Finals-Biochemistry-for-Medical-Laboratory-Science-Lecture-Part-2 PDF

Summary

This document covers lipid metabolism, including digestion, absorption, and storage in adipocytes. It discusses glycerol metabolism and fatty acid activation in the context of energy production. It relates the topic to other metabolic pathways and processes.

Full Transcript

BIOCHEMISTRY (LECTURE)

Lesson #9: Lipid Metabolism Triacylglycerol Storage
and Mobilization
Digestion and Absorption of Lipids Definition
Definition Ø Most cells in the body have limited
Ø The first step in the digestion of capability for storage of TAGs.
triacylglycerols and phospholipids Ø However, this activity is the major
begins in the mouth as lipids function of specialized cells called
encounter saliva. adipocytes, found in adipose tissue.
Ø Chewing with the action of Adipose tissue can be primarily
emulsifiers enables the digestive found beneath the skin. It is the insulator against
enzyme (lipase) to do their the excessive heat loss also it provides organs
tasks. with protection against physical shock.
Ø An adipocyte is a triacylglycerol-
Ø Lipids = source of energy. storing cell.
Enzyme: Lipase Ø Adipose tissue is tissue that contains
Ø Triacylglycerol (TAG) large numbers of adipocyte cells.

Ø As a result, the fats become tiny droplets and separate
from the watery components.
Ø In the stomach, gastric lipase starts to break down
triacylglycerols into diglycerides and fatty acids.

The use of TAGs stored in adipose tissue for
energy production is triggered by several
Ø As stomach contents enter the hormones.
small intestine, bile combines o Epinephrine and Glucagon – stimulates
the separated fats with its own fat mobilization.
watery fluids. HSL – Hormone Sensitive Lipase
Ø Bile contains bile salts, o Inactive after phosphorylation active
lecithin, and substances derived cAMP – Cyclic Adenosine Monophosphate
from cholesterol, so it acts as an o Serves as the second messenger.
emulsifier. o Signal transduction.
Ø As pancreatic lipase enters the Ø The overall process of tapping the body’s
small intestine, it breaks down the triacylglycerol energy reserves (adipose tissue) for
fats into free fatty acids and energy is called triacylglycerol mobilization.
monoglycerides. Ø Triacylglycerol mobilization is the hydrolysis of
Ø Bile salts envelop the fatty acids and monoglycerides triacylglycerols stored in adipose tissue, followed by
to form micelles. release into the bloodstream of the fatty acids and
glycerol so produced.
Ø Triacylglycerol mobilization is an ongoing process.
On the average, about 10% pf the TAGs in adipose
Ø Lipid Metabolism tissue are replaced daily by new triacylglycerol
molecules.
Ø Triacylglycerol energy reserves (fat reserves) are the
human body’s major source of stored energy.
Ø Energy reserves associated with protein, glycogen,
and glucose are small to very small when compared
to fat reserves.

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Glycerol Metabolism Fatty Acid Activation
Definition Ø The outer mitochondrial membrane is the site of fatty
Ø Glycerol metabolism primarily involves processes acid activation, the first stage of fatty acid oxidation.
considered in the previous chapter. After entering the Free fatty acid to Acyl CoA
bloodstream, glycerol travels to the liver or kidneys, o Enzyme: Acyl CoA Synthetase
where it is converted, in a two-step process, to
dihydroxyacetone phosphate.
Main Idea: To convert glycerol to DHAP

In activation, this reaction requires the
expenditure of 2 high energy phosphate bonds
from a single ATP molecule.
o From ATP to AMP. Result: 2Pi
1. The first step involves phosphorylation of a primary - 2 ATP consumed
hydroxyl group of the glycerol. Ø Here, the fatty acid is converted to a high-energy
Phosphorylation derivative of coenzyme A. reactants are the fatty acid,
From Glycerol to Glycerol-3-Phosphate coenzyme A, and a molecule of ATP.
o Enzyme: Glycerol kinase Ø The activated fatty acid-CoA molecule is called acyl
CoA.

Ø The difference between the designations acyl CoA is
2. In the second step, glycerol’s secondary alcohol that acyl refers to a random-length fatty acid carbon
group (C-2) oxidized to a ketone. chain that is covalently bonded to coenzyme A,
Oxidation whereas acetyl refers to a two-carbon chain
Glycerol-3-Phosphate to Dihydroxyacetone covalently bonded to coenzyme A.
phosphate Fatty Acid Transport
o Enzyme: Glycerol-3-Phosphate Ø Acyl CoA is too large to pass through the inner
dehydrogenase mitochondrial membrane to the mitochondrial matrix,
where the enzymes needed for fatty acid oxidation.
Carnitine Shuttle System
o Acyl CoA + Carnitine = Acyl Carnitine

Ø The following equation represents the overall
reaction for the metabolism of glycerol:

DHAP is intermediate in the glycolysis and
gluconeogenesis.

Oxidation of Fatty Acids
3 Parts to the Process by which Fatty Acids
are Broken Down to Obtain Energy (ATO)
1. The fatty acids must be activated by bonding to
coenzyme A.
2. The fatty acid must be transported into the
mitochondrial matrix by a shuttle mechanism.
3. The fatty acid must be repeatedly oxidized, cycling
through a series of four reactions, to produce acetyl
CoA, FADH2 and NADH.

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Reactions of the β-Oxidation Pathway Ø Step #4: Chain Cleavage
Ø The β-oxidation pathway The fatty acid chain is broken between the a and
is a repetitive series of b carbons by reaction with coenzyme A
four biochemical reactions molecule. The result is an acetyl CoA molecule
that degrades acyl CoA to and a new acyl CoA molecule that is shorter by
acetyl CoA by removing two carbon atoms than its predecessor.
two carbon atoms at a o Β-Ketoacyl CoA to Acyl CoA with two
time with FADH2 and fewer carbon atoms to Acetyl CoA
NADH also being - Enzyme: Thiolase
produced.
Ø For a saturated fatty acid,
the β-oxidation pathway
involves the following
functional group changes Ø Result:
at the β carbon and the 1 Acetyl CoA
following reaction types. 1 NADH
1 FADH2

Ø The new acyl CoA molecule
Ø Step #1: Oxidation (dehydrogenation) (now shorter by two carbons)
Hydrogen atoms are removed from the a and b is recycled through the same
carbons, creating a double bond between these set of four reactions again.
two carbon atoms. FAD is the oxidizing agent, Ø This yields another acetyl
and a FADH2 molecule is a product. CoA, a two-carbon-shorter
o Acyl CoA (single bond) to trans-Enoyl new acyl CoA, FADH2 and
CoA (double bond) NADH.
- Enzyme: Acyl CoA dehydrogenase Ø Recycling occurs again and
again, until the entire fatty
acid is converted to acetyl
CoA.
Ø Thus, the fatty acid carbon
chain is sequentially degraded,
Ø Step #2: Hydration two carbons at a time.
A molecule of water is added across the trans Ø The number of repetitions of the b-oxidation pathway
double bond, producing a secondary alcohol at that are needed to produce the acetyl CoA is always
the β-carbon position. one less than the number of acetyl CoA molecules
o trans-Enoyl CoA (double bond) to L-β- produced because the last repetition produces two
Hydroxyacyl CoA (single bond) acetyl CoA molecules as a C4 unit splits into two C2
- Enzyme: Enoyl CoA hydratase units.

Fatty Acid = # of Carbons
Acetyl CoA = # of Fatty Acids divide by 2
Ø Step #3: Oxidation (dehydrogenation) Repetitive Sequence = Acetyl CoA – 1
The β-hydroxy group is oxidized to a ketone o Repetitive Sequence = FADH2 / NADH
functional group with NAD+ serving as the
oxidizing agent. ATP Production from
o L-β-Hydroxyacyl CoA (single bond) to Fatty Acid Oxidation
β-Ketoacyl CoA (double bond) Definition
- Enzyme: β-Hydroxyacyl CoA Ø Let us calculate ATP
dehydrogenase production for the
oxidation of a specific fatty
acid molecule, stearic acid
(18:0), and compare it
with that from glucose.

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Ø Gross ATP:
60 ATP + 7.5 ATP + 12.5 ATP = 80 ATP
Ø Figure on the left shows Ø Fatty Acid Activation:
that for each four-reaction 2 ATP
sequence except the last Ø Net ATP Production:
one, 1 FADH2 molecule, 80 ATP – 2 ATP = 78 ATP
1 NADH molecule, and
1 acetyl CoA molecule is Ketone Bodies
produced. Definition
Ø In the final four-reaction Ø Ordinarily, when there is adequate balance between
sequence, two acetyl CoA lipid and carbohydrate metabolism, most of the acetyl
molecules are produced CoA produced from the β-oxidation pathway is
in addition to the FADH2 further processes through the citric acid cycle.
and NADH molecules. Ø Certain body conditions upset the lipid-carbohydrate
Ø Eight repetitions of the balance required for acetyl CoA generated by fatty
β-oxidation pathway are acids to be processed by the citric acid cycle.
required for the oxidation Dietary intake high in fat and low in
of stearic acid, an 18-carbon acid. carbohydrates.
Ø These eight repetitions of the pathway produce 9 Diabetic conditions, where the body cannot
acetyl CoA molecules, 8 FADH2 molecules and 8 adequately process glucose even though it is
NADH molecules. present.
Prolonged fasting conditions, including
starvation.
Types of Ketone Bodies

Ø Kreb’s Cycle Acetoacetate
3 NADH x 2.5 ATP = 7.5 ATP β-Hydroxybutyrate
1 FADH2 x 1.5 ATP = 1.5 ATP Acetone
1 GTP x 1 ATP = 1 ATP Ø Chemically, these three structures are closely related.
o Always 10 ATP The relationships are most easily seen if the focus
o 10 ATP = 9 Acetyl CoA starts with the molecule acetate.
Problem Solving
Ø What is the net ATP production for the complete 1. Reduction of the ketone group present in acetoacetate
oxidation of lauric acid, the C12 saturated fatty acid, to a secondary alcohol produces β-hydroxybutyrate.
to CO2 and H2O? Acetoacetate to β-hydroxybutyrate
1 Acetyl CoA = 10 ATP o Enzyme: Reducing agent
1 NADH = 2.5 ATP
1 FADH2 = 1.5 ATP

2. Decarboxylation of acetoacetate produces acetone.
Acetoacetate to Acetone
o Enzyme: Decarboxylation

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Ø Step #3: Chain Cleavage
Ketogenesis HMG-CoA is then cleaved to acetyl CoA and
Ø Ketogenesis is the metabolic pathway by which acetoacetate.
ketone bodies are synthesized from Acetyl CoA. o HMG-CoA to Acetoacetate and Acetyl
Ø Items to consider about this process prior to looking CoA
at the actual steps in this four-step process are: - Enzyme: HMG-CoA lyase

1.The primary site for the process is liver
mitochondria.
2. The first ketone body to be produced is
acetoacetate. This production occurs in Step 3 of
ketogenesis.
3. Some of the acetoacetate produced in Step 3 is
converted to the second ketone body, β- Ø Step #4: Reduction
hydroxybutyrate, in Step 4 of ketogenesis. Acetoacetate is reduced to β-hydroxybutyrate.
4. The acetoacetate and β-hydroxybutyrate The reducing agent is NADH.
synthesized by ketogenesis in the liver are o Acetoacetate to β-hydroxybutyrate
released to the bloodstream where acetone, the - Enzyme: β-hydroxybutyrate
third ketone body, is produced. dehydrogenase
5. Acetoacetate is somewhat unstable and can Ø Clinical Significance
spontaneously or enzymatically lose its carboxyl Ketoacidosis – during uncontrolled diabetes. Too
group to form acetone. much production of ketone bodies within the
6. The ketone body acetone present in the body. Diabetic ketone acidosis.
bloodstream is a volatile substance that is mainly Ketogenic – e.g., ketogenic diet
excreted by exhalation.
7. The amount of acetone present is usually small Lipogenesis
compared to the concentrations of the other two Definition
ketone bodies. Ø Is the metabolic pathway by which fatty acids are
The Process of Ketogenesis synthesized from acetyl CoA.
Ø Step #1: First Condensation Ø Is not simple a reversal of the steps for degradation of
Ketogenesis begins as two acetyl CoA molecules fatty acids (the β-oxidation pathway).
combine to produce acetoacetyl CoA, a reversal Features of Lipogenesis
of the last step of the β-oxidation pathway.
o 2 Acetyl CoA to Acetoacetyl CoA Lipogenesis Lipolysis
- Enzyme: Thiolase 1. Lipogenesis occurs in 1. Degradation of fatty
the cell cytosol. acids occurs in the
2. Lipogenesis enzymes mitochondrial matrix.
are collected into a 2. The enzymes
multienzyme involved in fatty acid
complex called fatty degradation are not
acid synthase. physically associated,
3. Lipogenesis so the reaction steps
Ø Step #2: Second Condensation intermediates are are independent.
Acetoacetyl CoA then reacts with a third acetyl bonded to ACP (acyl 3. The carrier for fatty
CoA and water to produce 3-hydroxy-3- carrier protein) acid degradation
methylglutaryl CoA (HMG-CoA) and CoA— 4. Fatty acid synthesis intermediates is CoA.
is dependent on the 4. Fatty acid
SH. reducing agent degradation is
o Acetoacetyl CoA and Acetyl CoA to NADPH. dependent on the
HMG-CoA 5. Fatty acids are built oxidizing agents
- Enzyme: HMG-CoA synthase up two carbons at a FAD and NAD+.
time during 5. Fatty acids are
synthesis. broken down two
6. In lipogenesis, acetyl carbons at a time
CoA is used to form during degradation.
malonyl ACP, which 6. CoA derivatives are
becomes the carrier involved in all steps
of the two carbon of fatty acid
units. degradation.

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When does Lipogenesis occurs?
Ø Lipogenesis occurs in well fed condition. The Malonyl CoA so produced then reacts with
Ø Conditions Favoring Lipogenesis ACP to produce malonyl ACP.
Excess of free glucose after heavy carbohydrate
meals.
Insulin promotes lipogenesis.
Where does Lipogenesis occur?
Ø Predominant site for Lipogenesis
Liver Cytoplasm
Ø Other tissues for Lipogenesis Ø Chain Elongation
Intestine Step #1: Condensation
Mammary Glands o Acetyl ACP and Malonyl ACP
Reasons for Lipogenesis condense together to form Acetoacetyl
Ø Free excess Glucose can’t be stored as it is in body ACP
cells and tissues.
Ø Free excess Glucose is first converted and stored in
the form of Glycogen.
Ø Storage of Glycogen is limited.
Ø In a well-fed condition after limited storage of
Glycogen.
Ø When still there remains Free Excess Glucose.
Ø This Free Excess Glucose is oxidized to Pyruvate via
Glycolysis.
Ø Further Pyruvate to Acetyl-CoA via PDH Complex
reaction. Step #2: First Hydrogenation
Ø This Acetyl-CoA when excess is then diverted for o The Keto Group of the Acetoacetyl
Lipogenesis. Complex, which involves the β-carbon
Triacylglycerols (TAG) atoms, is reduced to the corresponding
Ø To transform free excess Glucose to Acetyl-CoA alcohol by NADPH.
further into Fatty acids.
Ø Fatty acids are stored as TAG.
Ø Storageable form of Lipid (TAG).
Ø TAG in Adipocytes can be stored in unlimited
amounts.
2 Parts of Lipogenesis Step #3: Dehydration
Ø ACP Complex Formation – it shows that all o The alcohol produced in Step 2 is
intermediates in lipogenesis are bound to ACP-SH or dehydrated to introduce a double bond
also known as acyl carrier proteins. into the molecule (between the α and β
1. Acetyl ACP Formation (C2) carbons)
C2 to ACP

2. Malonyl ACP Formation (C3)
Carboxylation Step #4: Second Hydrogenation
C3 to ACP o The double bons introduced in Step 3 is
converted to a single bond through
hydrogenation.
o As in Step 2, NADPH is the reducing
agent.
o This reaction occurs only when cellular
ATP levels are high.
o It is catalyzed by Acetyl CoA
Carboxylase Complex, which requires
both Mn2+ion and the B Vitamin Biotin
for its activity.

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Fate of Fatty Acid-Generated
Acetyl CoA
Citric Acid Cycle
(Krebs Cycle)
Ø Acetyl-CoA enters the Citric Acid Cycle, where it
combines with oxaloacetate to form citrate.
Ø Through a series of enzymatic reactions, citrate is
converted back to oxaloacetate, producing ATP,
NADH, and FADH2, which are used for energy
production.

Lipogenesis and Citric
Acid Cycle Intermediates
Relationship between Lipogenesis
and Citric Acid Cycle Intermediates
Ø The intermediates in the last four steps of the Citric
Acid Cycle are all C4 molecules.

Ketogenesis
Ø In the liver, during periods of low carbohydrate
availability (e.g., fasting, low-carbohydrate diets, or
uncontrolled diabetes),
acetyl-CoA is converted
into ketone bodies
(acetoacetate,
beta-hydroxybutyrate, and
acetone).
Ø Ketone bodies can be used
as an alternative energy
source by peripheral tissues,
including the brain, during prolonged fasting or
Ø The last four intermediates of the Citric Acid Cycle carbohydrate restriction.
bear the following relationship to each other. Cholesterol Synthesis
Succinate Ø Acetyl-CoA is the
starting material for the
biosynthesis of cholesterol.
Ø The intermediate C4 carbon chains of Lipogenesis The process begins with the
bear the following relationship to each other. conversion of Acetyl-CoA
Butyrate into HMG-CoA
(3-hydroxy-3-methylglutaryl-
CoA), which is then reduced to
Ø Note two important contrasts in these compound mevalonate by the enzyme
sequences: HMG-CoA reductase.
The Citric Acid intermediates involve C4 diacids Ø Mevalonate undergoes a series
and the Lipogenesis intermediates involve C4 of reactions to
monoacids. eventually form
The order in which the various acid derivative cholesterol, a vital
types are encountered in Lipogenesis is the component of cell membranes and precursor for
reverse of the order in which they are steroid hormones and bile acids.
encountered in the Citric Acid Cycle.

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Fatty Acid Synthesis Fatty Acid Biosynthesis
Ø Although Acetyl-CoA is produced from fatty acids Ø The buildup of excess Acetyl CoA when dietary
during oxidation, it can also be used for fatty acid intake exceeds energy needs to leads to accelerated
synthesis. In the cytoplasm, Acetyl-CoA is converted fatty acid biosynthesis.
into Malonyl-CoA by Acetyl-CoA carboxylase. Cholesterol Biosynthesis
Ø As with fatty acid biosynthesis, cholesterol
biosynthesis occurs primarily when the body is in an
Acetyl CoA—rich state.

B Vitamins and Lipid Metabolism
Thiamin (Vitamin B1)
Ø Is a precursor for the coenzyme
Thiamine Pyrophosphate (TPP),
which is essential for the Pyruvate
dehydrogenase complex.
Ø This complex converts Pyruvate
Ø Malonyl-CoA is then used in (from Glycolysis) into Acetyl-CoA,
the fatty acid synthase which is necessary for entering the
complex to elongate Citric Acid Cycle and Lipid
fatty acid chains, Synthesis.
producing palmitate, Riboflavin (Vitamin B2)
which can be further Ø Is a component of the coenzymes
modified into other FAD (Flavin Adenine Dinucleotide)
fatty acids. and FMN (Flavin Mononucleotide).
Ø These coenzymes are crucial in the
beta-oxidation of fatty acids, where
Ø Acetyl-CoA serves they participate in the
as a precursor for the dehydrogenation steps, helping to
synthesis of certain generate acetyl-CoA from fatty acids.
amino acids and
other important Niacin (Vitamin B3)
biomolecules. Ø Is converted into NAD+
For example, (Nicotinamide Adenine
Acetyl-CoA can Dinucleotide) and NADP+
be used in the (Nicotinamide Adenine
production of the Dinucleotide Phosphate), which
amino acid leucine are key coenzymes in oxidation-
or in the formation reduction reactions.
of acetylcholine, a Ø NAD+ is required for the
neurotransmitter. oxidation of fatty acids during
beta-oxidation, while NADP+ is
involved in the synthesis of fatty
Relationships between Lipid acids.
and Carbohydrate Metabolism
Oxidation in the Citric Acid Cycle
Ø Both lipids (Fatty Acids and Glycerol) and
carbohydrates (Glucose) supply Acetyl CoA for the
operation of this cycle. Pyridoxine (Vitamin B5)
Ketone Body Formation Ø Is involved in amino acid
Ø This process is of major importance when there is metabolism, which intersects
imbalance between lipid and carbohydrate metabolic with Lipid Metabolism,
processes. The imbalance is caused by inadequate particularly in the production of
glucose metabolism during times of adequate lipid carnitine, a molecule necessary
metabolism. for transporting fatty acids into
the mitochondria for beta-
oxidation.

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Biotin (Vitamin B7)
Ø Is a coenzyme for
carboxylase enzymes,
such as Acetyl-CoA
carboxylase, which is
critical in the first step of
fatty acid synthesis.
Ø It is also involved in the
catabolism of odd-chain
fatty acids, which require
the conversion of
propionyl-CoA to succinyl-CoA.
Folate (Vitamin B9)
Ø Is involved in the transfer of
one-carbon units during the
synthesis of nucleotides and
amino acids.
Ø Its role in lipid metabolism
is more indirect, influencing
homocysteine levels, which
can affect cardiovascular
health and lipid profiles.
Cobalamin (Vitamin B12)
Ø Is necessary for the
conversion of
methylmalonyl-CoA to
succinyl-CoA, a critical step
in the catabolism of odd-
chain fatty acids. This
reaction prevents the
accumulation of
methylmalonic acid, which
could otherwise disrupt lipid
metabolism.

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Lesson #10: Protein Metabolism d. The enzyme carboxypeptidase is active.
o Small Intestine
Protein Digestion and Absorption
Process Amino Acid Utilization
Ø Protein metabolism is a supporting role. Definition
Ø In overall metabolism, within a normal diet, Ø Amino acids produced from the digestion of proteins
carbohydrate and fats supplies almost 90% of the enter the amino acid pool of the body.
energy needed within the body. 10% is from the Ø The amino acid pool is the total supply of free amino
Protein. acids available for use in the human body.
Ø Stomach Ø Sources of Amino Acids:
The digestion process happens in the stomach. Dietary Protein
o HCl pH: 1.5-2.0 (highly acidic) Protein Turnover (happens in the liver)
o Pepsin: hydrolyzes about 10% of the Biosynthesis (happens in the liver)
peptide bonds in proteins. Protein Turnover
- HCl and Pepsin is from hormone Ø Protein Turnover is the repetitive process in
gastrin. which proteins are degraded and
Ø Small Intestine resynthesized within the human body.
Production of Secretin Ø Within the human body, proteins
o Secretin stimulates the pancreatic are continually being degraded
production. Produces bicarbonate ions. (hydrolyzed) to amino acids
- Bicarbonate Ions = base (basic) and resynthesized.
Disease, injury, and “wear and tear”
Varies from few minutes to several hours.
Ø Healthy adult about 2% of the body’s protein is
broken down and resynthesized every day.
Biosynthesis
Ø Biosynthesis of amino acids by the liver also supplies
the amino acid pool with amino acids. However, only
the nonessential amino acids can be produced in this
manner.
Ø 11 Nonessential Amino Acids
Polar Neutral Amino Acids
Polar Basic Amino Acids
Practice Polar Acidic Amino Acids
Ø Determine the location within the human body where o Alanine
each of the following aspects of protein digestion o Arginine
occurs. o Asparagine
a. The enzyme trypsin is active. o Aspartic Acid
o Small Intestine o Cysteine
b. Large polypeptides are produced. o Glutamic Acid
o Stomach o Glutamine
c. Protein is denatured by HCl. o Glycine
o Stomach o Proline
d. Active transport moves amino acids into the o Serine
bloodstream. o Tyrosine
o Intestinal Lining Nitrogen Balance
Ø Based on the information in Figure 26.1, determine Ø Nitrogen Balance
the location within the human body where each of the
Is the state that results when the amount of
following aspects of protein digestion occurs.
nitrogen taken into the human body as protein
a. The enzyme aminopeptidase is active. equals the amount of nitrogen excreted form the
o Small Intestine body in waste materials.
b. Peptide bonds are hydrolyzed under the action of
pepsin.
o Stomach
c. Individual amino acids are produced.
o Small Intestine

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Ø Negative Nitrogen Balance Transamination and
Is when protein degradation exceeds protein Oxidative Deamination
synthesis, the amount of nitrogen in the urine 2 Stages of Degradation
exceeds the amount of nitrogen ingested (dietary of Amino Acid
protein). This is accompanied by a state of tissue 1. The removal of the amino group
wasting. 2. The degradation of the remaining carbon skeleton
o Examples:
- Protein poor diets
- Starvation

Ø Positive Nitrogen Balance
Nitrogen intake exceeds nitrogen output.
Indicates that the rate of protein anabolism
(synthesis) exceeds that of protein catabolism.
o Examples:
- Growth
- Pregnancy

Transamination vs Deamination
Ø The release of an amino group from most amino
acids requires a two-step process involving
Ø Although the overall transamination followed by oxidative deamination.
nitrogen balance in the
body often varies, the Transamination Deamination
relative concentrations Is the removal of an
of amino acids within Is the transfer of an amino acid group
the amino acid pool Definition amino group to a from an organic
remain essentially keto acid. compound.
constant.
Ø During negative nitrogen balance, the body must Involves two Involves one
resort to degradation of proteins that were Molecules molecules: amino molecule: an
synthesized for other functions. acid and keto acid amino acid
Ø The amino acids from the body’s amino acid pool are Transaminases
used in 4 different ways: Enzymes and Deaminase
Protein Synthesis (75% Free Amino Acid) aminotransferases
Synthesis of nonprotein nitrogen-containing Conversion of
compounds (Purine, pyrimidines) essential amino Breakdown of amino
Synthesis of nonessential amino acids Conversion acids into acids in order to
Production of energy nonessential amino produce energy
acids

Derivatives of 3 Carboxylic Acids
Ø Are particularly important in metabolic reaction.
Propionic – a three-carbon monoacid
Succinic – a four-carbon monoacid
Glutaric – a five-carbon monoacid

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Practice
Ø Determine the structural formulas for the products in
a transamination reaction in which the reactants are
aspartate and pyruvate.

Aspartate to Oxaloacetate
Pyruvate to Alanine

Transamination Reaction
Ø Is a biochemical reaction that involves the
interchange of the amino group of an α-amino acid
with the keto group of an α-keto acid.

Ø Determine the structural formulas for the products in
a transamination reaction in which the reactants are
Ø There are at least 50 aminotransferase enzymes α-ketoglutarate and alanine.
associated with transamination reactions. Most are
specific for α-ketoglutarate as the amino group
acceptor but are less specific for the amino acid.
Glutamate is the amino acid produced from the action α-ketoglutarate to Glutamate
of α-ketoglutarate specific aminotransferases. Alanine to Pyruvate
Initial Effect of
Transamination Reactions
Ø Is to collect the amino acids from a variety of amino
acids into just two amino acids – glutamate (most
cells) and alanine (muscle cells)

Ø An important exception to the α -ketoglutarate
specificity of aminotransferases is found in muscle
cells. Here, many aminotransferases have specificity
for the keto acid pyruvate. Alanine is the amino acid
produced from the action of such pyruvate specific
enzymes.

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Oxidative Deamination
Ø Is a biochemical reaction in which an α-amino acid is
converted into an α-keto acid with release of an The Urea Cycle
ammonium ion. Definition
Ø Oxidative deamination occurs primarily in liver and Ø The urea cycle is the series of biochemical reactions
kidney mitochondria. in which urea is produced from ammonium ions and
carbon dioxide.
Ø Three amino acids are involved in the urea cycle.
Arginine
Ornithine
Citrulline
Ø The sum of the transamination and deamination steps o Ornithine and Citrulline are proteins
of the degradation of amino acid is: that are not found in proteins a.k.a. non-
standard amino acids.
Ø Nitrogen Sources
Ø The NH4+ so produce, a toxic substance if left to Ammonium Ions (NH4+)
accumulate in the body, is then converted to urea in Aspartate
the urea cycle. o From blood to liver to kidney to urea
Ø Two amino acids, serine and threonine, exhibit
different behavior from the other amino acids. They
undergo direct deamination by a dehydration-
hydration process rather than oxidative deamination.

Practice
Ø Indicate whether each of the following reaction
characteristics is associated with the process of
transamination or with the process of oxidative
deamination.
a. The enzyme glutamate dehydrogenase is active.
o Oxidative Deamination
b. The coenzyme pyridoxal phosphate is needed.
o Transamination Ø Orange-Colored Cats Always Ask For Awesome
c. An amino acid is converted into a keto acid with Umbrellas
release of ammonium ion. Ornithine, Carbamoyl Phosphate, Citrulline,
o Oxidative Deamination Aspartate (enters cycle), Arginosuccinate,
d. One of the reactants is an amino acid and one of Fumarate (leaves cycle), Arginine, Urea (leaves
the products is an amino acid. cycle)
o Transamination Practice
Ø Indicate whether each of the following reaction Ø For each of the following urea cycle events identify
characteristics is associated with the process of the urea cycle intermediate that is involved. The urea
transamination or with the process of oxidative cycle intermediates are ornithine, citrulline,
deamination. arginosuccinate, and arginine.
a. One of the reactants is a keto acid and one of the a. Intermediate participates in a condensation
products is a keto acid. reaction.
o Transamination b. Intermediate is produced while urea is formed.
b. Enzymes with specificity toward α-ketoglutarate c. Intermediate must be transported from the
are often active. mitochondrial matrix to the cytosol.
o Transamination d. Intermediate is the product in Step 3 of the urea
c. NAD is used as an oxidizing agent. cycle.
o Oxidative Deamination
d. An aminotransferase enzyme is active.
o Transamination

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Ø For each of the following urea cycle events identify
the urea cycle intermediate that is involved. The urea
cycle intermediates are ornithine, citrulline,
arginosuccinate, and arginine.
a. Intermediate reacts with carbamoyl phosphate.
b. Intermediate must be transported from the
cytosol to the mitochondrial matrix.
c. Intermediate is a reactant in a hydrolysis
reaction.
d. Intermediate is the reactant in Step 2 of the urea
cycle.
Urea Cycle Net Reaction
Ø The equivalent of a total of four ATP molecules is
expended in the production of one urea molecule.
Two ATP molecules are consumed in the production
of carbamoyl phosphate, and the equivalent of two
ATP molecules is consumed in Step 2 of the urea
cycle.
The Urea Cycle
Ø Glucogenic Amino Acid
Is an amino acid that has a carbon-containing
degradation product that can be used to produce
glucose via gluconeogenesis.
Ø Ketogenic Amino Acid
Is an amino acid that has a carbon-containing
degradation product that can be used to produce
ketone bodies.

Ø Purely Ketogenic
Leucine
Lysine
Ø Both Glucogenic and Ketogenic
Alanine
Serine
Amino Acid Carbon Skeletons Tyrosine
Definition
Glycine
Ø Each of the 20 amino
acid carbon skeletons Threonine
undergoes a different Phenylalanine
degradation process. Cysteine
Ø It is important to Tryptophan
consider the products Isoleucine
of these 20 degradation Ø Purely Glucogenic
sequences: Glutamate
Ø 7 Degradation Products of Amino Acids: Proline
Pyruvate Valine
Acetyl-CoA Glutamine
Acetoacetyl-CoA Arginine
α-ketoglutarate (intermediates of Citric Acid Asparagine
Cycle) Histidine
Succinyl-CoA (intermediates of Citric Acid Methionine
Cycle) Aspartate
Fumarate (intermediates of Citric Acid Cycle)
Oxaloacetate (intermediates of Citric Acid
Cycle)

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Amino Acid Biosynthesis Ø The oxygen-carrying ability of red blood cells is due
Definition to the protein hemoglobin.
Ø The nonessential amino acids can be made in 1-3 Hemoglobin is a conjugated protein.
steps. Globin – the protein portion
Ø The essential amino acids can be made in 7-10 steps Heme – nonprotein portion (contains
(observations in microorganisms). 4 pyrrole groups with an iron
Ø Plants, consumed as food, are the major source of the atom in the center).
essential amino acids in humans and animals. o It is the iron atom
in heme that
interacts with O2.

Ø Old red blood cells are broken down in the:
Spleen (primary site)
Liver (secondary site)
Ø Globin – hydrolyzed to amino acids, which become
part of the amino acid pool.
Ø Iron Atom – becomes part of ferritin, an iron-storage
protein, which saves the iron for use in the
biosynthesis of new hemoglobin molecules.
Ø Tetrapyrrole – degraded to bile pigments that are
eliminated in feces and to a lesser extent in urine.
Heme Degradation
Ø Step #1: Degradation of heme begins with a ring-
opening reaction in which a single atom is removed.
Ø The starting materials for the biosynthesis of 11 The product is called biliverdin.
nonessential amino acids are: Molecular oxygen, O2, is required as a reactant.
3-phosphoglycerate Ring opening releases the iron atom to be
Pyruvate incorporated into ferritin.
Oxaloacetate The product containing the excised carbon atom
α-ketoglutarate is carbon monoxide.
Ø The lack of phenylalanine
hydroxylase caused the
metabolic disease
phenylketonuria (PKU).
Characterized by
elevated blood levels
of phenylalanine
and phenylpyruvate. Ø Step #2: In the second step of heme degradation,
Damage to developing brain cells. biliverdin is converted to
PKU leads to retarded mental development. bilirubin.
Management: This usually occurs in the spleen.
o Restrict children’s dietary The bilirubin is then transported
phenylalanine to that needed for protein by serum albumin to the liver,
synthesis until 6 years old. where it is rendered more
water-soluble by the attachment
Hemoglobin Catabolism of sugar residues to its
Definition propionate side chains (P side
Ø Red blood cells deliver oxygen to, and remove chains). The solubilizing sugar
carbon dioxide from, body tissues. is glucuronate.
Ø Mature red blood cells have no
nucleus or DNA. Instead, they
are filled with the red pigment
hemoglobin.
Ø The life span of a red blood
cell is about 4 months.

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Local Coloration
Ø The local coloration associated with a
deep bruise is also related to the
Solubilized bilirubin from the liver to small pigmentation associated with heme,
intestine. biliverdin, and bilirubin.
Here the bilirubin diglucuronide is changed, in a Ø The changing color of the bruise as it
multistep process, to either stercobilin for heals reflects the dominant degradation
excretion in feces or urobilin for excretion in product present at the time as the tissue
urine. repairs itself.

Interrelationships among
Metabolic Pathways
Definition
Ø Carbohydrate, Lipids, and Protein pathways are not
independent of each other but rather are integrally
linked.
Ø The numerous connections among pathways mean
that a change in one pathway can affect many other
pathways.
Ø A good illustration of the interrelationships among
Ø The tetrapyrrole degradation process obtained from pathways emerges from comparing the processes of
heme are known as bile pigments because they are eating (feasting), not eating for a short period
secreted with the bile (highly colored). (fasting), and not eating for a prolonged period
Stercobilin (starvation).
o Brownish hue = the reason why poops
are brown.
- 250-350 mg daily
Urobilin
o Yellowish hue = the reason why urine
are yellow.
- 1-2 mg daily
Ø When the body is functioning properly, degradation
of heme to bilirubin in the spleen = removal of
bilirubin from the blood by the liver.
Jaundice
Ø Jaundice is the condition that occurs when this
balance us upset such that bilirubin concentrations in
the blood become higher than normal.
Ø Can occur because of liver diseases, such as:
Infectious hepatitis and
cirrhosis, that decrease the
liver’s ability to process
bilirubin.
From spleen malfunction,
in which heme is degraded
more rapidly than it can be
absorbed by the liver.
From gallbladder malfunction, usually from an
obstruction of the bile duct.

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