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Catabolism of proteins

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Title: Catabolism of proteins


1
Chapter 9
  • Catabolism of proteins

2
Section 9.1
  • Nutritional function of proteins

3
Nutritional requirement of proteins
  • Nitrogen Balance
  • 1. nitrogen balance (normal adult)
  • intake N Losses N
  • from the diet losses in urine and
    feces
  • 2. Positive nitrogen balance (children,
    pregnant women, patients recovering)
  • intake N gt Losses N
  • 3. Negative nitrogen balance (starvation,
    malnutrition, patients with fever)
  • intake N lt Losses N

4
Protein requirement
  • After 8-10 days diets without proteins, the
    nitrogen excretion is 53mg/kg body weight per
    day. ( 20g proteins per day 60kg man.)
  • The World Health Organization recommend 0.75g/kg
    body wt day-1 proteins from food.
  • To Chinese diet 80g per day a 65kg man.
  • There is no storage of proteins in body, so
    proteins must be supplied every day.
  • Excess diet protein can be used as energy supply.

5
Nutritional quality of protein
  • Essential Amino Acids are amino acids that cannot
    be synthesized by the body and must be obtained
    from diet.
  • tryptophan phenylalanine
  • lysine threonine
  • valine leucine
  • isoleucine methionine
  • For infants and children
  • histidine arginine

6
  • Non-essential Amino Acids are amino acids that
    can be synthesized by body. Which including the
    other 12 amino acids .
  • Semi-essential Amino Acids can be synthesized in
    the body from essential amino acids.
  • tyrosine phenylalanine
  • cysteine methionine

7
Complementary Effect of Dietary Proteins
  • Quality of protein the essential amino acid
    composition.
  • high quality appropriate concentration of
    essential amino acids. (animal proteins)
  • plant proteins lack one or more of them.

8
  • Complementary effect of dietary proteins
  • two or more plant proteins supplied together
    will complement each other to a higher quality.

9
Complementary Effect of Dietary Proteins
Proteins origin amount of lysine amount of tryptophan
corn deficient rich
soybean rich deficient
together rich rich
10
  • Digestion, Absorption Putrefaction

11
Digestion of dietary proteins
  • In stomach pH of gastric juice lt 2
  • function kill microorganisms
  • denature protein
  • activate pepsinogen to
    pepsin.
  • Pepsin can
  • hydrolyze peptide bonds to form large fragments
    and some free AA.
  • coagulate milk (caseinogen casein)

12
In small intestine (main)
  • Proteolytic enzymes of pancreatic juice
  • endopeptidases cleave the internal peptide
    bonds.
  • trypsinase, chymotrypsin, elastase
  • exopeptidases remove AAs from N- or C-terminal
    ends.
  • carboxypeptidase A and B

13
In small intestine
  • Activation of zymogens from pancreas
  • enterokinase
  • trypsinogen trypsinase
  • chymotrypsinogen chymotrypsin
  • proelastase elastase
  • procarboxypeptidase carboxypeptidase

14
Products
  • Pancreatic proteolytic enzymes produce free amino
    acids and small peptides (2-8 AA residues.)
  • Aminopeptidase hydrolyzes amino-terminal AA from
    oligopeptide.
  • Dipeptidase hydrolyzes dipeptide.
  • The results of protein digestion
  • free AAs, dipeptides, tripeptides.

15
Carboxypeptidase
Aminopeptidase
endopeptidases
Dipeptidase
Digestion of protein
16
Absorption and transportation of AA
Location intestine
free amino acids,dipeptides,tripeptides
  • by transport systems
  • seven transport systems

17
Absorption and transportation of AA
  • The AA is absorbed with Na, which has to be
    pumped out of the cell by a sodium pump. It is an
    ATP-requiring process.
  • The absorbed dipeptides and tripeptides are
    hydrolyzed to free AAs before they be transport
    into portal vein.

18
Putrefaction
  • The undigested proteins and no absorbed AAs pass
    into the large intestine, where the decomposition
    of which by bacteria is called putrefaction.
  • Products
  • benefits vitamin K, B12, folic acid,
  • toxicoids amines, phenol, indole, H2S,

19
  • Decarboxylation of AAs produces amines
  • histidine histamine
  • tyrosine tyramine
  • lysine cadaverine
  • Tyramine can raise blood pressure, histamine and
    cadaverine can decrease blood pressure
  • Production of Phenol
  • tyrosine phenol

20
  • Production of indole (odor of feces)
  • tryptophan indole
  • Production of H2S
  • cysteine hydrogen sulfide
  • Production of ammonia
  • unabsorbed AA
  • urea (from blood)

NH3
21
  • The toxic products of putrefaction are removed by
    liver.
  • In liver disease, which may cause the hepatic
    coma.

22
Section 9.3
  • Degradation of Protein in Cells

23
  • Protein turnover
  • the degradation and synthesis of protein.
  • 1-2 of total body proteins turnover each day.

24
  • Half time (t1/2 ) the time required to reduce
    the proteins concentration to 50 of its initial
    value.
  • HMG CoA reductase 0.5-1 hours
  • plasma proteins 10 days
  • collagen and histone several months

25
There are two pathway to degrade protein in cells.
  • Lysosomal pathway
  • -extracellular membrane-associated long-lived
    proteins
  • -ATP independent process
  • -degraded by cathepsin (pH 5.0)

26
There are two pathway to degrade protein in cells.
  • Cytosol pathway
  • -abnormal, damaged, short-lived proteins
  • -require ATP and ubiquitin
  • -degraded by proteosome (pH 7.8)

27
  • Ubiquitin
  • -76 amino acid residues
  • -presents in all eukaryotic cells
  • -the primary structure is highly conserved,
  • The process of ubiquitin pathway
  • -ubiquitination chains of 4 or more ubiquitin
    combine to the protein
  • -degradation of ubiqitinated protein

28
ubiquitination
Ub
Ub
Ub
Ub
Ub
Ub
E1ubiquitin activating enzyme, E2
ubiquitin-conjugating enzyme, E3
ubiquitin-protein ligase
29
Degradation
Ubn-CO-NH-protein
proteosome
Amino acids
30
Section 9.4
  • Amino Acid Catabolism General

31
  • Amino acid metabolic pool
  • the amino acids coming from digestion and
    absorption of dietary proteins or from
    degradation of body proteins will be used equally
    in the body.

32
utilization
Source
Body protein
synthesis
Amino acid metabolic pool
Degradation
33
Deamination of AAs
  • Term removal of the amino groups of AAs
  • Including
  • -Oxidative deamination
  • -Non-oxidative deamination
  • -Transamination
  • -Coupling the transamination with
  • deamination of glutamate
  • -Purine nucleotide cycle

34
1. Oxidative deamination
  • L-amino acid oxidase
  • -in the liver and kidney,
  • -the activity is low ( unimportant)
  • D- amino acid oxidase
  • -in liver, kidney and other tissues
  • -important for glycin and D- amino acid

L-amino acid oxidase
L-amino acid
a-imino acid
a-Keto acid NH3
2H
35
1. Oxidative deamination
  • L-glutamate Dehydrogenase
  • -wide distribution, high activity (except muscle)
  • -the major enzyme in the metabolism of AAs
  • -inhibitors GTP, ATP activators GDP, ADP

NAD(P)HH
NAD(P)
NH3
H2O
L-glutamate Dehydrogenase
a-ketoglutarate
L-glutamate
a- aminoglutarate
36
2.Non-oxidative deamination
  • Serine and threonine
  • -the a-amino group of which can be removed
    nonoxidatively
  • -special dehydratases
  • Cysteine
  • -cysteine desulfhydrase

37
3.Transamination
  • The transfer of a-amino group from a a-amino acid
    to a a-keto acid, then the a-amino acid forms a
    corresponding a-keto acid, the a-keto acid forms
    a corresponding a-amino acid. (except Lys, Thr
    and Pro )

38
Transami-nase
a-amino acid 1
a-keto acid 1
a-amino acid 2
a-keto acid 2
39
3.Transamination
  • The ?-amino group of most amino acids is
    transferred to ?-ketoglutarate to form glutamate
  • ? -NH2 is only transferred from one of amino
    acids to a ? - keto acid, not really removed.
  • Aminotransferases (transaminases)
  • -Different transaminating reactions are
    catalyzed by different transaminases

40
  • Alanine transaminase (ALT, or GPT) and Aspartate
    transaminase (AST, or GOT)

Alanine ?-ketoglutarate
pyruvate Glutamate
ALT
Aspartate ?-ketoglutarate
Oxaloacetate Glutamate
AST
41
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42
  • The serum levels of GOT, GPT are very low
    normally.
  • Measure the serum level of special transaminase
    has diagnostic significance.
  • Increase of GPT liver damage (hepatitis)
  • Increase of GOT heart damage (myocardial
    infarction)

43
Mechanism of transamination
  • The cofactor of transaminase is pyridoxal
    phosphate

44
1
Amino acid
Pyridoxal phosphate
a-ketoacid
Aldimeine (Schiff base )
1
1
Ketimine (Schiff base )
pyridoxamine phosphate
45
Transaminase
Pyridoxal phosphate
pyridoxamine phosphate
?-keto acid
?-amino acid
46
4.Coupling the transamination with deamination of
glutamate
  • The ?-amino group of most amino acids is
    transferred to ?-ketoglutarate to form glutamate
    by transamination.
  • Then glutamate deaminated to ammonia and
    ?-ketoglutarate by glutamate dehydrogenase.
  • Which is called coupling deamination.

47
coupling deamination.
?-ketoglutarate
?- amino acid
transaminase
?-keto acid
glutamate
H2ONAD
48
5.Purine Nucleotide Cycle
  • The activity of L-glutamate dehydrogenase is low
    in the skeletal muscle and heart, where the major
    deamination process is purine nucleotide cycle.

49
?-keto-glutarate
a-amino acid
Adenylo-succinate
3 Adenylosuccinate synthetase
1 Transaminase
4 AMP deaminase
2 Aspartate transaminase(AST)
50
Metabolism of Ammonia
  • Source of ammonia in blood
  • --Endogenous source
  • deamination of amino acids (major)
  • catabolism of other nitrogen compounds
  • --Exogenous source (4g/day)
  • production of putrefaction
  • degradation of urea in large intestine by
  • bacteria

51
Transport of ammonia in blood
  • Only traces of ammonia (NH3) exist in blood.
  • NH3 is toxic to the central nervous system. So it
    must be transport in nontoxic type.
  • transport as glutamine
  • Alanine-glucose cycle

52
1.Fixes ammonia as glutamine
  • catalyzed by glutamine synthetase.
  • glutamine is the temporary non-toxic storage and
    transport form of NH3
  • Synthesized in brain and muscle,
  • degraded in kidney and liver

53
NH3ATP
ADPPi
Glutamine synthetase
glutaminase
NH3
H2O
54
2.Alanine-glucose cycle
Muscle
Blood
Liver
protein
urea
glucose
glucose
glucose
Amino acid
NH3
NH3
Glutamate
pyruvate
pyruvate
a-ketoglutarate
Glutamate
Alanine
Alanine
a-keto- glutarate
Alanine
55
Formation of Urea
  • Urea is the major product of nitrogen.
  • Synthesized in liver, excreted by kidney.
  • The process is called urea cycle or ornithine
    cycle found by Hans Krebs.
  • To 1mol urea
  • 1mol ammonia
  • 1mol a-amino nitrogen from aspartate
  • 1mol CO2
  • 3mol ATP

56
Process of urea cycle
  • 1. synthesis of carbamoyl phosphate (in
    mitochondria)

Carbamoyl phosphate synthetase?(CPS?) (N-acetylglu
tamate,Mg2)
57
Process of urea cycle
2. Formation of citrulline (in mitochondria)
Ornithine carbamoyl- transferase (OCT)

H3PO4
Carbamoyl phosphate
Ornithine
Citrulline
58
Process of urea cycle
3. Synthesis of Arginine (in cytosol)
NH
COOH
2
C
C
argininosuccinate synthesase (ASS)
N
H
CH
NH
2

COOH
(CH
)
Mg2
2
3
ATP
H2O
AMPPPi
CH
NH
2
COOH
Aspartate
Citrulline
argininosuccinate
59
Process of urea cycle
3. Synthesis of Arginine


Argininosuccin-ate lyase (AST)
??????????
Fumarate
Arginine
argininosuccinate
60
Reutilization of aspartate
citrulline
Aspartate
Amino acid
a-ketoglutarate
argininosuccinate
glutamate
oxaloacetate
Arginine
a-ketoacid
Fumarate
Malate
61
Process of urea cycle
4. Hydrolysis of arginine to release urea


Arginase
Urea
ornithine
Arginine
62
Formation fo NO
Nitric oxide synthase (NOS)
NO
O2
NADPHH NADP
Arginine
Citrulline
Nitric oxide is the muscle relaxant and gas
signal molecule.
63
Summary of Ornithine cycle

P
NH3
64
  • Urea synthesized will be excreted by kidney, some
    of the urea will enter the intestine and are
    degraded to ammonia by bacteria.
  • To the two nitrogen atoms of urea, one come from
    ammonia, which come from the degradation of amino
    acid,
  • the other one come from Aspartate, which can
    get the amino group again from other amino acid.
    So two nitrogen all come from amino acid.

65
Regulation in urea biosynthesis
  • Dietary nitrogen intake
  • high protein diet synthesis
  • starvation synthesis
  • CPS-? activated by
  • N-acetylglutamic acid
  • (AGA) and arginine

N-acetylglutamate
66
Enzymes in urea cycle
  • Key enzyme Argininosuccinate synthetase

67
Hyperammonemia
  • High level of ammonia in the blood.
  • Reasons
  • -inborn errors of enzymes in urea cycle,
  • - liver failure
  • Damage (ammonia poisoning)
  • coma and irreversible brain damage

68
Mechanism of the brain damage
NH3
NH3
a-ketoglutarate
Glutamate
glutamine
Quantity of a-ketoglutarate in brain?
TAC ?
ATP deficiency
69
Other metabolic pathway of ammonia
  • Excretion in urine as NH4 (in kidney)

Glutami-nase

NH3
NH4 is excreted in the urine, which can maintain
the acid-base balance of the body.
70
Other metabolic pathway of ammonia
  • Synthesis of amino acids
  • non-essential amino acids
  • Biosynthesis of Pyrimidine

Carbamoyl phosphate synthetase? (CPS?)
Pyrimidine
71
Metabolism of the Carbon Skeleton of Amino acids
AAs
glucose FA and ketone bodies TCA
Carbon skeletons
Amino acid
CO2 , H2O and ATP
72
Metabolism of the Carbon Skeleton of Amino acids
  • Ketogenic amino acids can be degraded to acetyl
    CoA or acetoacetyl CoA , which are precursor of
    producing ketone bodies.
  • Leu, Lys
  • Glucogenic amino acids can be degraded to the
    carbon skeletons which can be converted into
    glucose.
  • Ketogenic and glucogenic amino acids
  • Ile, Phe, Trp, Tyr, Thr

73
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74
Amino Acid Catabolism Individual
  • Decarboxylation of Amino Acid

Physiological effects
75
  • ?-Aminobutyric Acid (GABA)
  • GABA is inhibitory neurotransmitter.

L-glutamate decarboxylase
76
  • Histamine
  • vasodilation
  • stimulate the secretion of pepsin and
    hydrochloric acid

Bronchial asthma, allergic reaction
Histidine decarboxylase
77
  • 5-Hydroxytryptamine (5-HT)
  • inhibitory neurotransmitter in brain
  • cause contraction of smooth muscle of
    arterioles and bronchioles

Tryptophan
5-Hydroxytryptamine
78
  • Polyamine important to cell proliferation and
    tissue growth.

Ornithine decarboxylase
Ornithine
Putrescine
CO2
S-adenosylmethionine (SAM )
Decarboxylased SAM
Methythio-adenosine
CO2
spermine
spermidine
79
Metabolism of One Carbon Units
  • One Carbon Units One carbon containing groups
    produced in catabolism of some amino acids.

-CH3
methyl
methylene
-CH2-
methenyl
-CH
formyl
-CHO
formimino
-CHNH
80
Carrier of one carbon unit tetrahydrofolate (FH4)
81
N5, N10 nitrogen atoms involved in the transfer
of one carbon units.
N5Methyl FH4
N5?N10Methylene FH4
N5?N10-MethenylFH4
N10FormylFH4
N5FormiminoFH4
82
Production of one carbon unit
83
Conversion of one carbon units
N10CHOFH4
H
H2O
NH3
N5, N10CHFH4
N5CHNHFH4
NADPHH
NADP
N5, N10CH2FH4
NADHH
NAD
N5CH3FH4
84
Function of one carbon units
As donors of one carbon units in purine and
pyrimidine synthesis.
85
Metabolism of Methionine, Cysteine and Cystine
86
SAM
Macrocytic anemia
Homocysteine methyltransferase (Vitamine B12)
Methionine cycle
87
Creatine and creatine phosphate
Storage of high energy phosphate of ATP
88
Cysteine and Cystine
  • Conversion of cysteine to cystine

Cysteine
Cystine
89
  • Systhesis of Taurine

1.Form conjugant with bile acid. 2.Involved in
brain development
90
Formation of PAPS
Sulfate is produced mostly from cysteine.
AMP - SO3-
(adenosine -5-phosphosulfate)
3-PO3H2-AMP-SO3-
(3-phosphoadenosine-5-phosphosulfate,PAPS)
PAPS is the active sulfate group for biosynthesis.
91
Glutathione (GSH)
?-glutamylcysteinylglycine
  • transport amino acids across membranes.
  • Protect erythrocytes from oxidative damage.

92
?-glutamyl cycle
Cell membrane
93
Metabolism of aromatic amino acids
aromatic amino acids
phenylalanine
Tyrosine
Tryptophan
94
Phenylalanine and Tyrosine
The main catabolism pathway of phenylalanine is
hydroxylated to tyrosine first.
Phenylalanine hydroxylase
O2
H2O
phenylalanine
Tyrosine
95
Phenylketonuria (PKU)
  • Normally, small amount of phenylalanine can be
    transaminated to form phenylpyruvate.
  • If phenylalanine hydroxylase is genetic
    deficiency, transamination become the main
    catabolism pathway, which results in high level
    of phenylpyruvate and phenyllacetate in the
    urine, called PUK

96
transamination
p
phenyllacetate
phenylalanine
phenylpyruvate
97
Metabolism of tyrosine
  • Production of Dopamine, Epinephrine and
    Norepinephrine.

98
Parkinsons disease
character
slowing of emotional and voluntary movement,
muscular rigidity, postural abnormality and
tremor
Reasons
  • deficiency of Dopamine

99
Metabolism of tyrosine
  • Synthesis of Melanin
  • Tyrosine Dopa
    Melanin
  • Genetic lack of tyrosinase will cause Albinism.
  • --lack of pigment in the skin and eyes.
  • --sensitive to sunlight
  • --photophobia

tyrosinase
100
  • Production of thyroid Hormone
  • thyroxine (T4) and triiodothyronine (T3)

101
Metabolism of tryptophan
One carbon units
tryptophan
pyruvate acetoacetyl CoA
Melatonin
102
Degradation of branched-chain amino acid
branched-chain amino acid
isoleucine
valine
leucine
103
Succinyl CoA
Succinyl CoA

Acetyl CoA
Acetyl CoA

Acetoacetate
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