Amino Acids: Nitrogen Disposal PDF

Summary

This document describes the disposal of nitrogen from amino acids. It covers the processes of transamination, oxidative deamination, and the transport of ammonia. This study guide is suitable for undergraduate biology students and those studying biochemistry.

Full Transcript

Amino acids: Disposal of
Nitrogen
(page 605 in the book)

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 Learning objectives
Learn how the body/the cell deals with
amino acids.
Learn new terms such as: amino acid
pool, transamination and oxidative
deamination.
Learn about ammonia exchange process
between different tissues.

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* Introduction:
Amino acids are not stored by the body.
Therefore, amino acids are obtained from
the diet, synthesized de novo, or produced
from normal protein degradation. Any
amino acids in excess of the biosynthetic
needs of the cell are rapidly degraded.

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 Amino acid Pool
Free amino acids are present throughout the body
and they belong to a single entity, called the amino
acid pool.
The amino acid pool is supplied by three sources:
1) amino acids provided by the degradation of body
proteins, 2) amino acids derived from dietary protein,
and 3) synthesis of nonessential amino acids from
simple intermediates of metabolism.
The amino acid pool is utilized by three routes: 1)
synthesis of body protein, 2) amino acids consumed
as precursors of essential nitrogen-containing small
molecules, and 3) conversion of amino acids to
glucose, glycogen, fatty acids or CO2.
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Protein Turnover

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Protein Turnover

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 Digestion of Dietary Proteins
Amino acid catabolism is part of the larger
process of the metabolism of
nitrogen-containing molecules. Nitrogen
enters the body in a variety of compounds
present in food, the most important being
amino acids contained in dietary protein.
Nitrogen leaves the body as urea,
ammonia, and other products derived from
amino acid metabolism.
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 Digestion of
Dietary Proteins

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 Mechanism of Action for
Digestive Proteases

→ Role of Enteropeptidase ?
→ Free amino acids are taken into the enterocytes up by a Na+-linked
secondary transport system. Di- and tripeptides are taken
up by a H+-linked transport system. Amino acids are either metabolized
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by the liver or released into the general circulation.
 Amino acid Catabolism:
Removal of Nitrogen
A) Transamination:
The first step in the catabolism of most amino
acids is the transfer of their α-amino group to
α-ketoglutarate. The products are an
α-ketoacid and glutamate (Slide 11).
This transfer of amino groups from one carbon
skeleton to another is catalyzed by a family of
enzymes called aminotransferases (formerly
called transaminases). These enzymes are
found in the cytosol and mitochondria of cells
throughout the body (Slide 12).
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* All amino acids, with
the exception of
Lysine, threonine and
proline,
participate in
transamination
at some point in their
catabolism.

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* Allaminotransferases
require the coenzyme
pyridoxal phosphate which
is a derivative of vitamin B6.

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B) Oxidative deamination of amino acids:

These reactions occur primarily in the liver
and kidney. They provide α-keto acids that
can enter the central pathway of energy
metabolism, and ammonia, which is a
source of nitrogen in urea synthesis.

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* Glutamate dehydrogenase is unusual in that it can use either NAD+ or NADP+
as a coenzyme. NAD+ is used primarily in oxidative deamination and NADPH
is used in reductive amination.
* Guanosine triphosphate (GTP) is an allosteric inhibitor of glutamate
dehydrogenase, whereas adenosine diphosphate (ADP) is an allosteric activator.15
Amino Acids Catabolism

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C) Transport of Ammonia to the Liver:

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 Summary
PPP is essential for producing NADPH &
ribose 5-ph.
Proteins are digested mainly in the
S.intestine by specialised enzymes.
Amino group of free amino acids are
removed by transamination and oxidative
deamination. To deliver ammonia to the
lever for processing; most tissues send
glutamine and the muscles send alanine.
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