CHEM206 Week 7 - Protein and Amino Acid Metabolism PDF

Summary

These notes cover the topic of protein and amino acid metabolism. They detail the learning objectives, sources, breakdown, and degradation of proteins and amino acids. Also include biological, chemical and industrial aspects, with diagrams of relevant processes.

Full Transcript

CHEM206 Amino Acid Metabolism

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Amino Acid Metabolism Learning Objectives
By the end of this topic you will understand :
List the sources of amino acids for building proteins.
Discuss nitrogen fixation
The nitrogenase reaction
Families of amino acids based on their biosynthetic pathways and the relationship between amino acids and the citric acid cycle
Amino acid biosynthesis
Describe what is meant by the term essential amino acids.
Describe the breakdown of dietary proteins
Discuss the process of protein turnover
Explain the process whereby an amino group is removed form an amino acid.
Discuss the degradation of AA in muscle during prolonged exercise and fasting.
Describe how amino acid degradation is linked to the TCA cycle.
Discuss the Urea cycle e.g. ATP used, where performed, where the two N in urea are from.
Explain what is meant by the terms keto- and glucogenic amino acids and provide examples.
Give examples of conditions where there are errors in the degradation of amino acids..

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 A question you have
probably never asked:

How do amino acids get
their amino?

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Nitrogen Metabolism
Consists of biosynthesis and breakdown of amino acids, purines, and pyrimidines
Metabolism of porphyrins is related to that of amino acids
Nitrification: Conversion of ammonia to nitrates
Denitrification: Process by which nitrates and nitrites are broken down to molecular
nitrogen

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 Nitrogen Fixation

Flow of Nitrogen in the Biosphere

Nitrogen is the most common gas in the
atmosphere - 78.09% (dry air)

Issue: N N bond is very stable: bond energy = 225 kcal/mol

Industrial: Haber-Bosch Process (CHEM105!)

N2 + 3 H2 2 NH3

at 500°C, 300 ATM, Fe catalyst

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Nitrogen Fixation

Flow of Nitrogen in the Biosphere

Nitrogen is the most common gas in the
atmosphere - 78.09% (dry air)

Issue: N N bond is very stable: bond energy = 225 kcal/mol

Biological: free-living soil bacteria
- symbiotic bacteria in root nodules of legumes
- cyanobacteria (i.e. blue-green algae)

N2 + 8 e- + 8 H+ + 16 ATP 2 NH3 + 16 ADP + 16 Pi + H2
at biological temps, 0.8 ATM
Redox Reaction

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 Nitrogen Fixation

Symbiotic bacteria inside root nodule cell
Nitrogen Fixation Root nodules

Catalyzed by the nitrogenase enzyme complex = 2 metalloproteins, “reductase” and “nitrogenase”:
N2 + 8 e- + 8 H+ + 16 ATP 2 NH3 + 16 ADP + 16 Pi + H2

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Nitrogen Fixation

Summary of the Nitrogenase Reaction

N2 + 8 e- + 8 H+ + 16 ATP 2 NH3 + 16 ADP + 16 Pi + H2

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 Nitrogen Fixation

Summary of the Nitrogenase Reaction
2

Dinitrogenase Reductase:
- contains Fe-S redox center,
3 6
oxidized/reduced by 1 e- transfers 1 4
-
1. receives e from Ferredoxin and
transfers the e- to nitrogenase
2. 2 ATP hydrolyzed/e- transferred
5
3. ATP-binding enhances reducing power
of the reductase (E’° -0.25 V  -0.4 V),
which is required for e- transfer
4. ATP-binding causes conformational
change that promotes binding of
reductase to nitrogenase
5. ATP hydrolysis triggers e- transfer to
nitrogenase and promotes dissociation

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6. Nitrogenase MoFe cofactor = site of N2 reduction Nitrogenase has an unusual
redox center, a “cofactor”
containing 1 Mo, 7 Fe, 9 S

N N
2H+ + 2e-
6
HN NH
+ -
2H + 2e

5 2HN NH2
+ -
2H + 2e

2 NH3
N2 believed to bind to Fe’s in central
cavity of MoFe cofactor. Formation
of multiple Fe-N interactions weakens
the N N bond and lowers activation N2 reduction on the MoFe cofactor
barrier for reduction occurs in 3 steps, & requires 6 e-

The remaining 2 e- are used to
reduce 2 H+ to H2
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 NH4+ assimilation: glutamine & glutamate = entry
points into metabolism
Glutamate is formed by reductive amination of -ketoglutarate and NH4+
Amidation of glutamate gives glutamine

Glutamate can also be formed by
reversal of the glutamate
dehydrogenase reaction (minor
pathway)

Involves transamination reactions and one-carbon transfers
Transamination: Transfer of amino groups from one molecule to another
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Glutamate & Glutamine as N-donors
Glutamate

α-amino group is the source
of the α-amino group in most
other amino acids

reactions catalyzed by
aminotransferases (pyridoxal
phosphate = cofactor)

NOTE: this reaction is
REVERSIBLE! Will come
back for AA catabolism

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 Amino Acid Biosynthesis

Transamination Reactions
Role of Pyridoxal Phosphate

Biologically active form of vitamin B6 is
pyridoxal phosphate (PyrP)
PyrP - Participates in the catalysis of a wide
variety of reactions of amino acids, including
transaminations and decarboxylations
Forms an imine (a Schiff base) with the -
amino group of an amino acid
Rearrangement gives an isomeric imine
Hydrolysis of the isomeric imine gives an -ketoacid
and pyridoxamine
All reactions are reversible

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Glutamate & Glutamine as N-donors

Glutamine donates its side-chain N (=amide N) in the biosynthesis of a wide range of
compounds
- reactions catalyzed by glutamine amidotransferases

Two domains:

1. Hydrolysis of Glutamine

NH3 passes through channel
so it won’t get “lost”

2. NH3 reacts with acceptor
substrate

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 Classes of reactions involved in  synthesis
1. Transamination reactions (w. glutamate)

2. Transfer of amino groups derived from amide N of glutamine

N5, N10 methylene THF
3. Transfer of 1 carbon groups using tetrahydrofolate as cofactor

N N N
5
N CH2 N CH2 N CH2
H l
10 l l l l
N- H3C N- H2C N-
H

From AA losing a Carbon group

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Allosteric Regulation of Glutamine Synthetase Activity
by Feedback Inhibition
Clearly, Glutamine and Glutamate are
important for N-donation
They need to be well controlled!
Negative feedback or feedback
inhibition
9 (!) inhibitors allosterically control
this enzyme:
Glycine, alanine, serine, histidine,
tryptophan, CTP, AMP, carbamoyl
phosphate and glucosamine-6-
phosphate

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 How are the 20 common
amino acids synthesized?

NH3：primarily donated by glutamate
Building
blocks
Carbon Skeletons：α-keto acid

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Families of Amino Acids Based on Pathways
Carbon skeletons come from intermediates in
Glycolysis: PEP, pyruvate, 3-phosphoglycerate
Pentose-P pathway: ribose-5-P, erythrose-4-P
Citric acid cycle: oxaloacetate, -ketoglutarate

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 Amino Acid Biosynthesis

Relationship between Amino Acid Metabolism and the
Citric Acid Cycle

The CAC is amphibolic:
Anabolic and catabolic

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Families of Amino Acids Based on Pathways
Carbon skeletons come from intermediates in
Glycolysis: PEP, pyruvate, 3-phosphoglycerate
Pentose-P pathway: ribose-5-P, erythrose-4-P
Citric acid cycle: oxaloacetate, -ketoglutarate

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 Amino Acid Biosynthesis

Biosynthesis of Serine
(and of Glycine from Serine in all
organisms)
Transamination reaction in which
glutamate is the nitrogen donor produces
3-phosphoserine and a -ketoglutarate
Hydrolysis of phosphate group gives rise to
serine
Glycine is produced from serine by the
transfer of a one-carbon unit to an acceptor

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Amino Acid Biosynthesis

Biosynthesis of Serine
(and of Glycine from Serine in all
organisms)
Glycine is produced from serine by the
transfer of a one-carbon unit to an carbon
acceptor - tetrahydrofolate

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 Amino Acid Biosynthesis

Conversion of Serine to Cysteine

Source of sulfur in plants and bacteria differ from that in animals
In plants and bacteria, serine is acetylated to form O-acetylserine
Reaction is catalyzed by serine acyltransferase, with acetyl-CoA as the acyl donor
Sulfur donor is 3′-phospho-5′-adenylyl sulfate

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Amino Acid Biosynthesis

Methionine

Cannot be produced in animals and must be obtained from
dietary sources
Essential amino acid as it cannot be synthesized by the body
Reacts with ATP to form S-adenosylmethionine (SAM) when
ingested
SAM has a highly reactive methyl group
This makes three single-carbon carriers we have now met. Can
you name them?

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 Amino Acid Biosynthesis

Biosynthesis of Cysteine in Animals
SAM is a methyl group carrier, and the methyl group can be transferred to a number
of acceptors, producing S-adenosylhomocysteine
Hydrolysis of S-adenosylhomocysteine produces homocysteine
Cysteine can be synthesized from serine and homocysteine, and this pathway for cysteine biosynthesis is the only
one available to animals

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Essential Amino Acids

Essential Amino Acids







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 Amino Acid Metabolism Learning Objectives
By the end of this topic you will understand :
 List the sources of amino acids for building proteins.
 Discuss nitrogen fixation
 The nitrogenase reaction
 Families of amino acids based on their biosynthetic pathways and the relationship between amino acids and the citric acid cycle
 Amino acid biosynthesis
 Describe what is meant by the term essential amino acids.
Describe the breakdown of dietary proteins
Discuss the process of protein turnover
Explain the process whereby an amino group is removed form an amino acid.
Discuss the degradation of AA in muscle during prolonged exercise and fasting.
Describe how amino acid degradation is linked to the TCA cycle.
Discuss the Urea cycle e.g. ATP used, where performed, where the two N in urea are from.
Explain what is meant by the terms keto- and glucogenic amino acids and provide examples.
Give examples of conditions where there are errors in the degradation of amino acids..

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Proteins are degraded into amino acids.
Dietary proteins are a vital source of amino
acids.

Discarded cellular proteins are another
source of amino acids.

First step in protein degradation is the
removal of the nitrogen

Ammonium ion is converted to urea in most
mammals.

Carbon atoms are converted to other major
metabolic intermediates.

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 Amino Acid Digestion

Protein Digestion and Absorption

In order to be absorbed
proteins must first be digested
to smaller peptides and amino
acids
Different digestive enzymes
target different motifs
Digestive enzymes begin as
zymogens to prevent
unwanted digestion

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Summary of Enzymatic Digestion and
Absorption

Secretion Enzyme Substrate Action Final
Product
Saliva Ptyalin Starch Hydrolysis
to form
dextrins
Gastric Pepsin Protein Hydrolysis
juice of peptide
bonds
Gastric Fats Hydrolysis
lipase into free
fatty acids

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 Summary of Enzymatic Digestion and
Absorption —cont’d

Secretion Enzyme Substrate Action Final
Product
Pancreatic Lipase Fat Hydrolysis to Fatty
exocrine mono- acids
secretion glycerides
Cholesterol Cholesterol Hydrolysis to Choles-
esterase esters of terol
cholesterol
and fatty
acids
α-Amylase Starch, Hydrolysis Dextrin,
dextrins maltose

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Summary of Enzymatic Digestion and
Absorption —cont’d

Secretion Enzyme Substrate Action Final
Product
Pancreatic Trypsin Protein Hydrolysis Polypeptides
exocrine
secretion
Chymotrypsin Protein Hydrolysis Polypeptides
Carboxy- Polypep- Hydrolysis Amino acids
peptidase tides
Ribonuclease Ribonu- Hydrolysis Mono-
cleic acids nucleotides
Elastase Fibrous Hydrolysis Amino acids
protein

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 Summary of Enzymatic Digestion and
Absorption —cont’d

Secretion Enzyme Substrate Action Final
Product
Brush border Carboxy- Polypep- Hydrolysis Amino
enzymes peptidase; tides acids
aminopep-
tidase;
dipeptidase
Entero- Trypsino- Activates to Polypep-
kinase gen trypsin tidases
and
peptides
Sucrase Sucrose Hydrolysis Glucose,
fructose
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Summary of Enzymatic Digestion and
Absorption —cont’d

Secretion Enzyme Substrate Action Final
Product
Brush Isomaltase Dextrin Hydrolysis Glucose
border
enzymes
Maltase Maltose Hydrolysis Glucose
Lactase Lactose Hydrolysis Glucose,
galactose
Nucleotidases Nucleic acid Hydrolysis Nucleotides
Nucleosidases Nucleosidases Hydrolysis Purine and
and pyrimidine
phosphorylase bases

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 Cellular Protein Degradation
Cellular proteins are degraded at different rates.

The protein ubiquitin is used to mark
cellular proteins for destruction.

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Ubiquitin
Ubiquitin is activated and attached to proteins using a group
of three enzymes
E1 - Ubiquitin activating enzyme
E2 - Ubiquitin-conjugating enyzme
E3 - Ubiquitin-protein ligase

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 Protein Turnover

Protein Turnover

There is no storage pool for protein

Braz J Med Biol Res. 2012 Sep; 45(10): 875–890.
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Removal of Nitrogen
The first step in amino acid catabolism is the removal of the
nitrogen.

The liver is the major site of protein degradation in mammals.

Deamination produces α-keto acids, which are degraded to other
metabolic intermediates.

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 Conversion to Ammonium Ions
α–Amino groups are converted to ammonium ions by the
oxidative deamination of glutamate

Reverse of this!

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Serine and Threonine
The β–hydroxy amino acids,
serine and threonine, can be
directly deaminated

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 Transporting Nitrogen to Liver
Urea is produced in the Liver
The alanine cycle is used to transport nitrogen to the liver

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Deamination
In most terrestrial vertebrates the ammonium ion is
converted to urea.

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 The Urea Cycle

The Urea Cycle

Excess nitrogen is metabolised and
secreted with three main endpoints
Occurs almost exclusively in the liver
and requires 4 ATP per molecule of
urea

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The Urea Cycle

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 Formation of Carbamoyl Phosphate
Carbamoyl synthetase
Free NH4 reacts with HCO3 to form carbamoyl phosophate.
Reaction is driven by the hydrolysis of two molecules of ATP

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Formation of Citrulline
Ornithine transcarbamoylase
Citrulline is formed from transfer of the carbamoyl group to the γ-amino
group of ornithine.

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 Formation of Arginosuccinate
Condensation of citrulline with aspartate to form arginosuccinate
Two equivalent of ATP are required.

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Formation of Arginine and Fumarate
Arginosuccinase
Cleaves arginosuccinate to form arginine and fumarate

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 Formation of Urea
Arginase
The arginine is hydrolyzed to produce the urea and to reform the ornithine.
The ornithine reenters the mitochondrial matrix.

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Linked to Citric Acid Cycle
The urea cycle is linked to the citric acid cycle:
Kreb’s Bi-cycle!!

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 Carbon Atoms
The carbon atoms of
degraded amino acids
emerge as major
metabolic intermediates.
Degradation of the 20
amino acids funnel into 7
metabolic intermediates

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Glucogenic and ketogenic amino acids

Glucogenic and ketogenic
Amino acids broken down into a range
of molecules such as pyruvate, acetyl-
CoA and acetoacetyl-CoA
Oxaloacetate is a key molecule
Mammals cannot synthesise glucose
from acetyl-CoA. Instead, they produce
ketone bodies instead.

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Amino Acid Metabolism Learning Objectives
By the end of this topic you will understand :
 List the sources of amino acids for building proteins.
 Discuss nitrogen fixation
 The nitrogenase reaction
 Families of amino acids based on their biosynthetic pathways and the relationship between amino acids and the citric acid cycle
 Amino acid biosynthesis
 Describe what is meant by the term essential amino acids.
 Describe the breakdown of dietary proteins
 Discuss the process of protein turnover
 Explain the process whereby an amino group is removed form an amino acid.
Discuss the degradation of AA in muscle during prolonged exercise and fasting. Will cover later
 Describe how amino acid degradation is linked to the TCA cycle.
 Discuss the Urea cycle e.g. ATP used, where performed, where the two N in urea are from.
 Explain what is meant by the terms keto- and glucogenic amino acids and provide examples.
 Give examples of conditions where there are errors in the degradation of amino acids..

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