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Chapter 18: Carbohydrate Metabolism
VocabularyBiotin: a CO2 carrier molecule Cori Cycle: a pathway in carbohydrate metabolism that links glycolysis in the liver with gluconeogenesis in the liver Debranching Enzyme: an enzyme that hydrolyzes the linkages in a branched-chain polymer such as amylopectinGluconeogenesis: the pathway of synthesis of glucose from lactateHexose Monophosphate: shunt a synonym for the pentose phosphate pathway, in which glucose is converted to five-carbon sugars with concomitant production of NADPHPhosphorolysis: the addition of phosphoric acid across a bond, such as the glycosidic bond in glycogen, giving glucose phosphate and a glycogen remainder one residue shorter; it is analogous to hydrolysis (addition of water across a bond) Pentose Phosphate Pathway: a pathway in sugar metabolism that gives rise to five-carbon sugars and NADPHSubstrate Cycling: the control process in which opposing reactions are catalyzed by different enzymesTransaldolase: an enzyme that transfers a two-carbon unit in reactions of sugars
Chapter 18: Carbohydrate Metabolism
Chapter Summary
How does the breakdown of glycogen take place?
Glycogen can readily be broken down to glucose in response to energy needs. Glycogen
phosphorylase uses phosphate to break an a(1 : 4) linkage, yielding glucose-1-phosphate and a
glycogen molecule shorter by one glucose. Debranching enzyme aids in the degradation of the
molecule around the a(1 : 6)linkages.
How is glycogen formed from glucose?
When an organism has an available supply of extra glucose, more than is immediately
needed as a source of energy extracted in glycolysis, it forms glycogen, a polymer of glucose.
Glycogen synthase catalyzes the reaction between a glycogen molecule and UDP-glucose to add
a glucose molecule to the glycogen via an a(1 : 4) linkage. Branching enzyme moves sections of
a chain of glucoses so that there are a(1 : 6) branch points.
How is glycogen metabolism controlled?
Control mechanisms ensure that both formation and breakdown of glycogen are not
active simultaneously, a situation that would waste energy.
Why is oxaloacetate an intermediate in gluconeogenesis?
The conversion of pyruvate (the product of glycolysis) to glucose takes place by a
process called gluconeogenesis, which is not the exact reversal of glycolysis. Glycolysis involves
three irreversible steps. One of these irreversible steps is the conversion of phosphoenolpyruvate
to pyruvate. It is favorable to convert pyruvate to oxaloacetate to facilitate the conversion to
phosphoenolpyruvate.
What is the role of sugar phosphates in gluconeogenesis?
The hydrolysis of sugar phosphates is energetically favorable, so these steps have the
effect of reversing the early, energy requiring steps of glycolysis.
How does control of key enzymes control carbohydrate metabolism?
Glycogen synthase and glycogen phosphorylase are reciprocally controlled by
phosphorylation. Glycolysis and gluconeogenesis are controlled at several points, with
phosphofructokinase and fructose bisphosphatase being the most important.
Chapter 18: Carbohydrate Metabolism
How do different organs share carbohydrate metabolism?
In the same cell, glycolysis and gluconeogenesis are not highly active simultaneously.
When the cell needs ATP, glycolysis is more active; when there is little need for ATP,
gluconeogenesis is more active. Glycolysis and gluconeogenesis play roles in the Cori cycle. The
division of labor between liver and muscle allows glycolysis and gluconeogenesis to take place
indifferent organs to serve the needs of an organism.
What roles do the first and last steps of glycolysis play in control of carbohydrate
metabolism?
Hexokinase and pyruvate kinase, the enzymes that catalyze the first and last steps,
respectively, in glycolysis are also important control points. They have the effect of slowing
down the pathway when energy is not needed and speeding it up when there is a need.
What are the oxidative reactions of the pentose phosphate pathway?
The pentose phosphate pathway is an alternative pathway for glucose metabolism. In this
pathway five-carbon sugars, including ribose, are produced from glucose. In the oxidative
reactions of the pathway, NADPH is also produced.
What are the non-oxidative reactions of the pentose phosphate pathway, and why are they
important?
The non-oxidative reactions of the pentose phosphate pathway produce five-carbon
sugars, particularly ribose. They are important when an organism has less need for NADPH but
needs the sugars.
How is the pentose phosphate pathway controlled?
Control of the pathway allows the organism to adjust the relative levels of production of
five-carbon sugars and of NADPH according to its needs.
Chapter 18: Carbohydrate Metabolism
Questions and Answers
1. Why is it essential that the mechanisms that activate glycogen synthesis also deactivate
glycogen phosphorylase?
These two pathways occur in the same cellular compartment, and, if both are on at the
same time, a futile ATP hydrolysis cycle results. Using the same mechanism to turn them
on/off or off/ on is highly efficient.
2. How does phosphorolysis differ from hydrolysis?
In phosphorolysis, a bond is cleaved by adding the elements of phosphoric acid across
that bond, whereas in hydrolysis, the cleavage takes place by adding the elements of
water across the bond.
3. Why is it advantageous that breakdown of glycogen gives rise to glucose-6-phosphate
rather than to glucose?
Glucose-6-phosphate is already phosphorylated. This saves one ATP equivalent in the
early stages of glycolysis.
4. Briefly outline the role of UDPG in glycogen biosynthesis.
Each glucose residue is added to the growing glycogen molecule by transfer from UDPG.
5. Name two control mechanisms that play a role in glycogen biosynthesis. Give an
example of each.
Glycogen synthase is subject to covalent modification and to allosteric control. The
enzyme is active in its phosphorylated form and inactive when dephosphorylated. AMP is
an allosteric inhibitor of glycogen synthase, whereas ATP and glucose-6-phosphate are
allosteric activators.
6. Does the net gain of ATP in glycolysis differ when glycogen, rather than glucose, is the
starting material? If so, what is the change?
There is a net gain of three, rather than two, ATP when glycogen, not glucose, is the
starting material of glycolysis.
Chapter 18: Carbohydrate Metabolism
7. In metabolism, glucose-6-phosphate (G6P) can be used for glycogen synthesis or for
glycolysis, among other fates. What does it cost, in terms of ATP equivalents, to store
G6P as glycogen, rather than to use it for energy in glycolysis? Hint: The branched
structure of glycogen leads to 90% of glucose residues being released as glucose-1-
phosphate and 10% as glucose.
It “costs” one ATP equivalent (UTP to UDP) to add a glucose residue to glycogen. In
degradation, about 90% of the glucose residues do not require ATP to produce glucose-1-
phosphate. The other 10% require ATP to phosphorylate glucose. On average, this is
another 0.1 ATP. Thus, the overall “cost” is 1.1 ATP, compared with the three ATP that
can be derived from glucose- 6-phosphate by glycolysis.
8. How does the cost of storing glucose-6-phosphate (G6P) as glycogen differ from the
answer you obtained in Question 7 if G6P were used for energy in aerobic metabolism?
The ATP cost is the same, but more than 30 ATP can be derived from aerobic metabolism.
9. You are planning to go on a strenuous hike and are advised to eat plenty of high-
carbohydrate foods, such as bread and pasta, for several days beforehand. Suggest a
reason for the advice.
Eating high-carbohydrate foods for several days before strenuous activity is intended to
build up glycogen stores in the body. Glycogen will be available to supply required
energy.
10. Would eating candy bars, high in sucrose rather than complex carbohydrates, help
build up glycogen stores?
The disaccharide sucrose can be hydrolyzed to glucose and fructose, which can both be
readily converted to glucose-1- phosphate, the immediate precursor of glycogen. This is
not the usual form of “glycogen loading.”
11. Would it be advantageous to consume a candy bar with a high refined-sugar content
immediately before you start the strenuous hike in Question 9?
Probably not, because the sugar spike initially results in a rapid increase in insulin levels,
which results in lowering blood glucose levels and increased glycogen storage in the
liver.
Chapter 18: Carbohydrate Metabolism
12. The concentration of lactate in blood rises sharply during a sprint and declines slowly
for about an hour afterward. What causes the rapid rise in lactate concentration?
What causes the decline in lactate concentration after the run?
The sprint is essentially anaerobic and produces lactate from glucose by glycolysis.
Lactate is then recycled to glucose by gluconeogenesis.
13. A researcher claims to have discovered a variant form of glycogen. The variation is that
it has very few branches (every 50 glucose residues or so) and that the branches are only
three residues long. Is it likely that this discovery will be confirmed by later work?
It is unlikely that this finding will be confirmed by other researchers. The highly
branched structure of glycogen is optimized for release of glucose on demand.
14. What is the source of the energy needed to incorporate glucose residues into glycogen?
How is it used?
Each glucose residue added to a growing phosphate chain comes from uridine
diphosphate glucose. The cleavage of the phosphate ester bond to the nucleoside
diphosphate moiety supplies the needed energy.
15. Why is it useful to have a primer in glycogen synthesis?
The enzyme that catalyzes addition of glucose residues to a growing glycogen chain
cannot form a bond between isolated glucose residues; thus we have the need for a
primer.
16. Is the glycogen synthase reaction exergonic or endergonic? What is the reason for your
answer?
The glycogen synthase reaction is exergonic overall because it is coupled to
phosphate ester hydrolysis.
17. What is the effect on gluconeogenesis and glycogen synthesis of (a) increasing the level
of ATP, (b) decreasing the concentration of fructose-1,6-bisphosphate, and (c) increasing
the concentration of fructose-6-phosphate?
(a) Increasing the level of ATP favors both gluconeogenesis and glycogen synthesis.
(b) Decreasing the level of fructose-1,6-bisphosphate would tend to stimulate glycolysis,
rather than gluconeogenesis or glycogen synthesis.
(c) Levels of fructose-6- phosphate do not have a marked regulatory effect on these
pathways of carbohydrate metabolism.
Chapter 18: Carbohydrate Metabolism
18. Briefly describe “going for the burn” in a workout in terms of the material in this
chapter.
“Going for the burn” in a workout refers to the sensation that accompanies lactic acid
buildup. This in turn arises from anaerobic metabolism of glucose in muscle.
19. Suggest a reason why sugar nucleotides, such as UDPG, play a role in glycogen
synthesis, rather than sugar phosphates, such as glucose-6-phosphate.
Sugar nucleotides are diphosphates. The net result is hydrolysis to two phosphate ions,
releasing more energy and driving the addition of glucose residues to glycogen in the
direction of polymerization.
20. What reactions in this chapter require acetyl-CoA or biotin?
Reactions that require acetyl-CoA: none. Reactions that require biotin: carboxylation of
pyruvate to oxaloacetate.
21. Which steps of glycolysis are irreversible? What bearing does this observation have on
the reactions in which gluconeogenesis differs from glycolysis?
Three reactions of glycolysis are irreversible under physiological conditions. They are the
production of pyruvate and ATP from phosphoenolpyruvate, the production of fructose-
1,6- bisphosphate from fructose-6-phosphate, and the production of glucose-6-phosphate
from glucose. These reactions are bypassed in gluconeogenesis; the reactions of
gluconeogenesis differ from those of glycolysis at these points and are catalyzed by
different enzymes.
22. What is the role of biotin in gluconeogenesis?
Biotin is the molecule to which carbon dioxide is attached to the process of being
transferred to pyruvate. The reaction produces oxaloacetate, which then undergoes further
reactions of gluconeogenesis.
23. How does the role of glucose-6-phosphate in gluconeogenesis differ from that in
glycolysis?
In gluconeogenesis, glucose-6-phosphate is dephosphorylated to glucose (the last step of
the pathway); in glycolysis, it isomerizes to fructose-6-phosphate (an early step in the
pathway).
Chapter 18: Carbohydrate Metabolism
24. Avidin, a protein found in egg whites, binds to biotin so strongly that it inhibits enzymes
that require biotin. What is the effect of avidin on glycogen formation? On
gluconeogenesis? On the pentose phosphate pathway?
Of the three processes—glycogen formation, gluconeogenesis, and the pentose phosphate
pathway—only one, gluconeogenesis, involves an enzyme that requires biotin. The
enzyme in question is pyruvate carboxylase, which catalyzes the conversion of pyruvate
to oxaloacetate, an early step in gluconeogenesis.
25. How does the hydrolysis of fructose-1,6- bisphosphate bring about the reversal of one of
the physiologically irreversible steps of glycolysis?
The hydrolysis of fructose-1,6-bisphosphate is a strongly exergonic reaction. The reverse
reaction in glycolysis, phosphorylation of fructose-6-phosphate, is irreversible because of
the energy supplied by ATP hydrolysis.
26. Which reaction or reactions discussed in this chapter require ATP? Which reaction or
reactions produce ATP? List the enzymes that catalyze the reactions that require and
that produce ATP.
Reactions that require ATP: formation of UDP-glucose from glucose-1-phosphate and
UTP (indirect requirement, because ATP is needed to regenerate UTP), regeneration of
UTP, and carboxylation of pyruvate to oxaloacetate.
Reactions that produce ATP: none.
Enzymes that catalyze ATP-requiring reactions: UDP-glucose phosphorylase (indirect
requirement), nucleoside phosphate kinase, and pyruvate carboxylase.
Enzymes that catalyze ATP-producing reactions: none.
27. How does fructose-2,6-bisphosphate play a role as an allosteric effector?
Fructose-2,6-bisphosphate is an allosteric activator of phosphofructokinase(a glycolytic
enzyme) and an allosteric inhibitor of fructose bisphosphate phosphatase (an enzyme in
the pathway of gluconeogenesis).
Chapter 18: Carbohydrate Metabolism
28. How do glucokinase and hexokinase differ in function?
Hexokinase can add a phosphate group to any of several six-carbon sugars, whereas
glucokinase is specific for glucose. Glucokinase has a lower affinity for glucose than
does hexokinase. Consequently, glucokinase tends to deal with an excess of glucose,
particularly in the liver. Hexokinase is the usual enzyme for phosphorylating six-carbon
sugars.
29. What is the Cori cycle?
The Cori cycle is a pathway in which there is cycling of glucose due to glycolysis in
muscle and gluconeogenesis in liver. The blood transports lactate from muscle to liver
and glucose from liver to muscle.
30. Earlier biochemists called substrate cycles “futile cycles.” Why might they have chosen
such a name? Why is it something of a misnomer?
Substrate cycles are futile in the sense that there is no net change except for the
hydrolysis of ATP. However, substrate cycles allow for increased control over opposing
reactions when they are catalyzed by different enzymes.
31. Why is it advantageous for two control mechanisms —allosteric control and covalent
modification—to be involved in the metabolism of glycogen?
Having two control mechanisms allows for fine-tuning of control and for the possibility
of amplification. Both mechanisms are capable of rapid response to conditions,
milliseconds in the case of allosteric control and seconds to minutes in the case of
covalent modification.
32. How can different time scales for response be achieved in control mechanisms?
Different control mechanisms have inherently different timescales. Allosteric control can
take place in milliseconds, where as covalent control takes seconds to minutes. Genetic
control has a longer time scale than either.
33. How do the control mechanisms in glycogen metabolism lead to amplification of
response to a stimulus?
The most important aspect of the amplification scheme is that the control mechanisms
affect agents that are catalysts themselves. An enhancement by several powers of ten is
itself increased by several powers of ten.
Chapter 18: Carbohydrate Metabolism
34. Why would you expect to see that reactions of substrate cycles involve different
enzymes for different directions?
Enzymes, like all catalysts, speed up the forward and reverse reaction to the same extent.
Having different catalysts is the only way to ensure independent control over the rates of
the forward and reverse process.
35. Suggest a reason or reasons why the Cori cycle takes place in the liver and in muscle.
Muscle tissue uses large quantities of glucose, producing lactate in the process. The liver
is an important site of gluconeogenesis to recycle the lactate to glucose.
36. Explain how fructose-2,6-bisphosphate can play a role in more than one metabolic
pathway.
Fructose-2,6-bisphosphate is an allosteric activator of phosphofructokinase(a glycolytic
enzyme) and an allosteric inhibitor of fructose bisphosphate phosphatase (an enzyme in
the pathway of gluconeogenesis). It thus plays a role in two pathways that are not exactly
the reverse of each other.
37. How can the synthesis and breakdown of fructose- 2,6-bisphosphate be controlled
independently?
The concentration of fructose-2,6-bisphosphate in a cell depends on the balance between
its synthesis (catalyzed by phosphofructokinase-2) and its breakdown (catalyzed by
fructose bisphosphatase-2). The separate enzymes that control the formation and
breakdown of fructose-2,6-bisphosphate are themselves controlled by a
phosphorylation/dephosphorylation mechanism.
38. How is it advantageous for animals to convert ingested starch to glucose and then to
incorporate the glucose into glycogen?
Glycogen is more extensively branched than starch. It is a more useful storage form of
glucose for animals because the glucose can be mobilized more easily when there is a
need for energy.
39. List three differences in structure or function between NADH and NADPH.
NADPH has one more phosphate group than NADH (at the 29position of the ribose ring
of the adenine nucleotide portion of the molecule). NADH is produced in oxidative
reactions that give rise to ATP. NADPH is a reducing agent in biosynthesis. The enzymes
that use NADH as a coenzyme are different from those that require NADPH.
Chapter 18: Carbohydrate Metabolism
40. What are four possible metabolic fates of glucose-6-phosphate?
Glucose-6-phosphate can be converted to glucose (gluconeogenesis),glycogen, pentose
phosphates (pentose phosphate pathway),or pyruvate (glycolysis).
41. What is the connection between material in this chapter and hemolytic anemia?
Hemolytic anemia is caused by defective working of the pentose phosphate pathway.
There is a deficiency of NADPH, which indirectly contributes to the integrity of the red
blood cells. The pentose phosphate pathway is the only source of NADPH in red blood
cells.
42. Show how the pentose phosphate pathway, which is connected to the glycolytic
pathway, can do the following. (a) Make both NADPH and pentose phosphates, in
roughly equal amounts (b) Make mostly or only NADPH (c) Make mostly or only
pentose phosphates
(a) By using only the oxidative reactions.
(b) By using the oxidative reactions, the transaldolase and transketolase reactions, and
gluconeogenesis.
(c) By using glycolytic reactions and the transaldolase and transketolase reactions in
reverse.
43. What is a major difference between transketolase and transaldolase?
Transketolase catalyzes the transfer of a two-carbon unit, whereas transaldolase catalyzes
the transfer of a three-carbon unit.
44. List two ways in which glutathione functions in red blood cells.
In red blood cells, the presence of the reduced form of glutathione is necessary for the
maintenance of the sulfhydryl groups of hemoglobin and other proteins in their reduced
forms, as well as for keeping the Fe(II) of hemoglobin in its reduced form. Glutathione
also maintains the integrity of red cells by reacting with peroxides that would otherwise
degrade fatty-acid side chains in the cell membrane.
45. Does thiamine pyrophosphate play a role in the reactions of the pentose phosphate
pathway? If so, what is that role?
Thiamine pyrophosphate is a cofactor necessary for the function of transketolase, an
enzyme that catalyzes one of the reactions in the non-oxidative part of the pentose
phosphate pathway.
Chapter 18: Carbohydrate Metabolism
46. Using the Lewis electron-dot notation, show explicitly the transfer of electrons in the
following redox reaction.
The lactone is a cyclic ester that is an intermediate in the production of 6-
phosphogluconate.
47. Suggest a reason why a different reducing agent (NADPH) is used in anabolic reactions
rather than NADH, which plays a role in catabolic ones.
Having different reducing agents for anabolic and catabolic pathways keeps the pathways
separate metabolically. Thus, they are subject to independent control and do not waste
energy.
48. Explain how the pentose phosphate pathway can respond to a cell’s need for ATP,
NADPH, and ribose-5-phosphate.
If a cell needs NADPH, all the reactions of the pentose phosphate pathway take place. If
a cell needs ribose-5-phosphate, the oxidative portion of the pathway can be bypassed;
only the non-oxidative reshuffling reactions take place. The pentose phosphate pathway
does not have a significant effect on the cell’s supply of ATP.
49. Why is it reasonable to expect that glucose-6-phosphate will be oxidized to a lactone (see
Question 46) rather than to an open-chain compound?
The ester bond is more easily broken than any of the other bonds that form the sugar ring.
Hydrolysis of that bond is the next step in the pathway.
Chapter 18: Carbohydrate Metabolism
50. How would it affect the reactions of the pentose phosphate pathway to have an
epimerase and not an isomerase to catalyze the reshuffling reactions?
The reshuffling reactions of the pentose phosphate pathway have both an epimerase and
an isomerase. Without an isomerase, all the sugars involved are keto sugars, which are
not substrates for transaldolase, one of the key enzymes in the reshuffling process.