Download Arginine metabolism in human infants

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
page
23
page
24
page
25
page
26
page
27
page
28
page
29
page
30
page
31
page
32
page
33
page
34
page
35
page
36
page
37
page
38
Document related concepts

Evolution of metal ions in biological systems wikipedia , lookup

Genetic code wikipedia , lookup

Fatty acid synthesis wikipedia , lookup

Citric acid cycle wikipedia , lookup

Metabolism wikipedia , lookup

Proteolysis wikipedia , lookup

Clinical neurochemistry wikipedia , lookup

Biochemistry wikipedia , lookup

Peptide synthesis wikipedia , lookup

Oligonucleotide synthesis wikipedia , lookup

De novo protein synthesis theory of memory formation wikipedia , lookup

Artificial gene synthesis wikipedia , lookup

Biosynthesis wikipedia , lookup

Amino acid synthesis wikipedia , lookup

Transcript 
Arginine metabolism in
human infants
Christopher Tomlinson
Supervisors Dr. Paul Pencharz, Dr Ron Ball
Background
• Arginine is a cationic
amino acid
Metabolic functions of arginine
1. Protein synthesis
2. Amidino group for creatine synthesis
3. Polyamine synthesis via ornithine and
agmatine
4. Synthesis of nitric oxide
5. Urea Synthesis
6. Activates N-acetyl glutamate synthase
7. Post-transational modification of proteins
through methylation and citrullination
Background
Protein
ADMA
Agmatine
SDMA
Argininosuccinate
arginine
decarboxylase
ASL
Arginine
Citrulline
NOS
arginine : glycine
amidinotransferase
Excretion
in urine
ASS
NO
Glycine
arginase
Guanidinoacetate
Carbamoyl
Phosphate
Urea
Glutamine
OTC
Ornithine
Creatine
Glutamate
P5C
dehydrogenase
OAT
ODC
Putrescine
Spermidine
Spermine,
Cadaverine
Pyrroline
5-carboxylate
P5C
reductase
Proline
proline
oxidase
non-enzymic
reaction.
Glutamylsemialdehyde
P5C synthetase
Arginine Requirements
• Conditionally essential amino acid
• Arginine deficient diet in humans
– Healthy adults
• no ill effects (Beamier et al 1996)
• arg, pro, gln, asp free diet - no ill effects (Castillo 2008)
• azospermia (Holt 1944)
– Arginine deficient TPN leads to hyperammonemia
– Essential during critical illness
Carcillo 2003, Zello 2003, Morris 2004
Arginine Requirements
• Arginine deficient diet
– Rats
• Poor growth, fatty liver, orotic aciduria,
hyperammonemia
Milner et al 1974
– Piglets
• Hyperammonemia and death
Brunton 1999, Prior 1995
– Obligate carnivores
• Hyperammonemia and death
Morris 1978
Arginine Requirements
• Healthy human neonates
– Essential / non-essential?
– 3 infants fed arginine free diet
• No apparent ill effects
Snyderman 1959
• Neonates in ICU
– Essential
• TPN deficient in arginine leads to hyperammonemia
Heird 1972, Batshaw 1984
• Arginine low in infants in ICU
Arginine post cardiac surgery
120
100
80
60
40
20
0
Pre op
post op 1
post op 2
Arginine Requirements
• Neonates in ICU
– Persistent pulmonary hypertension
• Hypoargininemia, ? Reduced NO production
• Treatment with arginine improved oxygenation
– Necrotising enterocolitis
• Development of NEC related to low arginine
• Arginine supplementation reduced incidence?
Arginine Synthesis
Argininosuccinate
ASL
ASS
Arginine
Citrulline
Carbamoyl
Phosphate
Glutamine
OTC
Ornithine
Glutamate
P5C
dehydrogenase
OAT
Pyrroline
5-carboxylate
P5C
reductase
Proline
non-enzymic
reaction.
proline
oxidase
Glutamylsemialdehyde
P5C synthetase
Arginine Synthesis
• Adult mammals
– Intestinal – renal axis
• Citrulline synthesised in enterocyte from glutamate
• Citrulline not taken up by liver but by kidney
• Converted to arginine
Arginine Synthesis
• Neonatal mammals
– Kidney low levels of ASS and ASL
– Enterocyte has high levels of ASS and ASL,
low arginase
– Hence, arginine synthesis takes place in
enterocyte
– Precursor proline or glutamate?
Arginine Synthesis
• Neonatal piglet model
– In vitro studies
• Glutamate is significant and main precursor of
arginine synthesis
Wu 1995, Wu 2000
Arginine Synthesis
• Neonatal piglet model
– In vivo studies of arginine metabolism
• Arginine deficiency ameleriorated by enteral
proline and dependant on enteral function
Brunton1999, Bertolo 2003
• Arginine not synthesised from glutamate enteral or
parenteral
Brunton1999, Wilkinson 2004
Arginine Synthesis
• Neonatal piglet model
– Arginine synthesis upregulated but not able to
completely synthesise sufficient arginine
Wilkinson 2004
– Proline deficient diet
• Arginine converted to proline
• No conversion of glutamate to proline
Murphy 1996
– Proline ~60% of arg synthesis
Urschel 2007
Components of arginine
requirements in human infants
Neonatal Pigs
(7 days)
Arginine use
Protein synthesis
Arginine catabolism
(arginase and NO
synthase)
Creatine synthesis
Total Arginine use
Arginine intake
Arginine synthesis
All units mg/kg/day
750
260
70
1080
400
680
Components of arginine
requirements in human infants
Neonatal Pigs
(7 days)
Arginine use
Protein synthesis
Arginine catabolism
(arginase and NO
synthase)
Creatine synthesis
Total Arginine use
Arginine intake
Arginine synthesis
All units mg/kg/day
Neonatal
Humans
750
260
140
50
70
16
1080
400
680
206
45
160
Research Rationale
• Few studies on arginine metabolism in
human neonates
• Lack of understanding of arginine
physiology and role in pathophysiology
• High rate of arginine synthesis is implied
• What is the actual rate of arginine
synthesis?
• Where does it occur?
• What is/are the precursors?
Research objectives
1. To determine if human neonates can
synthesise arginine and what the
precursors are.
2. To determine arginine flux and rate of
synthesise in healthy newborns
3. To determine if the premature infant has a
greater dietary requirement for arginine.
Stable isotope study design
– Multi tracer experiment
• (2-15N-amidino) Arginine
• (1-15N) Proline
• (2,4,4-2H3) Glutamate
Stable isotope study design
Argininosuccinate
ASL
ASS
M+1 Arginine M+3
M+1OrnithineM+3
M+1 CitrullineM+3
Carbamoyl
Phosphate
Glutamine
OTC
Glutamate
P5C
dehydrogenase
OAT
Pyrroline
5-carboxylate
P5C
reductase
M+1
Proline
non-enzymic
reaction.
proline
oxidase
Glutamylsemialdehyde
P5C synthetase
M+3
Methods
• Labelled amino acids fed via NG tube 2 or
3 hourly before feeds
• Urine collected at baseline and with diaper
changes throughout study
Urine collection
Time 0
12 hours
Labelled amino acids pre feed
Subjects
•
•
•
•
•
12 preterm infants studied
Fully enterally fed, no resp support
Gestational age at birth 33+1 weeks
Birthweight 1.82 Kg
Age at study 13 days
Arginine Flux
• Average 90 mg/kg/hr
• Range 55-150 mg/kg/hr
• No correlation with gestational age at birth,
age at study
– Significantly higher than IV flux rate
Castillo 1995
Proline Flux
• Average • Range -
26 mg/kg/hr
19.5-47 mg/kg/hr
Glutamate flux
• No enrichment seen
– In keeping with literature
– All glutamate metabolised on first pass by
splanchnic organs
Arg synthesis from Pro/Glu
Argininosuccinate
ASL
ASS
M+1 Arginine M+3
M+1OrnithineM+3
M+1 CitrullineM+3
Carbamoyl
Phosphate
Glutamine
OTC
Glutamate
P5C
dehydrogenase
OAT
Pyrroline
5-carboxylate
P5C
reductase
M+1
Proline
non-enzymic
reaction.
proline
oxidase
Glutamylsemialdehyde
P5C synthetase
M+3
Pro/Glu conversion to Orn
• No M+3 Orn seen
• M+1 Orn seen in all infants
– Mean 2.9%
– Range 1.4 – 5.6 %
Pro/Glu conversion to Cit
• No M+3 Cit seen
• M+1 Cit seen in all infants
– Mean 2.9%
– Range 0.1 – 5.6 %
Pro/Glu conversion to Arg
• No M+3 Arg seen
• M+1 Arg seen in all infants
– Mean 0.9%
– Range 0.2 – 2.7 %
Arginine Synthesis
Argininosuccinate
ASL
ASS
0.9% Arginine
Citrulline
2.9%
Carbamoyl
Phosphate
2.9% Ornithine
Glutamine
OTC
Glutamate
P5C
dehydrogenase
OAT
Pyrroline
5-carboxylate
P5C
reductase
8% Proline
non-enzymic
reaction.
proline
oxidase
Glutamylsemialdehyde
P5C synthetase
Arg rate of synthesis
• Calculated from arginine and proline
enrichments
• ~7 mg/kg/hr = 168 mg/kg/day
NO Production
Argininosuccinate
ASL
ASS
M+2 Arginine
Citrulline
M+1
Carbamoyl
Phosphate
Glutamine
OTC
Ornithine
Glutamate
P5C
dehydrogenase
OAT
Pyrroline
5-carboxylate
P5C
reductase
Proline
non-enzymic
reaction.
proline
oxidase
Glutamylsemialdehyde
P5C synthetase
NO Production
Argininosuccinate
ASL
ASS
3.98% Arginine
Citrulline
2.5%
Carbamoyl
Phosphate
Glutamine
OTC
Ornithine
Glutamate
P5C
dehydrogenase
OAT
Pyrroline
5-carboxylate
P5C
reductase
Proline
non-enzymic
reaction.
proline
oxidase
Glutamylsemialdehyde
P5C synthetase
Conclusions
• Arginine is a conditionally essential amino
acid in human neonates.
• Healthy growing preterm infants are able
to synthesise arginine.
• The dietary precursor is proline.
• Glutamate entirely metabolised by
splanchnic organs.
Future studies
• TPN results in gut mucosal atrophy
• Repeat studies at HSC in infants as they
transition to oral feeding
– Comparison with data from study 1
Future studies
• All neonatal evidence shows proline is
only dietary precursor for arginine
– Study in adults using same protocol to
determine the dietary precursor for arginine
• Currently available evidence is from studies in
fasted, intraoperative patients
Thank You
• Supervisors
– Paul Pencharz
– Ron Ball
• Committee
– Keith Tanswell
– Harvey Anderson
• Pencharz lab
–
–
–
–
Mahroukh Rafii
Glenda Coutrney-Martin
Raja Elango
Karen Chapman
• Staff at St Mikes NICU
– Mike Sgro
• CIHR
Related documents
AAKG supplement
AAKG supplement
22 Reasons to Try ProArgi
22 Reasons to Try ProArgi
Venicon works to stimulate and potentially increase an erection!
Venicon works to stimulate and potentially increase an erection!
N H CCl3 C O N CCl3 C Cl (ii) SOCl2 7.55 g 7.78 g CCl C N NH N H
N H CCl3 C O N CCl3 C Cl (ii) SOCl2 7.55 g 7.78 g CCl C N NH N H
RESEARCH NOTES Davis, R.H.
RESEARCH NOTES Davis, R.H.
ARGININE DECARBOXYLASE TEST
ARGININE DECARBOXYLASE TEST
Accepted version - Queen Mary University of London
Accepted version - Queen Mary University of London
L-Canavanine (Sigma Aldrich C1625) Synonyms: Canavalia
L-Canavanine (Sigma Aldrich C1625) Synonyms: Canavalia
Protein Sequence WKS - Kenton County Schools
Protein Sequence WKS - Kenton County Schools
The Summary of International Veterinary Journal
The Summary of International Veterinary Journal
Quiz solutions key
Quiz solutions key
CLINICAL CASE (UREA CYCLE)
CLINICAL CASE (UREA CYCLE)