Hemoglobin 1 - O2 binding & cooperativeity 09/09 Traish

Question 1

function of Mb vs Hb

Answer 1

Mb - O2 storage

Hb - O2 transport

Question 2

why do we need oxygen?

Answer 2

• oxidative metabolism and energy production -> tissue survival and function
• oxidizing dietary substrates to yield energy & CO2

Question 3

why do we need O2 carriers? 4 reasons

Answer 3

• diffusion not adequate for large human bodies
• gas exchange through impermeable external skin layer impossible
• O2 has low aqueous solubility and cannot facilitate metabolic needs of body as naked gas
• O2 is strong oxidizing agent and at necessary high concentrations would harmfully oxidize tissues and cells

Question 4

how many grams of Hb are in 1 L of blood?

Answer 4

150 grams Hb

Question 5

how much O2 can 1g of Hb bind?

Answer 5

~1.5 ml O2

Question 6

how much O2 can 1L of blood bind?

Answer 6

~225 mL O2
150 g Hb / L blood
~1.5 ml O2 / g Hb
150 x 1.5 = 225

Question 7

how much naked O2 dissolves in blood at physiological temperature?

Answer 7

2.3 ml

Question 8

how much more O2 can travel in blood due to Hb?

Answer 8

~ 90 to 100 times more

~225 ml O2 with Hb / 2.3 ml O2 naked

Question 9

how much faster would blood have to circulate to deliver adequate O2 if there were no Hb?

Answer 9

~ 90 to 100 times faster

~225 ml O2 with Hb / 2.3 ml O2 naked = <100

Question 10

~how quickly does blood circulate under resting conditions?

Answer 10

once every 60 seconds

or 18 m/s

Question 11

what is the atmospheric partial pressure of oxygen

Answer 11

160 mmHg

Question 12

Hb transport reduces O2 partial pressure from __ to __ as it reaches tissues, which minimizes harmful tissue oxidation

Answer 12

100-160 mmHg to 30-40 mmHg

Question 13

Hb facilitates __ transport to tissues an __ transport to lungs

Answer 13

O2 to tissues and CO2 to lungs

Question 14

what are 3 properties of a “preferred oxygen carrier”

Answer 14

• binds O2 at high pO2
• does not oxidize cellular components
• gives up O2 on demand

Question 15

in what state is iron bound to the prosthetic group in Hb and Mb?

Answer 15

iron (II)
Fe^2+
ferrous

Question 16

ferrous iron is…

Answer 16

Fe^2+

Question 17

ferric iron is…

Answer 17

Fe^3+

Question 18

ferrous to ferric iron transition involves __

ferric to ferrous iron transition involves __

Answer 18

Fe^2+ –> Fe^3+ = oxidation

Fe^3+ –> Fe^2+ = reduction

Question 19

what kind of bonds hold heme in its crevice in Hb and Mb

Answer 19

non-covalent interactions

Question 20

is the heme crevice in Hb and Mb hydrophobic or hydrophilic?

Answer 20

hydrophobic - to prevent iron oxidation before O2 binding

Question 21

T/F heme is a prosthetic group in Hb and Mb

Answer 21

true

Question 22

how many ligands can ferrous iron usually bind?

Answer 22

6

Question 23

how does Fe2+ bind protoporphyrin IX?

Answer 23

it bonds to the four N atoms of the porphyrin rings

Question 24

how many bonds does Fe2+ form with protoporphyrin IX?

Answer 24

4

Question 25

in a heme group in Hb and Mb, what ligands occupy the 6 possible coordinate bonds in Fe2+?

Answer 25

• 4 occupied by N atoms of porphyrin rings in protoporphyrin IX
• 1 occupied by proximal histidine F8 (8th residue on helix F; his 93 in Mb, his 92 in b-Hb, his 87 in a-Hb)
• 1 occupied by O2 or empty but stabilized by distal hovering histidine E7 (his 64 in Mb, his 63 in b-Hb, his 58 in a-Hb)

Question 26

the 5th coordination site on Fe2+ is occupied by what?

Answer 26

the proximal histidine F8 (8th residue on helix F; his 93 in Mb, his 92 in b-Hb, his 87 in a-Hb)

Question 27

the 6th coordination site on Fe2+ is occupied by what?

Answer 27

O2, or empty but stabilized by distal hovering histidine E7 (his 64 in Mb, his 63 in b-Hb, his 58 in a-Hb)

Question 28

which are the proximal and distal Hb histidines that interact with heme, and why are they so named?

Answer 28

• proximal his F8 (8th residue on helix F; his 93 in Mb, his 92 in b-Hb, his 87 in a-Hb) “proximal” because covalent bond holds it closer to heme than hovering distal E7 his
• distal his E7 (his 64 in Mb, his 63 in b-Hb, his 58 in a-Hb) “distal” because it hovers further away from heme than covalently bonded proximal his F7

Question 29

what is the oxidation state of iron before O2 binds heme? what is the oxidation state of iron when O2 is released from heme?

Answer 29

ferrous Fe2+ before O2 binding

returns to ferrous Fe2+ after O2 release

Question 30

in what tissues is Mb primarily located as a storage reserve of O2?

Answer 30

skeletal muscle

Question 31

Mb accepts O2 from Hb in … and then delivers O2 to …

Answer 31

• accepts O2 from Hb in the circulating blood

- delivers O2 to the mitochondria

Question 32

binding of O2 to Mb is described by what kind of binding curve?

Answer 32

a hyperbolic binding curve

as pO2 increases, saturation of O2 binding sites is approached asymptotically

Question 33

what is the equation for the O2 - Mb binding curve?

Answer 33

theta = pO2 / (P50 + pO2)
theta = fraction of O2 bound Mb sites
pO2 = O2 partial pressure
P50 = O2 partial pressure for half saturation

Question 34

with regard to O2 binding, a low P50 signifies…

Answer 34

high affinity for oxygen (e.g. Mb)

P50 is partial pressure at which half of all bidning sites are saturated with O2

Question 35

which is lower, P50 of Mb or Hb?

Answer 35

P50 for Mb is lower, must have higher O2 affinity to extract O2 from Hb in blood

Question 36

how does Mb extract O2 from blood?

Answer 36

P50 for Mb is lower than for Hb, so it has a higher affinity for O2 and will pick up O2 as Hb drops it off at the lower O2 concentrations in tissues (~30-40 mmHg)

Question 37

how does Mb deliver O2?

Answer 37

at normal O2 concentrations in capillaries, Mb in adjacent tissues is nearly saturated. when cells are metabolically active, their internal pO2 falls to lower levels and Mb releases O2

Question 38

how many amino acids are there in Mb?

Answer 38

153

Question 39

how many polypeptide chains make up Mb?

Answer 39

1

Question 40

T/F the Mb molecule is a very compact globular molecule

Answer 40

true

Question 41

how many a-helices make up the tertiary structure of Mb?

Answer 41

8 (A-H)

Question 42

__ a-helices in Mb are terminated by this amino acid residue

Answer 42

4 a-helices in Mb are terminated by proline residues

Question 43

approximately what percentage of the Mb polypeptide chain is in a-helical structure?

Answer 43

75%

Question 44

T/F Mb is compact with very little empty space inside

Answer 44

true

Question 45

Mb is expressed mainly in what tissue?

Answer 45

skeletal muscle

Question 46

Mb releases O2 only when tissues are __

Answer 46

hypoxic

Question 47

how does the affinity of myoglobin for O2 change with O2 concentration?

Answer 47

it doesn’t. binding affinity is an intrinsic property of Mb. the molecule does not change (e.g. change conformation) to actively “release” O2, it just becomes less saturated at lower pO2 because oxygenated and de-oxygenated Mb exist at equilibrium with one another i.e. l’chatlier’s principle

Question 48

does Mb exhibit cooperativity?

Answer 48

no.

Question 49

T/F Mb can be found in most tissues

Answer 49

false - it is mainly found in tissues with high O2 demand, e.g. skeletal muscle

Question 50

affinity signifies…

Answer 50

how stongly / how long a substrate is bound

Question 51

where in Mb does heme bind

Answer 51

in a hydrophobic pocket/crevice

Question 52

the residue that binds heme in Mb is…

Answer 52

his 93 (F8)
the "proximal" histidine

Question 53

the distal Mb residue that hovers over the O2 binding site in heme is…

Answer 53

his 64 (E7)
the "distal" histidine

Question 54

the six coordinate bond structure of Fe2+ is termed __

Answer 54

octahedral

Question 55

octahedral coordinate binding structure includes how many bonds?

Answer 55

6 (4 planar, 1 above, 1 below)

Question 56

the residue that binds heme in beta Hb is…

Answer 56

beta his 92 (F8)

Question 57

the residue that binds heme in alpha Hb is…

Answer 57

alpha his 87 (F8)

Question 58

the “proximal histidine” residues that bind heme in Mb and alpha and beta Hb are…

Answer 58

Mb his 93 (F8)
beta his 92 (F8)
alpha his 87 (F8)

Question 59

the residue that hovers over the O2 binding site of heme in beta Hb is…

Answer 59

beta his 63 (E7)

Question 60

the residue that hovers over the O2 binding site of heme in alpha Hb is…

Answer 60

alpha his 58 (E7)

Question 61

the “distal histidine” residues that hover the O2 binding sites of heme in Mb and beta and alpha Hb are…

Answer 61

Mb his 64 (E7)
beta his 63 (E7)
alpha his 58 (E7)

Question 62

what is the role of E7 in oxy Hb and Mb?

Answer 62

when O2 is bound, his E7 sterically alters O2 binding so that O2 is not bound in the optimal conformation (O2 binds crooked), lowering O2 binding affinity and making easier to remove when needed

Question 63

what is the role of E7 in deoxy Hb and Mb?

Answer 63

when O2 is not bound, his E7 protects the site from water and prevents Fe2+ oxidation

Question 64

ferroprotoporphyrin is another name for __

Answer 64

heme

Question 65

another word for heme is __

Answer 65

ferroprotoporphyrin

Question 66

heme is the result of the combination of __ and __

Answer 66

ferrous iron and protoporphyrin IX

Question 67

T/F heme alone is sufficient to protect the iron atom from oxidation

Answer 67

false - O2 will oxidize ferrous iron to ferric iron in the absence of a protein like Hb or Mb

Question 68

how do Hb and Mb protect heme from irreversible oxidation?

Answer 68

the heme crevice is hydrophobic to exclude water and prevent oxidation by water, and his F7 prevents oxidation by O2 with a degree of steric hindrance

Question 69

what is the Ka for Mb

Answer 69

Ka = association constant
Ka = [MbO2] / [Mb] [O2]

Question 70

what does Ka refer to

Answer 70

association constant [products] / [reactants]

Question 71

what does Kd refer to

Answer 71

dissociation constant [reactants] / [products]

Question 72

association and dissociation constants refer to…

Answer 72

how slow or fast the bound molecule associates or dissociates

Question 73

how are Ka and Kd related

Answer 73

Ka = 1/Kd
Kd = 1/Ka

Question 74

what does the term “fractional saturation” refer to with respect to Mb

Answer 74

theta = [MbO2] / [Mb] + [MbO

Question 75

what is the Ka for Mb

Answer 75

Ka = association constant
Ka = [MbO2] / [Mb] [O2]

Question 76

what does Ka refer to

Answer 76

association constant [products] / [reactants]

Question 77

what does Kd refer to

Answer 77

dissociation constant [reactants] / [products]

Question 78

what are 3 alternative equations relating fractional saturation of Mb and oxygen concentration

Answer 78

theta = pO2 / (pO2 + P50)
-or-
theta / (1 - theta) = (pO2 / P50)^nH
-or-
log [theta / (1 - theta)] = nH log pO2 - nH log P50

nH = hill coefficient (1 for Mb, (~)1-4 for Hb)

Question 79

on an Mb or Hb binding curve, P50 signifies

Answer 79

the oxygen concentration or (oxygen partial pressure) at which 50% of Mb binding sites are occupied (O2 conc at 50% Mb saturation)

Question 80

what does the term “fractional saturation” refer to with respect to Mb

Answer 80

theta = [MbO2] / [Mb] + [MbO2]

Question 81

an oxygen binding plot for Mb and Hb plots…

a Hill plot for Mb and Hb plots…

Answer 81

normal plot: fractional saturation vs pO2

Hill plot: log fract sat / 1-fract sat vs log pO2

Question 82

what does Ka refer to

Answer 82

association constant [products] / [reactants]

Question 83

a Hill plot plots this equation…
x-intercept =
slope =

Answer 83

log [theta / (1 - theta)] = nH log pO2 - nH log P50
x-intercept = log P50
slope = nH (nH = 1 for Mb; for Hb (~)1<4)
(near P50 Hb nH~3.5)

Question 84

association and dissociation constants refer to…

Answer 84

how slow or fast the bound molecule associates or dissociates

Question 85

how are Ka and Kd related

Answer 85

Ka = 1/Kd
Kd = 1/Ka

Question 86

what does the term “fractional saturation” refer to with respect to Mb

Answer 86

theta = [MbO2] / [Mb] + [MbO2]

fractional sat = ratio of bound Mb / total Mb

Question 87

what is the Kd for Mb

Answer 87

Kd = [Mb] [O2] / [MbO2]

Question 88

how is binding affinity related to Kd?

Answer 88

inversely.
Kd down, affinity up
Kd up, affinity down

Question 89

according to Henry’s Law, the concentration of any gas dissolved in solution is proportional to…

Answer 89

the partial pressure of that gas above the solution

Question 90

what is the equation relating fractional saturation of Mb and oxygen concentration

Answer 90

theta = pO2 / (pO2 + P50)

Question 91

on an Mb or Hb binding curve, P50 signifies

Answer 91

the oxygen concentration or (oxygen partial pressure) at which 50% of Mb binding sites are occupied (O2 conc at 50% Mb saturation)

Question 92

a Hill Plot for Mb and Hb plots…

Answer 92

log fract sat / 1-fract sat vs log pO2
log [theta/(1-theta)] on y axis
log pO2 on x axis

Question 93

an oxygen binding plot for Mb and Hb plots…

a Hill plot for Mb and Hb plots…

Answer 93

normal plot: fractional saturation vs pO2

Hill plot: log fract sat / 1-fract sat vs log pO2

Question 94

the relevant equation for a Hill Plot is…

Answer 94

log [theta / (1 - theta)] = nH log pO2 - nH log P50

Question 95

what do the respective Hill plots for Mb and Hb look like?

Answer 95

-Mb is linear with a slope (nH) of 1 and a lower P50
Hb is sigmoidal with slope (nH) between (~)1 and 4 (<1 at tails at low and high log pO2, about 3.5 at pO2 near P50) and a higher P50 than Mb

Question 96

T/F the Hill coefficient (nH) indicates the number of subunits participating in binding

Answer 96

false - it indicates “degree of cooperativity”
(a proteins quaternary structure may involve multiple binding subunits but exhibit no cooperativity and an nH of 1, or even “negative cooperativity”)

Question 97

does a Hill coefficient (nH) value of 1.1 indicate cooperativity?

Answer 97

no - could be due to small experimental error

Question 98

on a Hill plot, what is the nH for Hb?

Answer 98

between ~1 and 4
at low and high pO2, nH is slightly < 1
at pO2 near P50, nH ~3.5

Question 99

a Hill coefficient (nH) of 1 indicates…

Answer 99

non-cooperative binding (e.g. Mb)

Question 100

a Hill coefficient (nH) of >1 indicates…

Answer 100

cooperative binding (e.g. Hb)

Question 101

Hb is composed of __ subunits

Answer 101

4
2 alpha
2 beta

Question 102

T/F the Hb tetramer is approximately spherical in shape

Answer 102

true

Question 103

T/F the alpha subunits in Hb are identical

Answer 103

false - they may or may not be identical (a1 and a2 differ by 1 amino acid and are transcribed from separate genes)

Question 104

T/F the beta subunits in Hb are identical

Answer 104

true - there is only one b-subunit gene

Question 105

how many genes code for a-Hb subunits

Answer 105

2 (a1 and a2 differ by 1 amino acid)

Question 106

how many genes code for b-Hb subunits

Answer 106

1

Question 107

what do the respective Hill plots for Mb and Hb look like?

Answer 107

-Mb is linear with a slope (nH) of 1 and a lower P50
Hb is sigmoidal with slope (nH) between 1 and 4 (1 at tails at low and high log pO2, about 3.5 at pO2 near P50) and a higher P50 than Mb

Question 108

why is cooperative binding necessary in Hb?

Answer 108

makes possible to switch from strong binding state at high pO2 in lungs to weak binding state at low pO2 in tissues

Question 109

T/F Hb participates in maintaining plasma pH

Answer 109

true - by transporting CO2 and H+ to lungs

Question 110

on a Hill plot, what is the nH for Hb?

Answer 110

between 1 and 4
at low and high pO2, nH ~1
at pO2 near P50, nH ~3.5

Question 111

how many aa residues in a-Hb subunit?

Answer 111

141

Question 112

how many aa residues in b-Hb subunit?

Answer 112

146

Question 113

when subjected to a 2 M urea solution, Hb dissociates into…

Answer 113

a-b dimers

Question 114

which Hb subunit interactions are stronger, those a-a and b-b or a-b?

Answer 114

a-b interactions are stronger

Question 115

in Hb, how far apart are heme prosthetic groups from one another?

Answer 115

2.5 nm

Question 116

T/F the source of cooperative oxygen binding in Hb can be attributed to heme-heme interactions

Answer 116

false - heme groups within the molecule are not close to one another

Question 117

T/F heme groups are located deep within Mb and Hb molecules

Answer 117

false - heme groups are located close to the surface in relatively superficial hydrophobic clefts in the molecules

Question 118

what are the 2 conformational states of Hb

Answer 118

oxyHb

deoxyHb

Question 119

what 4 molecules alter the affinity of Hb to O2?

Answer 119

• O2
• H+
• CO2
• BPG (bisphosphoglycerate)

Question 120

why is cooperative binding necessary in Hb?

Answer 120

makes possible to switch from strong binding state at high pO2 in lungs to weak binding state at low pO2 in tissues

Question 121

T/F Hb participates in maintaining plasma pH

Answer 121

true - by transporting CO2 and H+ to lungs

Question 122

the change in conformation from oxyHb to deoxyHb is called…

Answer 122

an allosteric shift

Question 123

the Mb binding plot is __

Answer 123

hyperbolic

Question 124

the Mb Hill plot is __

Answer 124

linear

Question 125

if pO2 in lung is 100mmHg, pO2 in capillary is 10mmHg, and P50 Hb is 26 mmHg, and nH for Hb is 2.8, how much O2 is delivered to capillaries? how much would be delivered if Hb was non-cooperative?

Answer 125

theta / (1-theta) = (pO2 / P50)^nH
theta lungs = 0.98
theta capillary = 0.063
.98 - .063 = 0.92 = % Hb subs that delivered O2
for non-coop, 0.51 = % Hb subs that delivered O2

Question 126

the Hb Hill plot is __

Answer 126

sigmoidal

Question 127

why is a sigmoidal binding curve necessary in Hb?

Answer 127

makes possible to switch from strong binding state at high pO2 in lungs to weak binding state at low pO2 in tissues

Question 128

what is the reaction equation for O2 binding to Hb

Answer 128

Hb + nO2 Hb(O2)^n

n is a number between 1 and 4

Question 129

how can you approximate Kd from a Hill plot?

Answer 129

P50 (x-intercept) approximates Kd

Question 130

the abscissa value on a Hill plot refers to

Answer 130

the x-axis value (the value of log pO2)

Question 131

is the slope of the Hb binding curve on a Hill plot at extreme (high or low) pO2 equal to 1 or less than 1?

Answer 131

slightly <4) state

Question 132

what is advantageous about the Hill plot versus a normal binding plot for Mb and Hb?

Answer 132

2 things:

• can visualize transition from non-coop to coop more easily
• gives a direct numerical measure of degree of cooperativity from slope (nH), the Hill coefficient

Question 133

what does it mean when nH = 4 for Hb?

Answer 133

the molecule is wholly cooperative and only wholly unliganded and wholly liganded molecules exist (hypothetical situation - never happens. max nH ~3.5)

Question 134

what is the Hill coefficeint (nH) for a hypothetical wholly cooperative situation?

Answer 134

nH = n, the number of subunits

Question 135

what is the functional difference between Hb and Mb?

Answer 135

cooperativity in Hb. possible because the oxygenation state of one subunit can be communicated to the others

Question 136

what is the maximum Hill coefficient (nH) for Hb?

Answer 136

~3.5
(4 only in hypothetical situations… would indicate that only fully oxyHb or fully deoxyHb are present, not partially oxyHb present)

Question 137

if pO2 in lung is 100mmHg, pO2 in capillary is 10mmHg, and P50 Hb is 26 mmHg, and nH for Hb is 2.8, how much O2 is delivered to capillaries?

Answer 137

theta / (1-theta) = (pO2 / P50)^nH
theta lungs = 0.98
theta capillary = 0.063
.98 - .063 = 0.92 = % Hb subunits that delivered O2