Cellular Energetics 2024 PDF

Summary

This document provides a detailed overview of cellular energetics, including metabolism, ATP hydrolysis, cellular respiration, and different types of fermentation, such as alcoholic and lactic acid fermentation. The information is presented using diagrams and text, which makes the material easy to follow and digest.

Full Transcript

Cellular Energetics
 Metabolism
Metabolism = sum of all chemical reactions in the body
Human Metabolic Map is Highly Complex
 Overview:
Aerobic Oxidation & Photosynthesis
Reactions may be Exergonic or Endergonic

Exergonic reactions: Endergonic reactions:
release energy (downhill) require energy (uphill)
ΔG = negative ΔG = positive
– spontaneous – non-spontaneous
catabolic (breakdown) anabolic (build-up)
 Energy Coupling
Endergonic reactions are coupled to exergonic reactions
– Theoretically, any endergonic reaction can be coupled to any
exergonic reaction. (However, this is not the case.)
 ATP Hydrolysis
ATP: major energy currency of cells
ATP hydrolysis: the most common
exergonic coupling reaction
– ATP  ADP + Pi ΔG = -7.3 kcal/mol

After ATP is hydrolyzed, how does a cell obtain more ATP?
– Cells can synthesize new ATP or regenerate ATP from ADP + Pi
Regeneration of ATP is more energetically favorable
– Cellular respiration evolved to regenerate ATP from ADP and Pi.
Average human regenerates about 100 moles ATP per day
– = ~6X1020 ATP regenerated per second!
 Cellular Respiration

Chemical equation for aerobic cellular respiration is:
C6H12O6 + 6O2  6H2O + 6CO2

– in this reaction:
glucose is oxidized to CO2
oxygen is reduced to H2O

complete eukaryotic oxidation of glucose requires both
the cytosol and mitochondria
Mitochondrion
 Origin of Mitochondria
Process called endosymbiosis:
– Mitochondria evolved from free-living bacteria that invaded or
was engulfed by an early eukaryotic cell (or another prokaryote)
– It then evolved to co-exist with its host, with some of its genes
moving to the nucleus.
 Aerobic Cellular Respiration

Obligate aerobes, facultative aerobes and facultative
anaerobes can undergo aerobic respiration.
4 subsets of reactions that are spatially separated:

Reactions Location
Glycolysis Cytosol
Oxidation of pyruvate Mitochondrial matrix
TCA cycle Mitochondrial matrix
Chemiosmosis, Oxidative Mitochondrial matrix,
Phosphorylation & Electron intermembrane space & inner
Transport Chain mitochondrial membrane
Summary of Aerobic Oxidation of
Glucose & Fatty Acids
 Comparing Substrate-Level & Oxidative
Phosphorylation
1. Substrate-level phosphorylation:

2. Oxidative Phosphorylation:
uses the electron transport chain and oxygen
most of the ATP made during aerobic cellular respiration is
made here
requires electrons, which are “captured” during glycolysis, the
oxidation of pyruvate and the Kreb’s cycle
 Electron Carriers
Two electron carriers of respiration:
– NAD+: Nicotinamide Adenine Dinucleotide
– FAD: Flavin Adenine Dinucleotide (Vitamin B2)
Redox of NAD+ and FAD: Oxidized forms of these compounds
do not carry e-, while reduced forms carry 2 e- each
NAD+NADH + H+ (2e- gained) FADFADH2 (2e- gained)
 Glycolysis
2 subsets of reactions
– Energy-requiring phase: need 2 ATP per glucose
– Energy-yielding phase: produce 4 ATP per glucose
By the end of glycolysis,
per glucose:
2NADH (4 e-)
2 pyruvate
4 ATP (2 net) by
substrate level
phosphorylation
 What happens if there is no O2?.
Cell can only regenerate ATP by glycolysis
– Typically increases uptake of glucose (Pasteur effect).
Pasteur effect: the shift from slow aerobic to rapid anaerobic
consumption of glucose was first noted by Pasteur.

This shift also happens anytime you are unable to provide oxygen to
your own mitochondria- they consume glucose faster in an attempt
to produce ATP via the less efficient fermentation to lactate, and
lactic acid accumulates in your muscles.

To continue break-down of glucose need NAD+, so
NADH is oxidized to NAD+ by fermentation.
2 common forms of fermentation are:

– alcohol fermentation in yeast
– lactic acid fermentation in human muscle cells
 Fermentation
Yeast would produce ethanol from glucose
via a process called alcoholic
fermentation

When oxygen is scarce in muscle cells,
NADH reduces pyruvate to form lactic
acid, regenerating NAD+, via a process
called lactic acid fermentation
In Presence of O2, Pyruvate
Enters Mitochondria
Pyruvate  Acetyl-CoA  TCA Cycle
TCA Cycle, Kreb’s Cycle, Citric Acid Cycle
 Tally-Sheet After TCA Cycle

yield of various substances from 1 glucose molecule thus far:

– NADH 10 [2 glycolysis, 2 pyruvate oxidation, 6 TCA cycle]
– FADH2 2 [TCA cycle]
– CO2 6 [2 oxidation of pyruvate, 4 TCA cycle]
– ATP 6 [4 net]
 Electron Transport Chain & Oxidative
Phosphorylation
NADH and FADH2 e- carriers release their e- into the electron
transport chain (ETC)
– located within the inner mitochondrial membrane
– e- transfer between ETC members driven by final e- acceptor O2, so
the process is named: oxidative phosphorylation.
 Electron Transport Chain &
Oxidative Phosphorylation
ETC consists of:
– 5 protein complexes (Complexes I-V):
Complex I = NADH dehydrogenase or NADH-CoQ reductase
Complex II = Succinate coenzyme Q reductase
Complex III = Cytochrome c reductase
Complex IV = Cytochrome c oxidase
Complex V = ATP Synthase

– 2 carriers:
Coenzyme Q (CoQ) or ubiquinone CoQ/CoQH2 (a lipid soluble
coenzyme Q)
Cytochrome c (Cyt c)- water soluble protein
e- Flow through Complexes I-IV & Carriers

NADH e- : I → CoQ → III → Cyt C → IV → O2

FADH2 e-: II → CoQ → III → Cyt C → IV→ O2

e- from
NADH e- from
FADH2
 What happens as e- flow?

As e- flow, protons (H+) move from the mitochondrial matrix to
the intermembrane space.

– the e- transferred from each NADH result in the movement
of ~10 H+ into the intermembrane space

– the e- transferred from each FADH2 result in the movement
of ~ 6 H+ into the intermembrane space

Why the difference?
 Complex V = ATP Synthase

H+ cannot return to the matrix
through the membrane

ATP synthase provides a
channel through which they
can move

movement of 3 H+ through ATP
synthase powers regeneration
of ~ 1 ATP
 ATP Made by Oxidative Phosphorylation
Total ATP by Oxidative Phosphorylation:
– From each NADH, 3ATP: 10 NADH X 3 = 30 ATP
– From each FADH2, 2 ATP: 2 FADH2 X 2 = 4 ATP

But, remember that 2 NADH were made in the cytosol during
glycolysis:

– NADH cannot move through the mitochondrial inner membrane.
these e- cannot be used in the ETC unless they are transported
across the membrane.

– Process of e- shuttle (malate shuttle and others) uses energy to
move NADH across (~1 ATP per NADH)
so the net ATP yield from one cytosolic made NADH is 2 (= 3 – 1)
 The Malate Shuttle
Cylical series of reactions transfers e- from NADH in cytosol across inner
mitochondrial membrane (NADH impermeable) to NAD+ in the matrix
Result: cytosolic NADH  NAD+ and matrix NAD+  NADH
 Revised ATP Yield from all of Aerobic
Cellular Respiration
Oxidative Phosphorylation:
NADH:
10 NADH X 3 = 30 ATP - 2 ATP (e- shuttle) = 28 ATP
FADH2:
2 FADH2 X 2 = 4 ATP
Therefore, 32 net ATP from oxidative phosphorylation

Substrate-level phosphorylation:
4 net ATP from substrate-level phosphorylation

Grand total = 36 net ATP per glucose
Summary of Aerobic Oxidation of
Glucose & Fatty Acids
Transport Across Mitochondrial Membranes

Outer mitochondrial membrane contains many porins:
– Relatively non-selective transmembrane proteins that allow ions,
small molecules, NADH, ATP, ADP, etc. to move through

Inner mitochondrial membrane
is more selective
– major selectivity barrier for
movement of substances into
and out of matrix
– IMM Transport examples:
Malate Shuttle
Phosphate transporter
ATP/ADP antiporter
 Control of Respiration

Rate of respiration is affected in a variety of ways:
1. Allosteric control of respiration occurs when
phosphofructokinase-1 is stimulated or inhibited.
AMP is an activator, whereas ATP and citrate are inhibitors.
 Control of Respiration

2. ADP levels:
endogenous ADP is depleted by ATP formation
low levels of ADP decrease rate of respiration, while increased
amounts of ADP increases respiratory rate

3. Uncouplers:
a substance that separates the proton-motive force across the
inner mitochondrial membrane from ATP synthesis and inhibits
ATP synthesis
include chemical uncouplers & natural substances

4. Metabolic Blocks
prevent e- flow through the ETC
Chemical Uncoupler: 2,4-dinitrophenol (DNP)

NORMAL: WITH 2,4-DNP:
Natural substance Uncoupler: Thermogenin
Thermogenin: a proton carrier protein found on the inner
mitochondrial membrane of brown-fat mitochondria (brown fat
tissue)
– by moving H+ across the inner membrane and not through ATP
synthase, heat (but not ATP) is generated
– brown fat is more common in children than adults
 Metabolic Blocks
typically prevent the flow of electrons through the ETC
– disrupt proton gradient, little or no ATP generated
– some block ATP synthase so protons cannot move through
examples: cyanide, rotenone, malonate, antimycin-a, oligomycin
 Alternative Fuels
Most cells “prefer” glucose as the molecule of choice for
respiration. In its absence, cells can metabolize other organic
compounds to regenerate ATP.

2 mechanisms are:
– β-oxidation: use of fatty acids for mitochondrial respiration
– Gluconeogenesis: production of glucose from sources
other than glycogen

Note: Some cells such as neurons, erythrocytes, and kidney
medullar cells use only glucose for respiration, whereas others
may preferentially use fatty acids. For example, fatty acids are
the major energy source for cardiomyocytes.
 β-Oxidation
using fatty acids for mitochondrial respiration
fatty acids are stored in adipose cells (adipocytes) as triglycerides
– when needed, triglycerides are oxidized to fatty acids in cytosol
– triglycerol + H20  Fatty acid + glycerol
fatty acids are esterified to CoA to form fatty acyl CoA
– fatty acid + HSCoA + ATP Fatty acyl CoA + AMP + PPi
fatty acyl group transferred to cytosolic carnitine molecule and moves
thru the IMM by acyl carnitine transporter protein
in matrix: carnitine releases fatty acyl group, which combines with
another CoA molecule to form fatty acyl CoA
– fatty acyl CoA is oxidized to Acetyl Co-A
 Fatty Acid Oxidation

Fatty acids converted to
Acetyl CoA by repeated
series of 4 enzyme catalyzed
reactions
Termed β-oxidation b/c it
occurs by sequential removal
of 2-carbon units by oxidation
at the β-carbon position of the
fatty acyl-CoA molecule
Each round of mitochondrial
β-oxidation of 1 molecule of
fatty acyl CoA to Acetyl CoAs
produces 1 FADH2 & 1 NADH
for each Acetyl CoA made
– Example: 18 C fatty acyl
molecule yields 9 Acetyl
CoA, 8 NADH & 8 FADH2
 β-oxidation cont.

Acetyl-CoA (end product of each round of β-oxidation)
enters the TCA cycle where it is further oxidized to CO2
– also generated in TCA cycle are 3 molecules of NADH, 1 molecule
of FADH2 and 1 molecule of ATP
– NADH and FADH2 generated during the fat oxidation and Acetyl-
CoA oxidation in the TCA cycle enter ETC to produce ATP

Fatty acids oxidation yields significantly more energy per
carbon atom than does the oxidation of carbohydrates
– Eg) net result of the oxidation of one mole of 18-C fatty acyl CoA will
be 146 moles of ATP; in comparison 114 moles would be generated
from an equivalent number of glucose carbon atoms.
 Very long Chain Acyl CoA
Dehydrogenase Deficiency (VLCADD)
an autosomal recessive
disorder resulting in an
intramitochondrial defect
in β-oxidation
body cannot oxidize fatty
acids b/c an enzyme is
absent or not functioning
correctly
can cause severe
hypoketotic
hypoglycemia, liver
dysfuction w/
hepatomegaly,
cardiomyopathy,
encephalopathy,
lethargy, sudden death
 Gluconeogenesis

Metabolic pathway resulting in glucose formation from
noncarbohydrate sources
– Site: occurs in liver & kidney when dietary carbohydrate sources
are insufficient to meet the body’s glucose demands
it occurs partly in cytosol and partly in mitochondria
Importance of gluconeogenesis:
– chief source of blood glucose after the 1st 18 hrs fasting
– removes blood lactate produced by RBC and muscles and blood
glycerol produced by adipose tissue or absorbed by intestine
when glycogen stores are depleted (muscle exertion, liver
during fasting), muscle protein catabolism to AA contributes
major carbon source to maintain blood glucose levels
Precursors include: pyruvate, lactate, glycerol, glucogenic AA
– all 20 AA (except L & K) can be degraded to TCA intermediates
– allows the carbon skeletons of the AA to be converted to those in
OAA and pyruvate
 Gluconeogenesis notes:
– Non-carbohydrate sources
and entry points for
gluconeogenesis (yellow)
– Enzymes used only for
gluconeogenesis (pink)
– Enzymes used for both
gluconeogenesis and
glycolysis (blue)