Deck 3: Microbial Metabolism

A) the microbial inoculum placed into a test tube or onto a Petri plate.
B) a series of practices to avoid contamination.
C) the autoclave and other sterilizing procedures.
D) cleanliness in the laboratory.

A) metabolism.
B) anabolism.
C) catabolism.
D) synthatabolism.

A) arginine
B) inorganic phosphorous
C) iron
D) vitamin B12

A) requires more reactants but makes the reaction rate faster.
B) increases the amount of reactants produced but does not change the rate.
C) changes the rate of the reaction but does not change the end amount of products.
D) changes both the rate of a reaction and the amount of the product that will be obtained as the reaction is completed.

A) carbohydrates.
B) DNA.
C) lipids.
D) proteins.

A) Most bacteria are capable of using ammonia as their sole nitrogen source.
B) Some bacteria are able to use nitrates or nitrogen gas as their nitrogen source.
C) Most available nitrogen is in organic forms.
D) Nitrogen is a major component of proteins and nucleic acids.

A) Coenzymes are essential for an enzymeʹs function and prosthetic groups only enhance its reaction rate.
B) Coenzymes are weakly bound whereas prosthetic groups are strongly bound to their respective enzymes.
C) Coenzymes are organic cofactors and prosthetic groups are inorganic cofactors.
D) Coenzymes require additional ions to bind to enzymes but prosthetic groups are able to directly interact with enzymes.

A) substrate complex.
B) active site.
C) catalytic site.
D) junction of van der Waals forces.

A) the ABC transport system.
B) group translocation.
C) symport.
D) simple transport.

A) iron
B) hydrogen
C) zinc
D) magnesium

A) carbon, iron, and sodium.
B) phosphorus, aluminum, and sodium.
C) calcium, potassium, and magnesium.
D) phosphorus, selenium, and sulfur.

A) oxygen.
B) carbon.
C) nitrogen.
D) phosphorous.

A) C₂H₃O₂⁻
B) H₂
C) CO₂
D) H⁺

A) exergonic and requires the input of energy.
B) endergonic and requires the input of energy.
C) exergonic and energy will be released.
D) endergonic and energy will be released.

A) required for a chemical reaction to begin.
B) given off as the products in a chemical reaction are formed.
C) absorbed as ΔG⁰ʹ moves from negative to positive.
D) needed by an enzyme to catalyze a reaction without coenzymes.

A) complex / minimal
B) minimal / complex
C) selective / complex
D) selective / differential

A) before enzyme production
B) during enzyme production
C) after enzyme production
D) at any point-before, during, or after enzyme production

A) the amount of energy catalysts required for biosynthesis or catabolism.
B) the potential metabolic reaction rate.
C) whether there will be a requirement or production of energy.
D) energy stored in each compound.

A) simultaneous reduction of a different compound will also occur, because electrons do not generally exist alone in solution.
B) another oxidation reaction will occur for a complete reaction, because one oxidation event is considered a half reaction.
C) a cell is undergoing aerobic respiration, because oxygen is being used.
D) a reduction reaction would not occur, because they are opposite reaction mechanisms.

A) OH⁻ accumulates on the outside of the membrane while H⁺ accumulates on the inside.
B) OH⁻ accumulates on the inside of the membrane while H⁺ accumulates on the outside.
C) both OH⁻ and H⁺ accumulate on the inside of the membrane.
D) both OH⁻ and H⁺ accumulate on the outside of the membrane.

A) acetyl~S-CoA
B) glycogen
C) adenosine triphosphate
D) H₂

A) the citric acid cycle.
B) glycolysis.
C) electron transport.
D) NADH production.

A) a physiological shift to anaerobic metabolism where an energized membrane is less important for energy production.
B) enhanced growth of a bacterium due to faster growth substrate uptake by a weakened membrane.
C) no harm to bacteria, because only archaeons and eukaryotes use ACPs for fatty acid biosynthesis.
D) death for a bacterium due to poor lipid bilayer integrity.

A) hydrogen.
B) oxygen.
C) water.
D) ATP.

A) FADH₂.
B) FMNH₂.
C) cytochromes.
D) quinones.

A) biotin production.
B) carbon dioxide produced by fermentation.
C) oxidative phosphorylation.
D) oxygen being released.

A) ATPase requires one proton to make one ATP.
B) Protons must be pumped against a concentration gradient from outside of the cell into the cell to rotate the F₀ subunit of ATPase for the F₁ subunit to make ATP.
C) Oxidative phosphorylation of ADP by ATP synthase requires protons as cofactors in the reaction.
D) Translocation of three to four protons drives the F₀ component of ATPase which in turn phosphorylates one ADP into ATP.

A) acetate, succinate, and glucose.
B) bicarbonate and carbon dioxide.
C) nitrate and nitrite.
D) acetate, bicarbonate, and nitrate.

A) electron donor
B) electron acceptor
C) use of electron transport
D) use of proton motive force

A) degrade an amino acid or nucleic acid
B) invoke the pentose phosphate pathway
C) degrade a fatty acid
D) use a broad specificity phosphatase with inorganic phosphatase and NADH

A) citric acid cycle and glycolysis
B) glycolysis and gluconeogenesis
C) proton motive force and substrate-level phosphorylation
D) pentose phosphate pathway and glycolysis

A) NADH dehydrogenases
B) flavoproteins
C) cytochromes
D) Cytochromes, flavoproteins, and NADH dehydrogenases all can be membrane-associated.

A) more reducing equivalents are used for anaerobic catabolism.
B) less ATP is consumed during the first stage of aerobic catabolism.
C) oxidative phosphorylation yields a lot of ATP.
D) substrate-level phosphorylation yields a lot of ATP.

A) the citric acid cycle for aerobic catabolism.
B) both the citric acid and glyoxylate pathways.
C) the glyoxylate pathway.
D) the glyoxylate and glycolysis pathways.

A) only α-ketoglutarate
B) only oxaloacetate
C) only succinyl-CoA
D) α-ketoglutarate, oxaloacetate, and succinyl-CoA

A) biosynthesis of DNA and RNA.
B) catabolic pentose phosphate pathway for carbon and energy.
C) biosynthesis of DNA and RNA as well as catabolic pentose phosphate pathway.
D) activation of pentoses to form glycogen for energy storage.

A) 1.
B) 2.
C) 4.
D) 8.

A) ATP and regenerated NAD⁺; the fermentation products are waste products.
B) ethanol or lactate; ATP is a waste product.
C) CO₂; ATP is a waste product.
D) not relevant because glycolysis is not a major pathway.

A) oxygen.
B) carbon.
C) nitrogen.
D) carbon and oxygen.

A) a higher diversity of cytochromes would likely be observed.
B) cytochromes would be unnecessary for cells and quinones would be more important.
C) Q-cycle reactions would no longer be necessary for electron transport, but the proton motive force would otherwise be unchanged.
D) most metabolic pathways for both anabolism and catabolism would have to be rewritten.

A) citric acid cycle intermediates.
B) citric acid cycle intermediates and glycolysis products.
C) glycolysis products.
D) glycolysis intermediates and products.

A) NADH.
B) water.
C) nitrate.
D) FMN.

A) aerobic catabolism
B) fermentation
C) chemoorganotrophy
D) photoautrophy

A) citric acid cycle
B) glycolysis
C) gluconeogenesis
D) pentose phosphate pathway

A) Cells require much less P to grow than N, so extra P will be used for ATP synthesis and result in a faster growth rate.
B) Cells will never consume all of the phosphate, because N is needed in higher quantities than P.
C) The final biomass of cells will be no different than if only 50% of the phosphate was provided.
D) The bacteria will import all of the ammonia to use for biosynthetic pathways.