Digestion, absorption and transport of CHO - Copy.pdf

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Digestion, absorption & transport of CHO
By the end of this lecture you must be able to
- explain digestion of CHO starting from the
buccal cavity & ending up in the small intestine
- Describe the transport of monosaccharides
(products of digestion) from the intestinal
lumen to the blood stream
- Describe the transport of glucose, fructose &
galactose from blood into different tissues
 Metabolism=
catabolism and
anabolism
Catabolic =
degradative
Anabolic =
synthetic
 The three stages of catabolism

Stage I

Stage II

Stage III

Stage I: Hydrolysis of their complex molecules to their
component building blocks
Stage II: Conversion of building blocks to Acetyl CoA
Stage III: Oxidation of Acetyl CoA (Oxidative phos.)
 Metabolism of carbohydrates
Digestion:
Starts in the oral cavity.
Saliva contains α – amylase that hydrolyses
starch giving maltose + oligosaccharides (short
chains of sugars formed of 3-10 glucose
molecules).
Salivary amylase is inactivated at pH 4.0.
 Digestion of carbohydrates continues in
the small intestine by:
Pancreatic amylase: (finally gives maltose +
some glucose + isomaltose, 2 glucose
molecules attached by 1 – 6 linkage).
Intestinal disaccharidases: include:
Maltase
Sucrase
Lactase
isomaltase.Lactose intolerance:
Develops due to deficiency of lactase enzyme
and causes osmotic diarrhea. Over 70% of
adults suffer lactose intolerance world wide.
The mechanism by which loss of lactase by
age is not known
 Final products of carbohydrates digestion are:
Glucose (main)
Fructose, galactose, pentoses..etc.
 Carbohydrates are absorbed as
monosaccharides by:
Active transport (against concentration gradient)
Facilitative transport (diffusion)
Glucose and galactose fulfil the necessary
configuration for active transport:
- OH on carbon 2
- A pyranose ring
- A methyl group at C5
Fructose is absorbed slowly by active transport.
Active absorption of glucose is powered by
the sodium pump
This system acts in the small intestine as well
as in the kidney tubules.
Phlorhizin is an inhibitor of sodium pump and
hence of glucose reabsorption in the kidney.
 Glucose transporters
GLUT1: ubiquitously distributed; exhibits
constitutive transport activity (responsible for the
low-level of basal glucose uptake required to
sustain respiration in all cells.)
GLUT2: present in gut, liver, and pancreatic islets
GLUT3: present in the central nervous system and
brain
GLUT4: present in insulin-responsive tissues,
skeletal muscle, adipose tissue, and heart
 GLUT 1
Is widely distributed in fetal tissues. In the
adult, it is expressed at highest levels in
erythrocytes and also in the endothelial cells
of barrier tissues such as the blood brain
barriers. However, it is responsible for the low-
level of basal glucose uptake required to
sustain respiration in all cells.
 GLUT 2
Is a bidirectional transporter, allowing glucose
to flow in 2 directions. Is expressed by renal
tubular cells, small intestinal epithelial cells,
liver cells and pancreatic beta cells.
 Bidirectionality is required in liver cells to
uptake glucose for glycolysis, and release of
glucose during gluconeogenesis. In pancreatic
beta cells, free flowing glucose is required so
that the intracellular environment of these
cells can accurately gauge the serum glucose
levels. All three monosaccharides (glucose,
galactose and fructose) are transported from
the intestinal mucosal cell into the portal
circulation by GLUT2
 GLUT 3
Expressed mostly in neurons (where it is
believed to be the main glucose transporter
isoform), and in the placenta
 GLUT 4
Present in insulin-responsive tissues, skeletal
muscle, adipose tissue, and heart
Found in adipose tissue and striated muscles
(skeletal muscle and cardiac muscle).
 GLUT 5
The GLUT 5 Na+-independent facilitative
transporter allows fructose as well as glucose
and galactose to be transported with their
concentration gradients.
 Transport of glucose, fructose, and
galactose across the intestinal epithelium. The SGLT 1 (Sodium – glucose transporter) coupled
to the Na+-K+ pump, allowing glucose and galactose
to be transported against their concentration
gradients.
The GLUT 5 Na+-independent facilitative transporter
allows fructose as well as glucose and galactose to be
transported with their concentration gradients.
Exit from the cell for all the sugars is via the GLUT 2
facilitative transporter.
Cotransport