Transcript Document

NS 315
Unit 4: Carbohydrate
Metabolism
Jeanette Andrade MS,RD,LDN,CDE
Kaplan University
Objectives
We want to learn about:
 Glycolysis and ATP formation
 Understand Gluconeogenesis, when, where
and how
 Krebs Cycle and Electron Transport Chain
Definitions
 Glycolysis: central pathway for the catabolism of carbohydrates;
occurs in most organs
 Gluconeogenesis: Biosynthesis of new glucose; occurs mainly in
liver
 Krebs cycle- series of enzymatic reactions in aerobic organisms
involving oxidative metabolism of acetyl units and producing highenergy phosphate compounds, which serve as the main source of
cellular energy
 Electron Transport Chain (ETC)- Composed of mitochondrial
enzymes that transfers electrons from one transport to another,
resulting in the driving force for the formation of ATP
 Oxidative phosphorylation- Process occurring in the cell, which
produce energy and synthesizes ATP
Definitions
 Pyruvate: final 3 carbon molecule of glycolysis, involved in the
Krebs cycle which facilitates energy production
 Adenosine diphosphate/Adenosine triphosphate: energy
storing molecule used by an organism on a daily basis
 NAD/NADPH: Reducing agent in several anabolic reactions such
as lipid and nucleic acid
 FAD/FADH: Reducing agent in several anabolic reactions such
as lipid
 Aerobic: in the presence of oxygen
 Anaerobic: no presence of oxygen
Glycolysis Animation
http://highered.mcgrawhill.com/sites/0072507470/student_view0/chapter2
5/animation__how_glycolysis_works.html
Fates of Pyruvate
Under aerobic conditions
In most aerobic organisms,
pyruvate continues in the
formation of Acetyl CoA and
NADH that follows into the
Krebs cycle and
Under anaerobic conditions
Under anaerobic conditions, such
as during exercise or in red blood
cells (no mitochondria), pyruvate is
reduced to lactate by lactate
dehydrogenase producing NAD for
glycolysis
Pathways during Glycolysis
Aerobic- with oxygen
Anaerobic- without oxygen
 The main energy releasing
 Fermentation pathway and
pathway in most human
cells
 Continues in the
mitochondrion where
oxygen serves as the final
electron acceptor
 1 glucose + 6 oxygen  6
carbon dioxide +6 water
 36 or 38 ATPs are
produced (total after all
cycles: glycolysis, krebs
and ETC)
anaerobic electron transportmany bacteria and humans,
when oxygen is limited, use
this pathway
 Ends in the cytoplasm where
other substances besides
oxygen is the final electron
receptor
 Only 2 ATP are produced
Gluconeogenesis
 During starvation (not eating for 16 hours
plus), the brain can use ketone bodies for
energy by converting to Acetyl CoA, usually
gluconeogenesis creates glucose when
glycogen stores are depleted
 Synthesis of glucose from 3-4 carbon
precursors is a reversal of glycolysis
2 pyruvate + 2 NADH + 4 ATP + 2 GTP
glucose + 2 NAD+ + 4 ADP + 2 GDP + 6 Pi
Gluconeogenesis
 3 reactions in glycolysis are essentially
irreversible, thus they are bypassed in
gluconeogenesis:



Hexokinase (1)
Phosphofructokinase (3)
Pyruvate Kinase (10)
 Share 7 of the 10 steps in glycolysis
Glycolysis vs Gluconeogenesis
Fed state
Fasting state
Cytoplasm
Cytoplasm
All cells
Liver mostly,
but also kidney
Activation of Pyruvate
 Before the Kreb’s cycle begins, pyruvate
must be activated into acetyl CoA
 Pyruvate dehydrogenase complex (PDHC)
is an enzyme that catalyzes the oxidative
decarboxylation of pyruvate to acetyl CoA
 PDHC is a multi-enzyme comprising of 5
coenzymes- which include many vitamins
such as thiamin (thiamin pyrophosphate),
riboflavin (FAD), and niacin (NAD)
Krebs Cycle
 Also known as the citric acid cycle or tricarboxylic acid (TCA)
cycle
 Under aerobic conditions pyruvate enters the mitochondria
MATRIX and is oxidized to Acetyl CoA which enters the Krebs
cycle
 Krebs cycle can occur after glycolysis, after Beta oxidation or
protein degradation to provide energy for cellular respiration
 Equation for Krebs cycle with the beginning products and the
ending. 8 steps involved
2 pyruvate + 2 GDP + 2 H3PO4 + 4 H2O + 2 FAD + 8 NAD+ ----> 6 CO2 + 2 GTP + 2 FADH2 + 8 NADH
Krebs Cycle
 http://highered.mcgraw-
hill.com/sites/0072507470/student_view0/chapter25/animation__ho
w_the_krebs_cycle_works__quiz_1_.html
Summary TCA
 Occurs in the mitochondrial matrix
 Uses acetyl CoA to produce:

3 NADH, 1 FADH, 1 GTP, 2CO2
 Produce intermediates for biosynthetic pathways
such as aminoacid synthesis, gluconeogenesis,
pyrimidine synthesis, phorphyrin synthesis, fatty
acid synthesis, isoprenoid synthesis.
Electron Transport Chain (ETC)
 Final pathway by which electrons generated from
oxidation of carbs, protein and fatty acids, are ultimately
transferred to O2 to produce H20
 Located in the inner mitochondrial membrane
 Electrons travel down the chain, pumping protons into the
intermembrane space creating the driving force to produce
ATP in a process called oxidative phosphorylation
 There are 4 complexes that comprise the ETC
Electron Transport Chain
http://vcell.ndsu.edu/animations/etc/movie.htm
Summary ETC
 Reduced electron carriers NADH & FADH2 reduce O2 to H2O via the
ETC. The energy released creates a proton gradient across the
inner mitochondrial membrane. The protons flow down this
concentration gradient back across the inner mitochondrial
membrane through the ATP Synthase. The driven force makes this
enzyme rotate and this conformation generates enough energy to
make ATP.
 Oxidation of NADH to NAD+ pumps 3 protons which charges the
electrochemical gradient with enough potential to generate 3 ATPs.
 Oxidation of FADH2 to FAD+ pumps 2 protons which charges the
electrochemical gradient with enough potential to generate 2 ATPs.