glycolysis

Question 1

glycolysis involves a sequence of reactions that metabolizes:

Answer 1

1 molecule of glucose to 2 molecules of pyruvate and generates 2 molecules of ATP

Question 2

under aerobic conditions, pyruvate is

Answer 2

completely oxidized generating much more ATP

aerobic system is more efficient than anaerobic

Question 3

complete oxidation is more energy efficient than

Answer 3

anaerobic glycolysis

Question 4

sources of glucose in diet:

Answer 4

disaccharides (especially sucrose and lactose)

starch

glycogen

Question 5

in mammals:

glucose is the only fuel that brain uses under

glucose is the only fuel that ______ cells can use

Answer 5

conditions of non-starvation

red blood

Question 6

pyruvate and lactate can be salvaged and resynthesized to glucose via

Answer 6

gluconeogenesis

Question 7

glucose uptake occurs via protein transporters called

Answer 7

glucose transporters (GLUTs)

Question 8

GLUT 1

Answer 8

ubiquitous but expressed highly in brain, RBCs, cornea, placenta, and cancer cells

high affinity

unregulated

Question 9

GLUT 2

Answer 9

main transporter in liver (also pancreas)

low affinity

unregulated

Question 10

GLUT 3

Answer 10

main transporter in neurons

high affinity

unregulated

Question 11

GLUT 4

Answer 11

present in skeletal muscle, heart, and adipose tissue

insulin dependent

Question 12

largest GLUT transporter

Answer 12

GLUT 2

Question 13

smallest GLUT transporter

Answer 13

GLUT 1/3

Question 14

location of glycolysis

Answer 14

occurs in cytoplasm of eukaryotic cells

Question 15

two stages of glycolysis

1.

2.

Answer 15

1. trapping of glucose and its cleavage into 2 interconvertible 3-carbon molecules
2. generation of ATP

Question 16

first stage of glycolysis begins with:

ends with

Answer 16

the phosphorylation of glucose

the isomerization of dihydroxyacetone phosphate to glyceraldehyde 3-phosphate (GAP)

Question 17

trapping of glucose (through GLUTs) and preparation phase:

ATPs consumed:

ATPs generated:

Answer 17

2 ATPs consumed

no ATPs generated

Question 18

strategy of stage 1 is to:

and form a compound that can be readily cleaved into:

Answer 18

trap the glucose in the cell

2 phosphorylated 3-carbon units

Question 19

stage 1 step 1

ATP:

enzyme:

Answer 19

glucose phosphorylated to glucose-6-phosphate (G6P)

ATP is consumed

enzyme: hexokinase (in all tissues) and glucokinase (in liver)

Question 20

stage 1 step 2

ATP:

enzyme:

Answer 20

G6P isomerized to fructose-6-phosphate (F6P)

no ATP

enzyme: phosphoglucoisomerase

Question 21

stage 1 step 3

ATP:

enzyme:

Answer 21

F6P phosphorylated to fructose-1,6-bisphosphate (F1,6BP)

ATP is consumed

enzyme: phosphofructokinase (rate limiting enzyme of glycolysis)

Question 22

stage 1 step 4

ATP:

enzyme:

Answer 22

F1,6BP broken down to glyceraldehyde-3-phosphate (G3P/GAP) and dihydroxyacetone phosphate (DHAP)

no ATP

enzyme: aldolase

Question 23

stage 1 step 5

ATP

enzyme:

Answer 23

DHAP isomerized to G3P (GAP)

no ATP

enzyme: triose phosphate isomerase

Question 24

second stage of glycolysis:

energy harnessed in _____ used to form _____

Answer 24

GAP

ATP

Question 25

stage 2 step 1

NAD+

enzyme:

Answer 25

oxidative phosphorylation of GAP to form 1,3-bisphosphoglycerate (1,3-BPG)

NAD+ reduced to NADH

enzyme: glyceraldehyde 3-phosphate dehydrogenase (GAPDH)

Question 26

NADH contains

Answer 26

a pair of “high energy” electrons

sent to ETC, plays role in oxidative phosphorylation

Question 27

stage 2 step 2

ATP:

enzyme:

Answer 27

1,3 BPG is converted to 3-phosphoglycerate (3-PG)

ADP is phosphorylated to form ATP

enzyme: phosphoglycerate kinase

Question 28

stage 2 step 3

ATP

enzyme:

Answer 28

3-PG is converted to 2-phosphoglycerate (2-PG)

no ATP

enzyme: phosphoglycerate mutase

Question 29

stage 2 step 4

water:

enzyme:

Answer 29

2-PG is dehydrated to form phosphoenolpyruvate (PEP)

water is formed

enzyme: enolase

Question 30

stage 2 step 5

ATP:

enzyme:

Answer 30

PEP is converted from unstable enol to pyruvate, a stable ketone

ATP is formed

enzyme: pyruvate kinase

this step is irreversible

Question 31

pyruvate can be reduced to

Answer 31

lactate, with the generation of NAD+

Question 32

pyruvate can be oxidized aerobically via the

Answer 32

citric acid cycle after first undergoing an oxidative decarboxylation to form acetyl CoA and producing CO2

Question 33

yeast and some other microorganisms can convert pyruvate to

Answer 33

ethanol

fermentation

Question 34

pyruvate –> lactate produces NAD+ that can be used in what step of glycolysis?

Answer 34

GAP –> 1,3 BPG

Question 35

sucrose is a disaccharide of

Answer 35

glucose and fructose

Question 36

lactose is a disaccharide of

Answer 36

glucose and galactose

Question 37

fructose and galactose can be converted into

Answer 37

glycolytic intermediates

Question 38

fructose quickly turned into ______ in times of high energy

Answer 38

fat

Question 39

what is important about fructose metabolism?

Answer 39

it bypasses the rate limiting step of glycolysis

Question 40

fructose metabolism:

Answer 40

1. fructose –> fructose 1-phosphate via enzyme fructoskinase (ATP –> ADP)
2. fructose 1-phosphate –> glyceraldehyde + DHAP via enzyme fructose 1-phosphate aldolase
3. glyceraldehyde –> G3P/GAP via enzyme triose kinase

Question 41

galactose metabolism

Answer 41

1. galactose –> galactose 1-phosphate via galactokinase
2. galactose 1-phosphate + UDP-glucose –> glucose 1-phosphate via enzyme: galactose 1-phosphate uridyl transferase
3. glucose 1-phosphate –> glucose 6-phosphate via phosphoglucomutase

Question 42

major regulatory enzymes of glycolysis and reactions they catalyze

Answer 42

hexokinase: glucose –> glucose 6-phosphate (ATP –> ADP)

phosphofructokinase (rate-limiting step): fructose 6-phosphate –> fructose 1,6 bisphosphate (ATP –> ADP)

pyruvate kinase: phosphoenolpyruvate –> pyruvate (ADP –> ATP)

Question 43

glycolysis in at rest muscles (major regulatory enzymes)

Answer 43

glycolysis is inhibited

glucose 6-phosphate inhibits action of hexokinase

high ATP : AMP ratio inhibits PFK and PK

Question 44

glycolysis in muscles during exercise (major regulatory enzymes)

Answer 44

glycolysis is stimulated

glucose 6-phosphate is continuing on in pathway (does not inhibit hexokinase)

low ATP : AMP ratio activates PFK and PK

Question 45

goal of glycolysis in muscle

Answer 45

to generate ATP during activity (ATP levels regulate glycolysis)

Question 46

goals of glycolysis in liver

Answer 46

to maintain blood glucose levels

to provide building blocks for other pathways

Question 47

glycolysis in liver (major regulatory enzymes)

Answer 47

glucokinase is not inhibited by glucose 6-phosphate (glucose is permanently trapped)

(very little hexokinase in live)

PFK is activated by F-2,6-BP (inhibited by citrate)

PK is regulated by allosteric effectors and covalent modifications (F-1,6-BP activates and ATP inhibits)

Question 48

hexokinase has a ______ affinity for glucose

Answer 48

high

Question 49

glucokinase has a ______ affinity for glucose

Answer 49

low

Question 50

excessive fructose has been linked to

Answer 50

fatty liver, insulin insensitivity, obesity, type II diabetes

Question 51

actions of fructokinase and triose kinase bypass

Answer 51

hte most important regulatory step in glycolysis (PFK rate limiting step)

Question 52

fructose-derived G3P and DHAP are processed by

Answer 52

glycolysis to pyruvate and acetyl CoA in an unregulated fashion

Question 53

excess acetyl CoA (from excess fructose) is converted to

Answer 53

fatty acids which can be transported to adipose tissue to form triacylglycerols, resulting in obesity ; and liver also begins to accumulate fatty acids resulting in fatty liver

Question 54

activity of fructokinase and triose kinase (from fructose consumption) can deplete the liver of

Answer 54

ATP and inorganic phosphate, compromising liver function

Question 55

lactose intolerance

Answer 55

inability to metabolize lactose

drinking milk causes disturbances in GI function

Question 56

lactose intolerance is caused by

Answer 56

deficiency in enzyme lactase (which breaks down lactose to glucose and galactose)

Question 57

galactosemia

Answer 57

disruption of galactose metabolism

Question 58

classic galactosemia (most common form)

Answer 58

is an inherited deficiency in galactose 1-phosphate uridyl transferase activity

Question 59

defects in galactose metabolism results in:

Answer 59

failure to thrive

vomiting/diarrhea after consuming milk

enlargement of liver and jaundice

cataracts

lethargy and retarded mental development

significant elevation of blood-galactose levels and presence of galactose in urine

Question 60

how do you diagnose defect in galactose metabolism

Answer 60

absence of galactose 1-phosphate uridyl transferase in RBCs

Question 61

how to you treat defect in galactose metabolism

Answer 61

remove galatose (and lactose) from diet

Question 62

although elimination of galactose from diet (in patients with defect in galactose metabolism) prevents liver disease and cataract development, many patients still suffer from

Answer 62

CNS malfunction, most commonly a delayed acquisition of language skills

Question 63

cataracts results from

Answer 63

galactose being unable to enter glycolysis and instead being turned into galactitol

Question 64

warburg effect (aerobic glycolysis)

Answer 64

rapidly growing tumor cells metabolize glucose to lactate even in the presence of oxygen

Question 65

visualization of tumor and effectiveness of treatment:

a non-metabolizable glucose analog, 2-F-2-D-deoxyglucose detected by a combination of

Answer 65

positron emission tomography (PET) and computer-aided tomography (CAT)