Biochemistry, 4th Edition P58 ppsx

© Arthur Beck/CORBISIn the glycolysis pathway Figure 18.1, a molecule of glucose is converted in 10 enzyme-catalyzed steps to two molecules of 3-carbon pyruvate.. Living things first appe

Further Reading 533

tial end products are provided Then the biochemical consequences of

the mutation can be investigated.

17.5 What Can the Metabolome Tell Us about a Biological System?

Rapid advances in chemical analysis have made it possible to carry out

comprehensive studies of the many metabolites in a living organism The

metabolome is the complete set of low-molecular-weight molecules

present in an organism or excreted by it under a given set of

physiologi-cal conditions Metabolomics is the systematic identification and

quanti-tation of all these metabolites in a given organism or sample Mass spec-trometry offers unmatched sensitivity for detection of metabolites at very low concentrations, whereas NMR spectroscopy can provide remarkable resolution and discrimination of metabolites in complex mixtures.

17.6 What Food Substances Form the Basis of Human Nutrition? In addition to essential fiber, the food that human beings require in-cludes the macronutrients—protein, carbohydrate, and lipid—and the micronutrients—including vitamins and minerals.

PROBLEMS

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chapter at www.cengage.com/login.

1.If 3  10 14 kg of CO 2 are cycled through the biosphere annually, how

many human equivalents (70-kg people composed of 18% carbon by

weight) could be produced each year from this amount of CO 2 ?

2.Define the differences in carbon and energy metabolism between

photoautotrophs and photoheterotrophs and between chemoautotrophs and

chemoheterotrophs.

3.Name three principal inorganic sources of oxygen atoms that are

commonly available in the inanimate environment and readily

accessible to the biosphere.

4.What are the features that generally distinguish pathways of

catabo-lism from pathways of anabocatabo-lism?

5.Name the three principal modes of enzyme organization in

meta-bolic pathways.

6.Why is the pathway for the biosynthesis of a biomolecule at least

partially different from the pathway for its catabolism? Why is the

pathway for the biosynthesis of a biomolecule inherently more

com-plex than the pathway for its degradation?

7.(Integrates with Chapters 1 and 3.) What are the metabolic roles of

ATP, NAD, and NADPH?

8.(Integrates with Chapter 15.) Metabolic regulation is achieved via

regulating enzyme activity in three prominent ways: allosteric

regu-lation, covalent modification, and enzyme synthesis and

degrada-tion Which of these three modes of regulation is likely to be the

quickest; which the slowest? For each of these general enzyme

reg-ulatory mechanisms, cite conditions in which cells might employ

that mode in preference to either of the other two.

9.What are the advantages of compartmentalizing particular

meta-bolic pathways within specific organelles?

10.Name and discuss four challenges associated with metabolomic

measurements in biological systems.

11.Compare and contrast mass spectrometry and NMR in terms of their

potential advantages and disadvantages for metabolomic analysis.

12.What chemical functionality is provided to enzyme reactions by

pyri-doxal phosphate (see Chapter 13)? By coenzyme A (see Chapter

19)? By vitamin B 12 (see Chapter 23)? By thiamine pyrophosphate

(see Chapter 19)?

13.Define the following terms:

a Genome

b Transcriptome

c Proteome

d Metabolome

14. The alcohol dehydrogenase reaction, described in Figure 17.11, in-terconverts ethyl alcohol and acetaldehyde and involves hydride transfer to and from NADand NADH, respectively Write a rea-sonable mechanism for the conversion of ethanol to acetaldehyde

by alcohol dehydrogenase.

15. For each of the following metabolic pathways, describe where in the cell it occurs and identify the starting material and end product(s):

a Citric acid cycle

b Glycolysis

c Oxidative phosphorylation

d Fatty acid synthesis

16. Many solutions to the problem of global warming have been pro-posed One of these involves strategies for carbon sequestration— the removal of CO 2 from the earth’s atmosphere by various means From your reading of this chapter, suggest and evaluate a strategy for carbon sequestration in the ocean.

17. Consult Table 17.4, and consider the information presented for 32 P and 35 S Write reactions for the decay events for these two isotopes, indicating clearly the products of the decays, and calculate what percentage of each would remain from a sample that contained both and decayed for 100 days.

Preparing for the MCAT Exam

18. Which statement is most likely to be true concerning obligate anaerobes?

a These organisms can use oxygen if it is present in their envi-ronment.

b These organisms cannot use oxygen as their final electron acceptor.

c These organisms carry out fermentation for at least 50% of their ATP production.

d Most of these organisms are vegetative fungi.

19. Foods rich in fiber are basically plant materials high in cellulose, a cell wall polysaccharide that we cannot digest The nutritional ben-efits provided by such foods result from

a other nutrients present that can be digested and absorbed.

b macromolecules (like cellulose) that are absorbed without diges-tion and then catabolized inside the cells.

c microbes that are the normal symbionts of plant tissues.

d All of the above.

FURTHER READING

Metabolism

Atkinson, D E., 1977 Cellular Energy Metabolism and Its Regulation New

York, Academic Press.

Chatterjee, R., and Yuan, L., 2006 Directed evolution of metabolic

path-ways Trends in Biotechnology 24(1):28–38.

Frayn, K., 2003 Metabolic Regulation New York: Wiley.

Gerrard, J A., Sparrow, A D., et al., 2001 Metabolic databases: What

next? Trends in Biochemical Sciences 26(2):137–140.

Gropper, S., and Smith, J L., 2008 Advanced Nutrition and Human

Me-tabolism Belmont, CA: Wadsworth Publishing.

Hosler, J P., Ferguson-Miller, S., et al., 2006 Energy transduction:

Pro-ton transfer through the respiratory complexes Annual Review of

Biochemistry 75:165–187.

Metzger, R P., 2006 Thoughts on the teaching of metabolism

Biochem-istry and Molecular Biology Education 34(2):78–87.

534 Chapter 17 Metabolism: An Overview

Nicholls, D G., and Ferguson, S J., 2007 Bioenergetics 3 New York:

Aca-demic Press.

Nicholson, D E., 2003 Metabolic Pathways, 22nd ed St Louis:

Sigma-Aldrich.

Nicholson, D E., 2005 From metabolic pathways charts to animaps in

50 years Biochemistry and Molecular Biology Education 33:156–158.

Smith, E and Morowitz, H J., 2004 Universality in intermediary

me-tabolism Proceedings of the National Academy of Sciences U.S.A.

101:13168–13173.

Teichmann, S A., Rison, S C G., et al., 2001 Small-molecule

metabo-lism: An enzyme mosaic Trends in Biotechnology 19:482–486.

Tu, B P., and McKnight, S L., 2006 Metabolic cycles as an underlying

basis of biological oscillations Nature Reviews Molecular Cell Biology

7:696–701.

Metabolomics and Metabonomics

Beckonert, O., Keun, H C., et al., 2007 Metabolic profiling,

metabo-lomic and metabonomic procedures for NMR spectroscopy of

urine, plasma, serum, and tissue extracts Nature Protocols 2:

2692–2703.

Breitling, R., Pitt, A R., et al., 2006 Precision mapping of the

metabo-lome Trends in Biotechnology 24:543–548.

Clayton, T A., Lindon, J C., et al., 2006 Pharmaco-metabonomic

phe-notyping and personalized drug treatment Nature 440:1073–1077.

Costello, L C., and Franklin, R B., 2006 Tumor cell metabolism: The

marriage of molecular genetics and proteomics with cellular

inter-mediary metabolism; proceed with caution! Molecular Cancer 5:1–5.

Feala, J D., Coquin, L., et al., 2007 Integrating metabolomics and

phe-nomics with systems models of cardiac hypoxia Progress in Biophysics

and Molecular Biology 96:209–225.

Fiehn, O., 2002 Metabolomics: The link between genotypes and

phe-notypes Plant Molecular Biology 48:155–171.

Griffen, J L., 2006 The Cinderella story of metabolic profiling: Does

metabolomics get to go to the functional genomics ball?

Philosophi-cal Transactions of the Royal Society B 361:147–161.

Idle, J R., and Gonzalez, F J., 2007 Metabolomics Cell Metabolism

6:348–351.

Kell, D B., 2004 Metabolomics and systems biology: Making sense of

the soup Current Opinion in Microbiology 7:296–307.

Lane, A N., Fan, T W-M., et al., 2008 Isotopomer-based metabolomic

analysis by NMR and mass spectrometry Methods in Cell Biology 84:

541–588.

Lewis, I A., Schommer, S C., et al., 2007 Method for determining molar concentrations of metabolites in complex solutions from two-dimensional 1 H- 13C NMR spectra Analytical Chemistry 79:9385–9390.

Pan, Z., and Raftery, D., 2007 Comparing and combining NMR

spec-troscopy and mass spectrometry in metabolomics Analytical

Bio-chemistry and Chemistry 387:525–527.

Parsons, H M., Ludwig, C., et al., 2007 Improved classification accuracy

in 1- and 2-dimensional NMR metabolomics data using the variance

stabilising generalised logarithm transformation BMC

Bioinformat-ics 8:1–16.

Pearson, H., 2007 Meet the human metabolome Nature 446:8.

Wu, H., Southam, A D., et al., 2007 High-throughput tissue extraction

protocol for NMR- and MS-based metabolomics Analytical

Biochem-istry 372:204–212.

Systems Biology

Doolittle, R F., 2005 Evolutionary aspects of whole-genome biology.

Current Opinion in Structural Biology 15:248–253.

Kell, D B., Brown, M., et al., 2005 Metabolic footprinting and systems

biology: The medium is the message Nature Reviews Microbiology

3:557–565.

Vitamins

Abelson, J N., Simon, M I., et al., 1997 Vitamins and Coenzymes, Part I.

New York: Academic Press.

Dennis, E A., Simon, M I., et al., 1997 Vitamins and Coenzymes, Part L.

New York: Academic Press.

© Arthur Beck/CORBIS

In the glycolysis pathway (Figure 18.1), a molecule of glucose is converted in 10

enzyme-catalyzed steps to two molecules of 3-carbon pyruvate Most of the details of

this pathway (the first metabolic pathway to be elucidated) were worked out in the

first half of the 20th century by the German biochemists Otto Warburg, G Embden,

and O Meyerhof In fact, the sequence of reactions in Figure 18.1 is often referred

to as the Embden–Meyerhof pathway.

Why is glycolysis so important to organisms? There are several reasons For

some tissues (such as brain, kidney medulla, and rapidly contracting skeletal

muscles) and for some cells (such as erythrocytes and sperm cells), glucose is

the only source of metabolic energy In addition, the product of glycolysis—

pyruvate—is a versatile metabolite that can be used in several ways In most

tis-sues, when oxygen is plentiful (aerobic conditions), pyruvate is oxidized (with

loss of the carboxyl group as CO2), and the remaining two-carbon unit becomes

the acetyl group of acetyl-coenzyme A (acetyl-CoA) (Figure 18.2) This acetyl

group is metabolized in the tricarboxylic acid (TCA) cycle (and fully oxidized)

to yield CO2(see Chapter 19)

Alternatively, in the absence of oxygen (anaerobic conditions), pyruvate can be

reduced to lactate through oxidation of NADH to NAD—a process termed lactic

acid fermentation.In microorganisms such as brewer’s yeast, and in certain plant

tissues, pyruvate can be reduced to ethanol, again with oxidation of NADH to

NAD Most students will recognize this process as alcoholic fermentation.

Glycolysis consists of two phases In the first phase, a series of five reactions,

glu-cose is broken down to two molecules of glyceraldehyde-3-phosphate In the

sec-ond phase, five subsequent reactions convert these two molecules of

glyceralde-hyde-3-phosphate into two molecules of pyruvate Phase 1 consumes two molecules

of ATP (Figure 18.1) The later stages of glycolysis result in the production of four

molecules of ATP The net is 4 2  2 molecules of ATP produced per molecule

of glucose Microorganisms, plants, and animals (including humans) carry out the

10 reactions of glycolysis in more or less similar fashion, although the rates of the

in-dividual reactions and the means by which they are regulated differ from species to

species

Louis Pasteur’s scientific investigations into fermen-tation of grape sugar were pioneering studies of glycolysis.

Living organisms, like machines, conform to the law of conservation of energy, and must pay for all their activities in the currency of catabolism.

Ernest Baldwin

Dynamic Aspects of Biochemistry (1952)

KEY QUESTIONS 18.1 What Are the Essential Features of Glycolysis?

18.2 Why Are Coupled Reactions Important

in Glycolysis?

18.3 What Are the Chemical Principles and Features of the First Phase of Glycolysis?

18.4 What Are the Chemical Principles and Features of the Second Phase of Glycolysis?

18.5 What Are the Metabolic Fates of NADH and Pyruvate Produced in Glycolysis?

18.6 How Do Cells Regulate Glycolysis?

18.7 Are Substrates Other Than Glucose Used

in Glycolysis?

18.8 How Do Cells Respond to Hypoxic Stress?

ESSENTIAL QUESTION

Nearly every living cell carries out a catabolic process known as glycolysis—the

stepwise degradation of glucose (and other simple sugars) Glycolysis is a paradigm

of metabolic pathways Carried out in the cytosol of cells, it is basically an anaerobic

process; its principal steps occur with no requirement for oxygen Living things first

appeared in an environment lacking O2, and glycolysis was an early and important

pathway for extracting energy from nutrient molecules It played a central role in

anaerobic metabolic processes during the first 2 billion years of biological evolution

on earth Contemporary organisms still employ glycolysis to provide precursor

mol-ecules for aerobic catabolic pathways (such as the tricarboxylic acid cycle) and as a

short-term energy source when oxygen is limiting

What are the chemical basis and logic for this central pathway of metabolism;

that is, how does glycolysis work?

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536 Chapter 18 Glycolysis

2 NADH + 2 H+

2 NAD+

2 Pi

C OPO3–

H 2

CH2OPO3–

Two Glyceraldehyde-3-phosphates

O

HCOH 2

COO–

CH2OPO3–

HCOPO3– 2

COO–

CH2OH

2 C

COO–

O

CH2

COO–

CH3

PO3–

Phosphoenolpyruvate (PEP)

Pyruvate

K+, Mg 2 +

K+, Mg 2 +

2 ADP

2 ATP

O

CH2OPO3–

H

H OH

H

H

OH

O C

CH2OH

D-Glucose-6-phosphate (G-6-P)

D-Fructose-6-phosphate (F-6-P)

D-Fructose-1,6-bisphosphate (FBP)

D-Glyceraldehyde-3-phosphate (G-3-P)

1,3-Bisphosphoglycerate (BPG)

Dihydroxyacetone

phosphate (DHAP)

Phase 2

Phosphorylation of glucose and conversion to 2 molecules of

glyceraldehyde-3-phosphate; 2 ATPs are used to prime these reactions.

Conversion of glyceraldehyde-3-phosphate to pyruvate and coupled formation of 4 ATP and 2 NADH

Phase 1

Phosphoglucoisomerase

Phosphofructokinase

Mg 2 +

ATP

ADP

Phosphoglycerate kinase

Mg 2 +

2 ATP

Enolase

Pyruvate kinase

2 ADP

Glyceraldehyde-3-phosphate dehydrogenase

O

CH2OH

H H

H

H

OH

HOH

4

5 6

D-Glucose

Mg 2 +

ATP

ADP

Hexokinase glucokinase

Fructose bisphosphate aldolase

Triose phosphate isomerase

3-Phosphoglycerate (3-PG)

Phosphoglycerate mutase

Mg 2 +

2-Phosphoglycerate (2-PG)

H HO

H OH

CH2OH O

H HO

H OH

CH2OPO3–

CH2OPO3–

2 H2O O

C H

H

CH2OPO3– O

2

7

8

3

9

10 4

5

1

6

– 2 O3POCH2

– 2 O3POCH2

ACTIVE FIGURE 18.1 The glycolytic pathway Test yourself on the concepts in this figure

at www.cengage.com/login.

18.3 What Are the Chemical Principles and Features of the First Phase of Glycolysis? 537

The process of glycolysis converts some, but not all, of the metabolic energy of the

glu-cose molecule into ATP The free energy change for the conversion of gluglu-cose to two

molecules of lactate (the anaerobic route in contracting muscle) is 183.6 kJ/mol:

C6H12O6→ 2 H3COCHOHOCOO 2 H (18.1)

G°  183.6 kJ/mol

This process occurs with no net oxidation or reduction Although several individual

steps in the pathway involve oxidation or reduction, these steps compensate each

other exactly Thus, the conversion of a molecule of glucose to two molecules of

lac-tate involves simply a rearrangement of bonds, with no net loss or gain of electrons

The energy made available through this rearrangement is a relatively small part of

the total energy obtainable from glucose

The production of two molecules of ATP in glycolysis is an energy-requiring process:

2 ADP  2 Pi⎯⎯→ 2 ATP  2 H2O (18.2)

G°  2  30.5 kJ/mol  61.0 kJ/mol

Glycolysis couples these two reactions:

Glucose 2 ADP  2 Pi→ 2 lactate  2 ATP  2 H 2 H2O (18.3)

G°  183.6  61  122.6 kJ/mol

Thus, under standard-state conditions, (61/183.6) 100%, or 33%, of the free

en-ergy released is preserved in the form of ATP in these reactions However, as we

dis-cussed in Chapter 3, the various solution conditions, such as pH, concentration,

ionic strength, and presence of metal ions, can substantially alter the free energy

change for such reactions Under actual cellular conditions, the free energy change

for the synthesis of ATP (Equation 18.2) is much larger, and approximately 50% of

the available free energy is converted into ATP Clearly, then, more than enough

free energy is available in the conversion of glucose into lactate to drive the

synthe-sis of two molecules of ATP

of the First Phase of Glycolysis?

In the first phase of glycolysis, glucose will be phosphorylated at C-1 and C-6, and

the six-carbon skeleton of glucose will be cleaved to yield two three-carbon

mole-cules of glyceraldehyde-3-phosphate Phosphorylation and cleavage reorganize the

2 Pyruvate

Anaerobic conditions

Lactic acid fermentation

in contracting muscle

2 Lactate

2 NADH

2 NAD+

Anaerobic conditions

Alcoholic fermentation

in yeast

2 NADH

2 NAD+

Aerobic

conditions 2 Acetyl-CoA

TCA cycle

4 CO2

4 H2O

+ Animals and plants

in aerobic conditions

2 CoASH

2 CO2

2 NADH

2 NAD+

2 Ethanol

2 CO2 +

FIGURE 18.2 Pyruvate produced in glycolysis can be utilized by cells in several ways In animals, pyruvate is normally converted to acetyl-coenzyme A, which is then oxidized in the TCA cycle to produce CO 2 When oxygen

is limited, pyruvate can be converted to lactate Alcoholic fermentation in yeast converts pyruvate to ethanol and CO 2

538 Chapter 18 Glycolysis

glucose molecule so that molecules of ATP can be produced in the second phase of glycolysis

Reaction 1: Glucose Is Phosphorylated by Hexokinase

or Glucokinase—The First Priming Reaction

The initial reaction of the glycolysis pathway involves phosphorylation of glucose at carbon atom 6 by either hexokinase or glucokinase (Recall that “kinases” are en-zymes that transfer the -phosphate of ATP to nucleophilic acceptors.)

Phosphory-lation activates glucose for the following reactions in the pathway However, the for-mation of such a phosphoester is thermodynamically unfavorable and requires energy input to operate in the forward direction (see Chapter 3) The energy comes from ATP, a requirement that at first seems counterproductive Glycolysis is

de-signed to make ATP, not consume it However, the hexokinase or glucokinase

reac-tion (Figure 18.1) is one of two priming reacreac-tions in the pathway Just as

old-fashioned, hand-operated water pumps (Figure 18.3) have to be primed with a small amount of water to deliver more water to the thirsty pumper, the glycolysis pathway requires two priming ATP molecules to start the sequence of reactions and delivers four molecules of ATP in the end

The complete reaction for the first step in glycolysis is

-D-Glucose ATP4⎯⎯→ -D-glucose-6-phosphate2 ADP3 H (18.4)

G°  16.7 kJ/mol

The hydrolysis of ATP makes 30.5 kJ/mol available in this reaction, and the phos-phorylation of glucose “costs” 13.8 kJ/mol (Table 8.1) Thus, the reaction liberates

16.7 kJ/mol under standard-state conditions (1 M concentrations), and the equilib-rium of the reaction lies far to the right (Keq 850 at 25°C; see Table 18.1) Under cellular conditions (Table 18.2), this first reaction of glycolysis is even more favor-able than at standard state, with a G of 33.9 kJ/mol (see Table 18.1)

FIGURE 18.3 Just as a water pump must be “primed”

with water to get more water out, the glycolytic pathway

is primed with ATP in steps 1 and 3 in order to achieve

net production of ATP in the second phase of the

pathway.

glucose-6-phosphate2 ADP3 H Glucokinase

Glucose-6-phosphate234 fructose-6-phosphate2 Phosphoglucoisomerase 1.67 0.51 2.92

fructose-1,6-bisphosphate4 ADP3 H

dihydroxyacetone-P2 glyceraldehyde-3-P2 aldolase

Dihydroxyacetone-P234 glyceraldehyde-3-P2 Triose phosphate isomerase 7.56 0.0472 2.41 Glyceraldehyde-3-P2 Pi 2 NAD34 Glyceraldehyde-3-P 6.30 0.0786 1.29

1,3-bisphosphoglycerate4 NADH  H dehydrogenase

1,3-Bisphosphoglycerate4 ADP334 Phosphoglycerate kinase 18.9 2060 0.1

3-P-glycerate3 ATP4

3-Phosphoglycerate334 2-phosphoglycerate3 Phosphoglycerate mutase 4.4 0.169 0.83

phosphoenolpyruvate3 H2O Phosphoenolpyruvate3 ADP3 H34 Pyruvate kinase 31.7 3.63 105 23.0

pyruvate ATP4

Pyruvate NADH  H34 lactate NAD Lactate dehydrogenase 25.2 2.63 104 14.8

*G values calculated for 310K (37°C) using the data in Table 18.2 for metabolite concentrations in erythrocytes G° values are assumed to be the same at 25° and 37°C.

TABLE 18.1 Reactions and Thermodynamics of Glycolysis

18.3 What Are the Chemical Principles and Features of the First Phase of Glycolysis? 539

The Cellular Advantages of Phosphorylating Glucose The incorporation of a

phos-phate into glucose in this energetically favorable reaction is important for several

rea-sons First, phosphorylation keeps the substrate in the cell Glucose is a neutral

mole-cule and could diffuse across the cell membrane, but phosphorylation confers a

negative charge on glucose and the plasma membrane is essentially impermeable to

6-phosphate (Figure 18.4) Moreover, rapid conversion of glucose to

glucose-6-phosphate keeps the intracellular concentration of glucose low, favoring faciliated

dif-fusion of glucose into the cell In addition, because regulatory control can be imposed

only on reactions not at equilibrium, the favorable thermodynamics of this first

reac-tion makes it an important site for regulareac-tion

The Isozymes of Hexokinase In most animal, plant, and microbial cells, the enzyme

that phosphorylates glucose is hexokinase Magnesium ion (Mg2) is required for this

reaction, as for the other kinase enzymes in the glycolytic pathway The true substrate

for the hexokinase reaction is MgATP2 There are four isozymes of hexokinase in

most animal tissues Hexokinase I is the principal form in the brain Hexokinase in

skeletal muscle is a mixture of types I (70% to 75%) and II (25% to 30%) The K m

for glucose is 0.03 mM for type I and 0.3 mM for type II; thus, hexokinase operates

efficiently at normal blood glucose levels of 4 mM or so The animal isozymes are

allosterically inhibited by the product, phosphate High levels of

glucose-6-phosphate inhibit hexokinase activity until consumption by glycolysis lowers its

con-centration The hexokinase reaction is one of three points in the glycolysis pathway

that are regulated As the generic name implies, hexokinase can phosphorylate a

vari-ety of hexose sugars, including glucose, mannose, and fructose

The type IV isozyme of hexokinase, called glucokinase, is found predominantly

in the liver and pancreas Type IV is highly specific for D-glucose,has a much higher

K m for glucose (approximately 10 mM), and is not product inhibited With such a

high K mfor glucose, glucokinase becomes important metabolically only when liver

glucose levels are high (for example, when the individual has consumed large

amounts of carbohydrates) When glucose levels are low, hexokinase is primarily

responsible for phosphorylating glucose However, when glucose levels are high,

glu-cose is converted by glucokinase to gluglu-cose-6-phosphate and is eventually stored in

the liver as glycogen Glucokinase is an inducible enzyme—the amount present in the

liver is controlled by insulin (secreted by the pancreas) (Patients with diabetes

melli-tusproduce insufficient insulin They have low levels of glucokinase, cannot tolerate

high levels of blood glucose, and produce little liver glycogen.) Because

glucose-6-phosphate is common to several metabolic pathways (Figure 18.5), it occupies a

branch point in glucose metabolism

Glucose-6-phosphate 0.083 Fructose-6-phosphate 0.014 Fructose-1,6-bisphosphate 0.031 Dihydroxyacetone phosphate 0.14 Glyceraldehyde-3-phosphate 0.019 1,3-Bisphosphoglycerate 0.001 2,3-Bisphosphoglycerate 4.0

Phosphoenolpyruvate 0.023

Adapted from Minakami, S., and Yoshikawa, H., 1965

Thermo-dynamic considerations on erythrocyte glycolysis

Biochemi-cal and BiophysiBiochemi-cal Research Communications 18:345.

TABLE 18.2 Steady-State Concentrations

of Glycolytic Metabolites

in Erythrocytes

Glucose is kept in the cell

by phosphorylation to G-6-P,

which cannot easily cross

the plasma membrane

Extracellular fluid

Glucose

Cytoplasm

Glucose

Glucose-6-phosphate

ADP

ATP

ANIMATED FIGURE 18.4 Phosphorylation of glucose to glucose-6-phosphate by ATP

creates a charged molecule that cannot easily cross the plasma membrane See this figure animated at

www.cengage.com/login.

540 Chapter 18 Glycolysis

Hexokinase Binds Glucose and ATP with an Induced Fit In most organisms, hex-okinase occurs in a single form: a two-lobed 50-kD monomer that resembles a clamp, with a large groove in one side (Figure 18.6; see also Figure 13.24) Daniel Koshland predicted, years before structures were available, that hexokinase would undergo an induced fit (see Chapter 13), closing around the substrates ATP and glucose when they were bound Koshland’s prediction was confirmed when struc-tures of the yeast enzyme were determined in the absence and presence of glucose (Figure 18.6)

The human hexokinase isozymes I, II, and III are twice as big as those of lower organisms They are composed of two separate domains, each similar to the yeast enzyme, and connected head to tail by a long -helix (Figure 18.7) The sequence

Glucose

Glucose-6-phosphate

Fructose-6-phosphate

Glycolysis continues

Glucose-1-phosphate

Pentose phosphate pathway

Glucosamine-6-phosphate Synthesis of

NADPH and 4-C, 5-C, and 7-C sugars

Glycogen

Glucuronate

Energy storage in liver and muscles

Carbohydrate synthesis

FIGURE 18.5 Glucose-6-phosphate is the branch point for several metabolic pathways.

Glucose

(a)

(b)

FIGURE 18.6 The (a) open and (b) closed states of yeast

hexokinase Binding of glucose (green) induces a

con-formation change that closes the active site, as

predict-ed by Koshland (a: pdb id  1IG8; b: pdb id  1BDG).

Glucose

FIGURE 18.7 (a) Mammalian hexokinase I contains an

N-terminal domain (top) and a C-terminal domain (bottom) joined by a long -helix Each of these domains is similar in

sequence and structure to yeast hexokinase (pdb id  1CZA).

(b) Human glucokinase undergoes an induced fit upon

binding glucose (green) (Top: pdb id  1V4T; bottom: pdb

id  1V4S).

18.3 What Are the Chemical Principles and Features of the First Phase of Glycolysis? 541

and structure similarity apparently arose from the duplication and fusion of a

pri-mordial hexokinase gene Interestingly, both halves of hexokinase II support

catal-ysis, but only the C-terminal half of isozymes I and III performs phosphorylation of

glucose The N-terminal half, on the other hand, has apparently evolved into a form

that allosterically regulates the activity of the C-terminal half! Type IV hexokinase

(glucokinase) is similar in structure to the yeast enzyme, with a single clamp

do-main, a single active site, and a mass of 50 kD (Figure 18.7)

Reaction 2: Phosphoglucoisomerase Catalyzes the Isomerization

of Glucose-6-Phosphate

The second step in glycolysis is a common type of metabolic reaction: the

isomer-ization of a sugar In this particular case, the carbonyl oxygen of glucose-6-phosphate

is shifted from C-1 to C-2 This amounts to isomerization of an aldose

(glucose-6-phosphate) to a ketose—fructose-6-phosphate (Figure 18.8) The reaction is

neces-sary for two reasons First, the next step in glycolysis is phosphorylation at C-1, and the

hemiacetalOOH of glucose, would be more difficult to phosphorylate than a simple

primary hydroxyl Second, the isomerization to fructose (with a carbonyl group at

position 2 in the linear form) activates C-3, facilitating C-C bond cleavage in the

fourth step of glycolysis The enzyme responsible for this isomerization is

phospho-glucoisomerase, also known as phosphoglucose isomerase and glucose phosphate

isomerase.In humans, the enzyme requires Mg2for activity and is highly specific

for glucose-6-phosphate The G° is 1.67 kJ/mol, and the value of G under

cellu-lar conditions (Table 18.1) is 2.92 kJ/mol This small value means that the reaction

operates near equilibrium in the cell and is readily reversible

Phosphoglucoiso-merase proceeds through an enediol intermediate, as shown in Figure 18.8 Although

the predominant forms of glucose-6-phosphate and fructose-6-phosphate in solution

are the ring forms, the isomerase interconverts the open-chain form of G-6-P with

the open-chain form of F-6-P

Phosphoglucoisomerase, with fructose-6-P (blue) bound (pdb id  1HOX).

OH

O H

HO

O

O

H

OH H

OH HO

OH H

C HO

H H

H B

OH O HO

CH2OPO3–

OH

OH

– 2 O3POH2C

OH

CH2OH

H

H

H

H

B

O H

B

CH2OPO3–

H

H

H

B

H B

+ +

+

+

B

H

C

intermediate

H

H

OH

H

C

HO

H

B

OH

H

H

O

B

E

E

E

E

E

E E

E

1

3

2

ACTIVE FIGURE 18.8 The phosphoglucoiso-merase mechanism involves opening of the pyranose ring (step 1), proton abstraction leading to enediol formation (step 2), and pro-ton addition to the double bond, followed by ring closure (step 3).

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542 Chapter 18 Glycolysis

Reaction 3: ATP Drives a Second Phosphorylation

by Phosphofructokinase—The Second Priming Reaction

The action of phosphoglucoisomerase, “moving” the carbonyl group from C-1 to C-2, creates a new primary alcohol function at C-1 (see Figure 18.8) The next step in the

glycolytic pathway is the phosphorylation of this group by phosphofructokinase.

Once again, the substrate that provides the phosphoryl group is ATP Like the hexo-kinase/glucokinase reaction, the phosphorylation of fructose-6-phosphate is a prim-ing reaction and is endergonic:

Fructose-6-P Pi⎯⎯→ fructose-1,6-bisphosphate (18.5)

G°  16.3 kJ/mol

When coupled (by phosphofructokinase) with the hydrolysis of ATP, the overall re-action becomes exergonic:

Fructose-6-P ATP ⎯⎯→ fructose-1,6-bisphosphate  ADP (18.6)

G°  14.2 kJ/mol

G (in erythrocytes)  18.8 kJ/mol

At pH 7 and 37°C, the phosphofructokinase reaction equilibrium lies far to the

right Just as the hexokinase reaction commits the cell to taking up glucose, the phos-phofructokinase reaction commits the cell to metabolizing glucose rather than converting it

to another sugar or storing it Similarly, just as the large free energy change of the hexokinase reaction makes it a likely candidate for regulation, so the phosphofruc-tokinase reaction is an important site of regulation—indeed, the most important site in the glycolytic pathway

Regulation of Phosphofructokinase Phosphofructokinase is the “valve” control-ling the rate of glycolysis In addition to its role as a substrate, ATP is also an allosteric inhibitor of this enzyme Thus, phosphofructokinase has two distinct binding sites for ATP; a high-affinity substrate site and a low-affinity regulatory site In the pres-ence of high ATP concentrations, phosphofructokinase behaves cooperatively, plots

of enzyme activity versus fructose-6-phosphate are sigmoid, and the K mfor fructose-6-phosphate is increased (Figure 18.9) Thus, when ATP levels are sufficiently high

in the cytosol, glycolysis “turns off.” Under most cellular conditions, however, the ATP concentration does not vary over a large range The ATP concentration in muscle during vigorous exercise, for example, is only about 10% lower than that during the resting state The rate of glycolysis, however, varies much more A large range of glycolytic rates cannot be directly accounted for by only a 10% change in ATP levels

AMP reverses the inhibition due to ATP, and AMP levels in cells can rise dramat-ically when ATP levels decrease, due to the action of the enzyme adenylate kinase,

which catalyzes the reaction

ADP ADP 34 ATP  AMP with the equilibrium constant:

[ADP]2

+

H HO

H OH

CH2OH

– 2 O3POCH2

H HO

H OH

CH2OPO3– – 2 O3POCH2 O

+

ΔGerythrocyte = –18.8 kJ/mol

ΔG⬚' = –14.2 kJ/mol

ADP

Fructose-6-phosphate

Phosphofructokinase (PFK)

Fructose-1,6-bisphosphate ATP

Phosphofructokinase with ADP (in orange) and

fructose-6-phosphate (in red) (pdb id  4PFK).

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regula-tion of phosphofructokinase.

[Fructose-6-phosphate]

Low [ATP]

High [ATP]

FIGURE 18.9 At high [ATP], phosphofructokinase (PFK)

behaves cooperatively and the plot of enzyme activity

versus [fructose-6-phosphate] is sigmoid High [ATP] thus

inhibits PFK, decreasing the enzyme’s affinity for

fructose-6-phosphate.