Glucides 1.2:

Question 1

What is neoglucogenese?

Answer 1

Synthèse endogène de glucose

Question 2

True or False,

Most organs are capable of undergoing néoglucogenèse

Answer 2

FALSE
Contrairement à la glycolyse, la néoglucogenèse n’a pas lieu dans toutes les cellules
* Foie (principalement) et reins

Glucose-6-phosphate à Glucose + Pi
* (glucose-6-phosphatase ** dans le foie uniquement **)

Question 3

What is fructose-1,6-diphosphatase

Answer 3

IT is a key enzyme in neoglucogenesis converting Fructose-1,6-diphosphate à
Fructose-6-phosphate

Question 4

Point de contrôle majeur de la vitesse de la néoglucogenèse

Answer 4

Fructose-1,6-diphosphate à
Fructose-6-phosphate

Catalyzed by fructose-1,6-diphosphatase

Question 5

What inhibits fructose-1,6-diphosphatase

Answer 5

Insuline

Question 6

What is fructose-2,6-diphosphate? Explain in detail.

Answer 6

Régulateur majeur du sens des voies métaboliques de la glycolyse et de la
néoglucogenèse

it stimulates PFK-1 -> etape 3 in glycolyse
it blocks fructose 1,6 diphosphatase of the neoglucogenesis

fructose-2,6-diphosphate est synthétisé ou dégradé par la même enzyme -> PFK-2
the activity of PFK2 is dependent on insuline and glucagon activity
it can phosphorylate or phosphoroylate based on these signals

if insulin -> kinase activity -> more fructose-2,6-diphosphate -> less glucose

Question 7

What does glucagon do to PFK2? What is the result of this?

Answer 7

PFK-2 activity becomes a diphosphatase (i.e, break stuff)

it will then break fructose-2,6-diphosphate

because** F2,6DP has an effect of activating PFK1** and deactivating F1,6P -> we get less PFK1 activity and thus less glucose breakdown -> more glucose in blood

Question 8

Aerobic vs anerobic pathway for Pyruvate?

Answer 8

condition anaérobique (ou en absence de mitochondrie), le
pyruvate est transformé en lactate par la lactate déshydrogénase

condition aérobique, le pyruvate entre dans la mitochondrie où
il est transformé en acétyl-CoA

Question 9

Result of Krebs cycle

Answer 9

First, only works in aerobic conditions
Produces 38ATP

Question 10

Role of Voie des pentoses phosphates?

Answer 10

Formation du NADPH
Formation de ribose

Question 11

Reactions exergoniques vs endergoniques

Answer 11

Les réactions exergoniques qui dégagent de l’énergie
Ex: A + B à C + D** + énergie (chaleur)**
DG < 0: la réaction est exergonique et elle se produit spontanément
* Les réactions endergoniques qui nécessitent de l’énergie
Ex: A + B + énergie (chaleur) à C + D
DG > 0: la réaction est endergonique et ne se produit pas spontanément

DG = 0: la réaction est en équilibre, c’est-à-dire qu’elle se fait aussi vite dans un sens que dans l’autre

Question 12

What are some composés riches en énergie

Answer 12

ATP
Creatine Phosphate
Carbamoyl phosphate

acyls-coenzyme A
phosphoénol pyruvate et le 1,3-biphosphoglycérat

Question 13

What is the role of Creatine Phosphate?

Answer 13

It acts as a storage of Phosphate
In fact, passing from creatine to creatine phosphate is a endorgenic reaction
However, when there are a lot of ATPs around, we can store them

La créatine phosphate constitue donc un système de tampon pour l’ATP.

Question 14

True or False:

Les enzymes ne modifient jamais les concentrations finales des composés à l’équilibre, elles ne font qu’accélérer la réaction.

Answer 14

True

Enzymes do not decrease the need for energy, they simply accelerate a given reaction

Question 15

What is special about Oxydoréduction reactions?

Answer 15

In contract to other reactions

These can only go 1 direction!!!
Ex:
NADH + H+ + ubiquinone -> ubiquinol + NAD+

but NEVER THE OPPOSITE

Which means: le transfert des électrons du NADH + H+ et du FADH2 vers l’oxygène est très favorable (très exergonique)

Question 16

What are co-factors?

Answer 16

co-facteurs doivent se lier à l’enzyme et sont nécessaires à l’activité
participent à la réaction, mais sont souvent recyclés

Question 17

True or False,

NADH producted in the cytoplasm by glycolysis can diffuse to enter the mitochondria and be converted to ATP under aerobic conditions

Answer 17

FALSE

IT needs a transporter since the membrane of the mitochondria is impermeable

Question 18

Role of complex 1?

Answer 18

Accepte NADH electrons and gives them to CoenzymeQ

Given that it is transmembranaire
the energy of the electron transfer is used to pump a proton across the membrane

Question 18

Difference of Complex 1 vs 2?

Answer 18

Complex 2 is not transmembranaire = does not pump protons across the membrane

It takes it from FADH instead of NADH

Question 19

Role of complex 3?

Answer 19

Accepts electrons from CoenzymeQ and gives them to CytochromeC

Given that it is transmembranaire
the energy of the electron transfer is used to pump a proton across the membrane

Question 20

Role of complex 4?

Answer 20

Takes electrons from Cytochrome C and gives them to Oxygen -> the last electron acceptor

Given that it is transmembranaire
the energy of the electron transfer is used to pump a proton across the membrane

Question 21

What does FADH only produce 2 ATP instead of 3 ATP like NADH?

Answer 21

Because FADH uses complex 2, which is not transmembranaire which means it does not pump protons