Krebs Cycle Study Guide 2025 PDF

Summary

This document is a study guide for the Krebs cycle, also known as the Tricarboxylic Acid Cycle (TCA) or Citric Acid Cycle (CAC). It details the definitions, steps, importance, and regulation of this crucial metabolic pathway, specifically for medical students at King Salman International University. This guide also presents diagrams illustrating different aspects of the cycle.

Full Transcript

‫جامعة الملك سلمان الدولية‬
‫كلية الطب‬

Krebs' Cycle
Tricarboxylic Acid Cycle (TCA)
Citric Acid Cycle (CAC)
 TRICARBOXYLIC ACID CYCLE
(Citric Acid Cycle or Krebs' Cycle)

ILOs:
By the end of the course, the student should be able to:

1. Define tricarboxylic acid cycle.
2. Illustrate the steps of tricarboxylic acid cycle.
3. Point out the importance of tricarboxylic acid cycle.
4. Calculate the ATP generated per each turn of the cycle.
5. Explain how the tricarboxylic acid cycle is regulated.
6. Enumerate the inhibitors of the tricarboxylic acid cycle and
explain their mechanism of action.

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 TRICARBOXYLIC ACID CYCLE
(Citric Acid Cycle or Krebs' Cycle)

Definition:
-The citric acid cycle is known as the Krebs' cycle or the tricarboxylic acid cycle (TCA
cycle). It is formed of a series of reactions that are responsible for the complete
oxidation of the acetyl moiety of acetyl-CoA.
-It is the final common pathway for the oxidation of carbohydrates, lipids and proteins
because glucose, fatty acids and all amino acids are metabolized to acetyl-CoA or
intermediates of the cycle.
-During the reactions of the cycle, coenzymes (NAD+ and FAD) are reduced and
subsequently reoxidized by the respiratory chain with the formation of ATP.
Site
The enzymes of the TCA cycle are found in the mitochondrial matrix except succinate
dehydrogenase which is tightly bound to the inner mitochondrial membrane (forms
complex II of the respiratory chain). The enzymes of the TCA cycle are in close
proximity to the enzymes of the respiratory chain.
Steps of TCA Cycle
1- Formation of citrate
The TCA cycle begins with the condensation of acetyl moiety of acetyl-CoA (C2) with
oxaloacetate (C4) to form citrate (C6). The reaction is catalyzed by citrate synthase.
2- Formation of isocitrate
Citrate is converted to isocitrate by the enzyme aconitase; the reaction occurs in two
steps. Citrate is dehydrated to cis-aconitate then hydrated to isocitrate (C6). Aconitase
contains iron-sulfur proteins and requires reduced glutathione.
3- Formation of α-ketoglutarate
Isocitrate (C6) undergoes dehydrogenation catalyzed by isocitrate dehydrogenase to
form initially, oxalosuccinate (C6), which remains enzyme bound, and undergoes
decarboxylation to α-ketoglutarate (C5). This requires Mg2+ or Mn2+ for the
decarboxylation reaction. This reaction produces the first NADH and releases the first
CO2 of the cycle.
4- Formation of succinyl-CoA
α-ketoglutarate (C5) undergoes oxidative decarboxylation to succinyl-CoA. This
reaction is catalyzed by the enzyme α-ketoglutarate dehydrogenase complex. This
complex requires the following cofactors; thiamine pyrophosphate (TPP), lipoate,
CoASH, FAD and NAD+. This reaction produces the second NADH and releases the
second CO2.
5- Formation of succinate
Succinyl-CoA is converted to succinate (C4) by the enzyme succinate thiokinase.

Succinate thiokinase cleaves the high-energy thioester bond of succinyl-CoA, the
energy of which is used to generate the high energy phosphate bond of ATP. This is
the only reaction in the TCA cycle that generates ATP by substrate level
phosphorylation.

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6- Formation of fumarate
Succinate (C4) is dehydrogenated to fumarate (C4) by succinate dehydrogenase which
is bound to the inner mitochondrial membrane. The enzyme contains FAD (forms
FADH2) and two iron sulfur centers.
7- Formation of malate
Fumarate is hydrated to malate (C4) by the enzyme fumarase.
8- Regeneration of oxaloacetate
Malate is dehydrogenated to oxaloacetate (C4) by the enzyme malate dehydrogenase.
This produces the third NADH of the cycle. This reaction regenerates oxaloacetate,
which condenses with a new acetyl molecule of acetyl – CoA to repeat the cycle again.
Thus, the overall reactions of one turn of the Krebs' cycle yield two molecules of
CO2, three molecules of NADH , one molecule of FADH2 and one molecule of
ATP.

Summary Diagram for TCA Cycle

Citrate synthase

Malate Aconitase
dehydrogenase

Isocitrate
Fumarase dehydrogenase

Succinate -Ketoglutarate
dehydrogenase dehydrogenase

Succinate

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 CH3– CO ~ S-CoA
Active acetate CoA- SH
CH2– COOH
O=C- COOH HO–C– COOH
CH2-COOH CH2– COOH
Citrate synthase
Oxaloacetate H2O Citrate
Aconitase
NADH,H+
Fe2+
Malate dehydrogenase G-SH H2O
NAD+ TCA Cycle CH2– COOH
HO–CH–COOH
C– COOH
CH2– COOH
CH– COOH
L-Malate
Cis-aconitate
Fumarase Aconitase H2O
H2O Fe2+
G-SH
HC – COOH
CH2– COOH
HOOC – CH
ETC 10 ATP HC– COOH
Fumarate
HOCH– COOH
Isocitrate
FADH2
Succinate NAD+
dehydrogenase Isocitrate
FAD dehydrogenase
CH2– COOH NADH,H+
CH2– COOH
CH2– COOH
Succinate
HC– COOH
CoA-SH ATP O=C – COOH

Succinate thiokinase Oxalosuccinate
Mg2+
Isocitrate
ADP + Pi dehydrogenase
Mn2+ CO2
CH2– COOH -Ketoglutarate CoA-SH
NADH,H+ NAD+
dehydrogenase CH2– COOH
CH2
complex CH2
O=C ~ S-CoA
TPP, Lipoate, & FAD O=C – COOH
Succinyl-CoA CO2
-Ketoglutarate

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Importance of Citric Acid Cycle
The citric acid cycle is called an amphibolic pathway because it participates in both
catabolism and anabolism.
I- Energy production
The oxidation of one mole of the acetyl group of acetyl-CoA through Krebsʹ cycle
yields 10 moles of ATP.

ETC
3 NADH, H+ 7.5 ATP
ETC
FADH2 1.5 ATP
Substrate level
ADP + Pi ATP

Total 10 ATP

II- It is a common final pathway for oxidation of carbohydrates, fats and amino
acids

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III- Importance of citric acid cycle intermediates (anabolic function)
Many of the intermediates produced in the citric acid cycle are precursors for important
biomolecules (anabolic function).
1- Citrate
Citrate can be exported out of the mitochondria into the cytosol where it is broken down
by ATP-citrate lyase to yield oxaloacetate and acetyl-CoA. The acetyl-CoA produced
is a precursor for fatty acids and cholesterol.
2- α-ketoglutarate
α-ketoglutarate is converted by amino transferase into glutamate, which is an important
amino acid.
3- Succinyl-CoA
It is used for heme synthesis and oxidation of ketone bodies (Ketolysis).
4- Malate
Malate can be reoxidized into oxaloacetate or can be oxidatively decarboxylated to
pyruvate by malic enzyme (it is one of the sources of NADPH).

Malic Enzyme COOH
HOCH-COOH
C=O
CH2-COOH
Malate NADP+ NADPH,H+ CH3
+ CO2 Pyruvate

5- Oxaloacetate
Oxaloacetate can be transaminated by aspartate aminotransferase (AAT or AST) to
form aspartate, which is an important amino acid.
In cytosol, oxaloacetate is converted into 2-phosphoenolpyruvate (2-PEP) by
phosphoenolpyruvate carboxykinase enzyme (PEPCK), which is an important step in
gluconeogenesis (formation of glucose from non-carbohydrate compounds).
IV. Importance of CO2
CO2 produced by isocitrate dehydrogenase and α-ketoglutarate dehydrogenase is used
in many important reactions :
1- Conversion of pyruvate to oxaloacetate by pyruvate carboxylase.
2- Conversion of acetyl -CoA to malonyl-CoA, which is used in FA synthesis.
3- Conversion of propionyl-CoA to methylmalonyl-CoA.
4- Synthesis of carbamoyl-phosphate for synthesis of pyrimidines and urea.
5- Formation of C6 of purines.
6- Formation of H2CO3/ BHCO3 buffer system.
V. Interconversion between carbohydrates, fats and proteins
TCA cycle represents the center of body metabolism. Through the cycle intermediates,
carbohydrates, fats and amino acids are interconverted during the feed-starve cycle.

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 Importance of the Intermediates of TCA Cycle
(Anabolic Function)

Cholesterol
Cytosolic
ATP – Citrate
Lyase
Citrate Acetyl - CoA
CoA Oxaloacetate
ATP ADP + Pi
Fatty acids

Transamination
-Ketoglutarate Glutamate

Heme

Succinyl-CoA

Ketolysis

Cytosolic malic enzyme
Malate Pyruvate

NADP+ NADPH,H+ + CO2

Cytosolic PEPCK
Oxaloacetate 2-Phosphoenolpyruvate

GTP GDP + CO2 Gluconeogenesis
AST

Aspartate Glucose

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Regulation of Citric Acid Cycle
The citric acid cycle must be carefully regulated by the cell. If the citric acid cycle was
permitted to run unchecked, large amounts of metabolic energy would be wasted in the
over production of reduced coenzymes and ATP. Conversely if the citric acid cycle ran
too slowly, ATP would not be generated fast enough to sustain the cell.
In the Krebs' cycle there are three irreversible steps. These three reactions of the cycle
are catalyzed by citrate synthase, isocitrate dehydrogenase and α-ketoglutarate
dehydrogenase which are the rate controlling enzymes of the cycle (key enzymes).
The TCA is regulated through as follows:
A. Substrate activation and product feedback inhibition
1-The availability of both oxaloacetate and acetyl-CoA is very important for the
activity of citrate synthase.
- Oxaloacetate is formed from pyruvate by pyruvate carboxylase enzyme. The latter
is allosterically activated by acetyl-CoA, this ensures an enough supply of oxaloacetate
for the activation of the cycle.
- The mitochondria contain a very low concentration of oxaloacetate (lower than the
Km value of oxaloacetate on citrate synthase). Therefore, any increase in the
concentration of oxaloacetate increases the activity of citrate synthase to a great extent.
2- Increased concentration of succinyl-CoA produces feedback inhibition of citrate
synthase and α-ketoglutarate dehydrogenase.

Diagram for Regulation of TCA Cycle

Active Acetate
+
Pyruvate Citrate synthase ADP & Ca2+ (muscles)
carboxylase
+
Pyruvate Oxaloacetate
+ Citrate
- -
L-Malate ADP & NAD
Ca2+ (muscles)

Fumarate
(C4) ATP Isocitrate
+
Succinate - Isocitrate
dehydrogenase
- - -Ketoglutarate -
Succinyl~S-CoA

ADP & NAD -Ketoglutarate -
+ NADH
Ca2+ (muscles) dehydrogenase

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B- NADH/NAD+ ratio
High NADH/NAD+ ratio inhibits isocitrate dehydrogenase and alpha-ketoglutarate
dehydrogenase and vice versa.
This mechanism for regulation is due to inhibition by NADH of the enzymes that use
NAD+ and produce NADH.
This mechanism explains that the cycle is only active under aerobic condition, where
ETC is active to oxidize NADH into NAD+.
C- ATP/ ADP ratio (Energy Requirements)
The rate of the Krebs' cycle reflects the cell's need for ATP. When ATP/ ADP ratio is
high, the rate of the citric acid cycle is reduced.
High ATP/ADP ratio inhibits citrate synthase, isocitrate dehydrogenase and alpha-
ketoglutarate dehydrogenase and vice versa.

So, TCA cycle is turned on by high ratios of ADP/ATP or NAD+/NADH and vice
versa.

During Work
↓ATP → ↑ ADP → Activation of ATP synthase → Activation of oxidation by ETC
→ ↓NADH → ↑NAD → Activation of TCA cycle key enzymes

During Rest
↑ATP → ↓ADP → Inhibition of ATP synthase → Inhibition of oxidation by ETC
→ ↑NADH → ↓NAD → Inhibition of TCA cycle key enzymes

D- Calcium (Effect of muscular exercise):
Calcium release from sarcoplasmic reticulum is increased to trigger muscle
contraction. Ca2+ is transported into mitochondria by specific Ca2+ transporters through
the outer and inner mitochondrial membrane. Within the mitochondria, Ca2+ activates
allosterically citrate synthase, isocitrate dehydrogenase and α-ketoglutarate
dehydrogenase to supply the contracting muscles with ATP.

Inhibitors of Citric Acid Cycle
1. Fluroacetate inhibits activity of aconitase. It is used as rodenticide. In the body, it
is converted to fluoroacetyl-CoA, which gives rise to fluorocitrate after condensing with
oxaloacetate. The aconitase is inhibited by fluorocitrate.
2. α-ketoglutarate dehydrogenase is inhibited by arsenic compounds. Arsenite forms
a stable complex with the thiol groups of lipoic acid making it unavailable for the
enzyme action.
3. Malonate is a competitive inhibitor of succinate dehydrogenase.

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