^-

A) nitrogen fixation, nitrogen assimilation, and nitrate reduction
B) nitrogen oxidation and nitrogen reduction
C) nitrogen fixation, nitrification, and nitrate reduction
D) nitrogen oxidation and nitrate assimilation

A) Mostly reactants are made.
B) Mostly products are made.
C) Equal amount of products and reactants are made.
D) This reaction is thermodynamically unfavorable.

A) Add ATP to the cell to produce more amino acids.
B) Use common intermediates to interconvert between amino acids.
C) Phosphorylate the amino acids to prevent them from being used.
D) Remove NADH from the cell to produce more amino acids.

A) accumulation of nitrogen in the body.
B) a diet heavy in protein.
C) starvation.
D) overall good health.

A) ammonia; nitrogen
B) nitrogen; nitrogen
C) glucose; glucose
D) nitrogen; ammonia

A) increase
B) decrease
C) no change
D) Not enough information is given.

A) ternary
B) ping-pong
C) cooperative
D) reversible

A) 7
B) 6
C) 5
D) 4

A) "glutamine.
B) "nitrate."
C) " $\alpha$ -ketoglutarate."
D) "histidine."

A) " $\alpha$ -ketoglutarate + NH₄⁺ + ATP + NADH + H⁺ $\rightarrow$ NAD⁺ + ADP + P_i + glutamate"
B) "NAD⁺ + ADP + P_i + glutamate $\rightarrow$ $\alpha$ -ketoglutarate + NH₄⁺ + ATP + NADH + H⁺"
C) " $\alpha$ -ketoglutarate + NH₄⁺ + ATP + NADH + H⁺ $\rightarrow$ NAD⁺ + ADP + P_i + glutamine"
D) "glutamate + NH₄⁺ + ATP + NADH + H⁺ $\rightarrow$ NAD⁺ + ADP + P_i + $\alpha$ -ketoglutarate"

A) target proteins and E1 ligases.
B) E1 and E2 ligases.
C) target proteins and E3 ligases.
D) the E2-ubiquitin-E3 complex.

A) Pepsin cleaves trypsin, whereas secretin activates proteolytic zymogens.
B) Pepsin activates trypsinogen, whereas secretin neutralizes pH back to 7.
C) Pepsin denatures proteins, whereas secretin cleaves polypeptide bonds.
D) Pepsin cleaves polypeptide bonds, whereas secretin neutralizes pH back to 7.

A) gastric juices; pepsinogen
B) gastric juices; chyme
C) chime; enteropeptidase
D) secreton; enteropeptidase

A) "phosphorylated residue"
B) "N terminus"
C) "C terminus"
D) " $\alpha$ -helix"

A) cleaves trypsinogen to form trypsin.
B) cleaves chymotrypsinogen to form chymotrypsin.
C) generates peptides and amino acids.
D) neutralizes the pH of the duodenum to a pH of 7.

A) there is a high concentration of nitrogen available.
B) there is a low concentration of nitrogen available.
C) operates regardless of nitrogen concentration.
D) Not enough information is given.

A) 1
B) 2
C) 3
D) 0

A) enhances protein denaturing.
B) deactivates cysteine proteases.
C) makes it easier for ATP to be converted to ADP + P_i.
D) enhances the degradation of ubiquitinated proteins.

A) " $\alpha$ -keto acid and glutamate"
B) "oxaloacetate and glutamate"
C) "pyruvate and glutamate"
D) "histidine and glutamate"

A) lowering activation energy.
B) inhibiting activity.
C) increasing activation energy.
D) increasing rate of reaction.

A) all proteins; they are not selective
B) ubiquitinated proteins
C) phosphorylated proteins
D) ATP-dependent proteins

A) oxidation of phenylalanine
B) oxidation of homogentisate
C) reduction of acetoacetyl-CoA
D) dehydration

A) citrulline
B) argininosuccinate
C) aspartate
D) malate

A) remove excess sugar from
B) remove excess water-soluble vitamins from
C) remove excess nitrogen from
D) add additional nitrogen to

A) glycine
B) pyruvate
C) acetoacetyl-CoA
D) acetyl-CoA

A) alanine
B) urea
C) ammonia
D) glutamine

A) Urea + Fumerate + 2 ADP + 2P_i + AMP + PP_i $\rightarrow$ NH⁺ + HCO₃^- + aspartate + 3ATP
B) NH⁺ + HCO₃ ^- + aspartate + 3ATP $\rightarrow$ urea + fumerate + 2 ADP + 2P_i + AMP + PP_i
C) NH⁺ + HCO₃ ^- + fumerate + 3ATP $\rightarrow$ urea + aspartate + 2 ADP + 2P_i + AMP + PP_i
D) NH⁺ + HCO₃ ^- + aspartate + 2 ADP + 2P_i + AMP + PP_i $\rightarrow$ urea + fumerate + 3ATP

A) enter the urea cycle.
B) are used to produce new amino acids.
C) enter the citrate cycle.
D) are used to produce DNA and RNA.

A) fumerate and argininosuccinate
B) citrulline and malate
C) arginine and oxaloacetate
D) urea and ammonia

A) arginine to produce 2 ATP.
B) citrulline to produce NADPH, which can generate 3 ATP.
C) oxaloacetate to produce NADH, which can generate 2.5 ATP.
D) urea, which will make more ATP.

A) buildup of urea.
B) buildup of glutamate.
C) depletion of proline.
D) depletion of histidine.

A) glucogenic
B) ketogenic
C) nonessential
D) urea

A) fumarate.
B) urea.
C) glutamine.
D) glucose.

A) carbamoyl phosphate synthetase I
B) glutamate dehydrogenase
C) arginase
D) argininosuccinase

A) increases; fumerate that is metabolized by the citric acid cycle to lower ammonia levels
B) increases; ammonia in the diet to keep them regulated
C) increases; ornithine that is needed to maintain flux through the urea cycle
D) decreases; citrulline to prevent ammonia toxicity

A) through conversion to glutamine
B) through conversion to aspartate
C) by degrading down to ammonia
D) by getting phosphorylated

A) group 1
B) group 2
C) group 3
D) urea

A) Flux would be accelerated through the cycle.
B) There would be a buildup of citrulline.
C) There would be a buildup of urea.
D) The cycle would maintain equilibrium.

A) degrade glucogenic amino acids to generate $\alpha$ -ketoglutarate.
B) convert phenylalanine to tyrosine.
C) degrade alanine.
D) convert fumerate to oxaloacetate.

A) water.
B) carbamoyl phosphate.
C) aspartate.
D) the citrate cycle.

A) pyruvate
B) urea
C) ketone bodies
D) glucose

A) only available from a person's diet.
B) produced from other intermediates.
C) not needed for a body to function.
D) the main intermediates to the urea cycle.

A) black hair.
B) red hair.
C) gray hair.
D) hair loss.

A) buildup of lysine.
B) depletion of asparagine.
C) buildup of aspartate.
D) depletion of methionine.

A) condensation of phosphoenolpyruvate and erythrose-4-phosphate.
B) synthesis of essential amino acids from pyruvate.
C) synthesis of essential amino acids from oxaloacetate.
D) condensation of oxaloacetate and shikimate.

A) histidine
B) asparagine
C) glycine
D) glutamine

A) heme synthesis
B) bilirubin removal from blood
C) urea synthesis
D) amino acid degradation

A) citrulline + NO + 1.5 NADP⁺ $\rightarrow$ L-arginine + 1.5 NADPH + H⁺ + 2O₂
B) L-arginine + 1.5 NADPH + H⁺ + 2O₂ $\rightarrow$ citrulline + NO + 1.5 NADP⁺
C) L-arginine + 1.5 NADPH + H⁺ + 2O₂ $\rightarrow$ dopamine + NO + 1.5 NADP⁺
D) L-arginine + 1.5 NADP⁺ + H⁺ + 2O₂ $\rightarrow$ citrulline + NO + 1.5 NADPH

A) essential; death would occur
B) nonessential; aspartate could be synthesized from other intermediates
C) essential; aspartate could be synthesized from other intermediates
D) nonessential; death would occur

A) porphyrias.
B) albinism.
C) shikimate.
D) alkaptonuria.

A) inefficient production of dopamine
B) the enzyme tyrosinase working inefficiently
C) overproduction of NADPH
D) low levels of ATP available in the cell

A) Glyphosate is a competitive inhibitor to plant EPSP synthase.
B) Urea is a competitive inhibitor to plant chorismate synthase.
C) Glyphosate is an activator to plant EPSP synthase.
D) Anthranilate is an activator to chorismate synthase.

A) as a rapid source of NO for blood vessel dilation
B) as a source of ammonia for muscle relaxation
C) to inhibit acetylcholine release from neurons
D) to inhibit cGMP phosphodiesterase

A) tyrosine
B) phenylalanine
C) pyruvate
D) alanine

A) dopamine
B) phosphate
C) acetylcholine
D) citrulline

A) protein
B) methanol
C) aspartame
D) phenylalanine