E2P1 Cell Metabolism PPT - student PDF

Summary

This document covers cellular metabolism and metabolic pathways, including glycolysis, the Krebs cycle, and oxidative phosphorylation. It explains the terminology, structure of ATP, and the fate of pyruvate under aerobic and anaerobic conditions.

Full Transcript

Cellular Metabolism
and Metabolic
Pathways
E2P1

Lecture Material for Exam 2
 Terminology
Catabolism – break down of large
molecules
o
Anabolism – building large molecules
o
Substrate = reactant = beginning
Product = ending
 Structure of ATP Molecule
Adenosine triphosphate (ATP) is the energy molecule of the cell. During catabolic reactions, ATP is
created and energy is stored until needed during anabolic reactions.
 Terminology 2
Oxidation – loss of electron –
Reduction – gain of electron –
Redox reaction - transfer of electron
o Facilitated by high energy enzymes
NADH and FADH2
Oxidative phosphorylation –
conversion of NADH and FADH2 into
ATP
 Figure 24.4

Cellular
Respiration
Cellular respiration
oxidizes glucose
molecules through
glycolysis, the
Krebs cycle, and
oxidative
phosphorylation to
produce ATP.
 Glycolysis Catabolizes
Carbohydrates

Figure 3.41
*Do NOT memorize structures*

Glycolysis
Location: Cytosol
Glucose (6C) ➞ 10 reactions ➞ 2 pyruvates (3C)
– Note: pyruvic acid = pyruvate
 Glycolysis Catabolizes

Campbell Essential Biology with Physiology 4th Ed. Fig 6.7
Carbohydrates

Glycolysis
Location: Cytosol
Glucose (6C) ➞ 10 reactions ➞ 2 pyruvates (3C)
– Note: pyruvic acid = pyruvate
Substrate Level Phosphorylation
Produces ATP Directly

Campbell Biology 9th Ed. Figure 9.7

Substrate-level
phosphorylation
Phosphate transferred directly
from substrate to ADP to form ATP
Mass Action Determines Pyruvate Fate

Sprinters Marathoners

aerobic
anaerobic

Anaerobic (low O2) Aerobic (high O2)
– Fermentation – Kreb’s, Electron Transport
(cytosol) (mitochondria)
 Anaerobic Glycolysis Relies on
Regeneration of NAD+
Anaerobic
Glycolysis
Regenerates
NAD+ so reactions
can persist
Small, but
ATP yield
No O2 requirement The energy stored in
(but still occurs in lactate is still used by
presence of O2) the body
 Anaerobic Glycolysis Relies on Regeneration of
NAD+

Anaerobic Glycolysis
2 pyruvate + 2 NADH 2 lactate + 2
NAD+
 Glycolysis Overview
During the energy-consuming phase
of glycolysis, two ATPs are
consumed, transferring two
phosphates to the glucose molecule.
The glucose molecule then splits into
two three-carbon compounds, each
containing a phosphate. During the
second phase, an additional
phosphate is added to each of the
three-carbon compounds. The
energy for this endergonic reaction
is provided by the removal
(oxidation) of two electrons from
each three-carbon compound.
During the energy-releasing phase,
the phosphates are removed from
both three-carbon compounds and
used to produce four ATP molecules.
Anaerobic Glycolysis Summary (One Glucose)

Proces ATP ATP NAD FADH ATP ATP ATP CO2
s used direc H 2 indir total net net
t net net ect
Anaerob 2 4 0 0 0 4 2 0
ic
ATP used: # of ATP broken down (input)
glycolys
is ATP direct: # ATP via substrate level phosphorylation
NADH net: # NADH produced - # NADH used
FADH2 net: # FADH2 produced - # FADH2 used
ATP indirect: # ATP via oxidative phosphorylation
(3 x #NADH) + (2 x #FADH2) via electron transport chain
ATP total: ATP direct + ATP indirect
ATP net: ATP total – ATP used
CO2 net: CO2 produced
Mass Action Determines Pyruvate Fate

Sprinters Marathoners

aerobic
anaerobic

Campbell Biology 9th Ed. Figure 9.18

Anaerobic (low O2) Aerobic (high O2)
– Fermentation – Kreb’s, Electron Transport
(cytosol) (mitochondria)
 Under Aerobic Conditions Pyruvate
Enters the Mitochondria
Aerobic
carbohydrate
metabolism:
1. Glycolysis
2. Pyruvate
activation
3. Kreb’s Cycle
4. Electron Transport
Campbell Essential Biology with Physiology 4 th
Ed. Ch

Chain (ETC)
 Under Aerobic Conditions Pyruvate
Enters the Mitochondria
Aerobic
carbohydrateGlycolysis (aerobic conditions
metabolism:
1. Glycolysis
2. Pyruvate
activation
3. Kreb’s Cycle
4. Electron Transport
Chain (ETC)

Campbell Essential Biology with Physiology 4th Ed. Fig
Electrons on Cytoplasmic Carriers Must
Be “Shuttled” Into the Mitochondria

FADH2
NADH

Silverthorn 5th Ed
*NADH*

Cytoplasmic NADH has varied energy
equivalents
– Depends on active vs. passive transport
 Electrons Must Enter
Mitochondria
Heart/Liver:
Mitochondrial shuttles:
Heart/Liver:
Malate-aspartate shuttle
– no energy loss
– 3 ATP/NADH
Skeletal Muscle:

Skeletal Muscle:
Glycerol-phosphate shuttle
– energy loss
– 2 ATP/NADH
Under Aerobic Conditions Pyruvate
Enters the Mitochondria
Aerobic
carbohydrate
metabolism:
1. Glycolysis
2. Pyruvate
activation
3. Kreb’s Cycle Campbell Biology 9th Ed. Figure 9.10

4. Electron Transport
Chain (ETC)
Under Aerobic Conditions Pyruvate
Enters the Mitochondria

Aerobic
carbohydrate
metabolism:
1. Glycolysis
2. Pyruvate
activation
3. Kreb’s Cycle
4. Electron Transport
Chain (ETC) *Do NOT memorize structures*
 Electron Carriers Link Glycolysis and the
Kreb’s Cycle to Oxidative Phosphorylation

Campbell Biology 9th Ed. Figure 9.6
The electron transport chain produces ATP from
high energy electrons via oxidative phosphorylation
The Electron Transport Chain Produces
ATP by Oxidative Phosphorylation

Electrons transferred to
electron transport chain
– Energy released during
transfer pumps H+ into
FADH2
NADH intermembrane space

Chemiosmosis:
H+ gradient used to
make ATP (ATP
synthase)
Silverthorn 5th Ed. – NADH = 3 ATP
– FADH2 = 2 ATP
Oxygen is required as the ultimate
electron acceptor: ‘oxidative
phosphorylation’
Complete Oxidation of Glucose
 Complete Oxidation of
Glucose
Glycolysis (Aerobic): Heart/Liver
Proces ATP ATP NAD FADH ATP ATP ATP CO2
s used direc H 2 indir total net net
t net net ect
glycolys 2 4 2 0 6 10 8 0
is ATP used: # of ATP broken down (input)
ATP direct: # ATP via substrate level phosphorylation
NADH net: # NADH produced - # NADH used
FADH2 net: # FADH2 produced - # FADH2 used
ATP indirect: # ATP via oxidative phosphorylation
((3 x #NADH) + (2 x #FADH2) via electron transport chain)
ATP total: ATP direct + ATP indirect
ATP net: ATP total – ATP used
CO2 net: CO2 produced
Complete Oxidation of Glucose
Glycolysis (Aerobic): Skeletal Muscle
Proces ATP ATP NAD FADH ATP ATP ATP CO2
s used direc H 2 indir total net net
t net net ect
glycolys 2 4 0 *Cytosolic
2* 4
NADH 8
converted to6 FADH2 0
is ATP used: # of ATP broken down (input)
ATP direct: # ATP via substrate level phosphorylation
NADH net: # NADH produced - # NADH used
FADH2 net: # FADH2 produced - # FADH2 used
ATP indirect: # ATP via oxidative phosphorylation
((3 x #NADH) + (2 x #FADH2) via electron transport chain)
ATP total: ATP direct + ATP indirect
ATP net: ATP total – ATP used
CO2 net: CO2 produced
Complete Oxidation of Glucose
Pyruvate Activation
Proces ATP ATP NAD FADH ATP ATP ATP CO2
s used direc H 2 indir total net net
t net net ect
activati 0 0 2 0 6 6 6 2
on ATP used: # of ATP broken down (input)
ATP direct: # ATP via substrate level phosphorylation
NADH net: # NADH produced - # NADH used
FADH2 net: # FADH2 produced - # FADH2 used
ATP indirect: # ATP via oxidative phosphorylation
((3 x #NADH) + (2 x #FADH2) via electron transport
chain)
ATP total: ATP direct + ATP indirect
ATP net: ATP total – ATP used
CO2 net: CO2 produced
Complete Oxidation of Glucose
Kreb’s
Proces ATP ATP NAD FADH ATP ATP ATP CO2
s used direc H 2 indir total net net
t net net ect
Kreb’s 0 2 6 2 22 24 24 4
ATP used: # of ATP broken down (input)
ATP direct: # ATP via substrate level phosphorylation
NADH net: # NADH produced - # NADH used
FADH2 net: # FADH2 produced - # FADH2 used
ATP indirect: # ATP via oxidative phosphorylation
((3 x #NADH) + (2 x #FADH2) via electron transport
chain)
ATP total: ATP direct + ATP indirect
ATP net: ATP total – ATP used
CO2 net: CO2 produced
Summary of Glucose Oxidation
Heart/Liver
Process ATP ATP NADH FADH ATP ATP ATP CO2
used direct net 2 indire total net net
net ct
glycolysi 2 4 2 0 6 10 8 0
s
activatio 0 0 2 0 6 6 6 2
n
1.Kreb’s
Glycolysis:
0 2 6 2 22 24 24 4
total 1glucose
2 +6 10 2pyruvate
2ATP ➞ 2 34 40 + 2NADH
+ 4ATP 38 6

2. Pyruvate Activation:
2pyruvate + 2NAD+ ➞ 2Acetyl CoA + 2CO2 + 2NADH
3. Kreb’s:
2Acetyl CoA + 6NAD++ 2FAD + 2ADP ➞ 4CO2 + 6NADH +
Summary of Glucose Oxidation
Skeletal Muscle
Proces ATP ATP NAD FADH ATP ATP ATP CO2
s used direc H 2 indir total net net
t net net ect
glycolys 2 4 0 2* 4 8 6 0
is
activati 0 0 2 0 6 6 6 2
on
1.Kreb’s
Glycolysis:
0 2 6 *Cytosolic
2 NADH
22 converted
24 to FADH42
24
total 1glucose
2 + 62ATP ➞
8 2pyruvate
4* 32+ 4ATP
38 + 2NADH
36 6

2. Pyruvate Activation:
2pyruvate + 2NAD+ ➞ 2Acetyl CoA + 2CO2 + 2NADH
3. Kreb’s:
2Acetyl CoA + 6NAD++ 2FAD + 2ADP ➞ 4CO2 + 6NADH +
 Metabolic Timeline
What happens after we eat?

What happens between meals?

What happens when we skip a meal?
 Metabolic Timeline
What happens after we eat?
0-4 hours; anabolic phase
Pancreas releases insulin to get
glucose into cells
Liver: extra glucose→glycogen;
AA→ketones
Muscle: glucose→glycogen; AA repair
tissue
Adipose: store extra fats
 Absorptive State
During the absorptive
state, the body digests
food and absorbs the
nutrients.
 Metabolic Timeline
What happens between meals?
4-16 hours; catabolic phase
Initially rely on glycogen Liver:
release glucose; ketones→ATP
Muscle: release glucose;
AA→ketones→ATP
Adipose: release stored lipids
 Postabsorptive State
During the postabsorptive
state, the body must rely
on stored glycogen for
energy.
 Metabolic Timeline
What happens when we skip a
meal?
16 hours+; starvation
Fat-burning
Glycolysis stops in cells that can use
other alternate sources
Fatty acids and triglycerides are used
to create ketones

What Happens When There Is No
Glucose?
Glucose is the primary energy
souce
– Adequate levels must be
maintained

Sources of glucose:
– Glycogen (primary)
Glycogenolysis: Breakdown of
glycogen
Glycogenesis: Synthesis of glycogen
– Gluconeogenesis
Glucose from glycolytic intermediates
(run glycolysis backwards)
– Lactate
– Glycolysis intermediates
– Glucogenic amino acids
– Glycerol from triglycerides (minor) Silverthorn 5th Ed. Figure 4.1
Protein Catabolism Produces Toxic
Intermediates
Protein Catabolism:
1. Proteolysis: polymer ➞ monomers
– Enzyme: proteases
– Polypeptide (protein) ➞ amino acids

2. Deamination
– Amino Acid ➞ NH3 + organic (keto) acid
– NH3 ➞ NH4+ (ammonium; toxic)
– NH4+ ➞ urea (liver) ➞ excreted

3. Energy Production
– Glycolysis and/or Kreb’s
Glucogenic: glycolysis
Ketogenic: Kreb’s
– Oxidative phosphorylation
Siverthorn 5th Ed.
Fats Are the Most Efficient Energy Storage Molecule

Lipids are calorically
dense
– 9kcal/g
– Carbons are more
reduced
– Less weight of hydration

10,000kcals stored as
fat
– enough to run 100 miles
(or sleep for months)
 Important Metabolic
Hormones
Cortisol – – gluconeogenesis
– break down fats and proteins to increase
blood glucose
Glucagon – – breaks down glycogen
in liver to increase blood glucose
Epinephrine – – stimulates
gluconeogenesis
Insulin – – helps cells take glucose from
blood and store it as glycogen in liver –
anabolic