BMS100_BCH1_Metabolism overview student.pdf

Full Transcript

Review: ATP
ATP structure
Note the three parts of the nucleotide
structure – what are they?
Note the high energy phosphoanhydride
bonds

Burning of fuels
ADP +

Pi
Biological Work

ATP

NH2
C
N
HC

O O O
O P O P O P O C H2
O
O O
H
H
HO

N

C N
C

N

O
H H

HO

CH

Energy Production
Forms of cellular energy
ATP = direct energy
NADH and FADH2 = indirect energy
Need to go to ETC to make ATP

ANABOLIC
PATHWAYS

Purpose

Location

Gluconeogenesis
Gluconeogenesis

Makes glucose from precursor
molecules

Mitochondria
and cytosol

Glycogenesis
Glycogenesis

Makes glycogen to store glucose

Cytosol

Fatty acid synthesis

Fatty Acid Synthesis

Makes fatty acids from acetyl CoA

Cytosol

Lipogenesis/
triglyceride
Lipogenesis
synthesis

Adds fatty acids to a glycerol
backbone to make triglyceride
lipids

Cytosol

Ketogenesis
Ketogenesis

Makes ketone bodies from acetyl
CoA

Mitochondria

Pentose
Phosphate
Shunt
Pentose
Phosphate
(PPS)

Shunts glucose into the creation
of various 5-carbon sugars and
NADPH

Cytosol

Shunt

CATABOLIC
PATHWAYS
Glycogenolysis
Glycogenolysis

Purpose

Location

Breakdown of glycogen to release glucose.
Glucose can then enter glycolysis to produce
energy.

Cytosol

Glycolysis
Glycolysis

Breakdown of glucose to pyruvate to produce Cytosol
energy (NADH, ATP). After glycolysis,
pyruvate can be converted to acetyl CoA to
enter the CAC to produce more energy.

Beta oxidation
Beta

Breakdown of fatty acyls to acetyl CoA to
produce energy (NADH, FADH2). Acetyl CoA
can enter the CAC to produce more energy.

Mitochondria

Ketolysis/ketone
Ketolysis
body
oxidation

Breakdown of ketone bodies to acetyl CoA.
Acetyl CoA can enter the CAC to produce
more energy.

Mitochondria

Krebs Cycle/Citric
Citric Acid
Acid Cycle (CAC)

Breakdown of citrate (made from acetyl CoA
and oxaloacetate) to produce energy (NADH,
FADH2, ATP).

Mitochondria

oxidation

Cycle

Glucose for energy
Glycolysis

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

*NADH,
FADH2

Citrate
Citric
Acid
Cycle

Ketones

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Glycolysis

Cytosol
Glucose

Glucose 6-P

Conversion of glucose into
two pyruvate in the cytosol

ATP
NADH

ATP and NADH produced
Pyruvate can then be
converted to acetylCoA
Creates more NADH
Can enter CAC

Why does conversion of
pyruvate to acetyl CoA
only happen under
aerobic conditions?

Pyruvate

Mitochondia

Pyruvate
NADH

Acetyl CoA
NADH
FADH2
ATP

CAC

Anaerobic Glycolysis
When there is a lack of
oxygen, pyruvate
converts to lactate
rather than ?
Purpose

Cytosol
Glucose

Glucose 6-P
NADH + H+

NAD+
ADP + Pi

ATP

Regenerates NAD+
How is this helpful in
terms of energy
production?

Lactate

Pyruvate

NAD+

Gluconeogenesis

Cytosol
Glucose

Glucose 6-P

Liver is a main site of GNG
Helps make glucose to send
to other tissues when blood
sugar is low

Glycerol
Pyruvate

Lactate

oxaloacetate

Substrates include:
Certain amino acids
(“glucogenic” aa’s)
Lactate

Mitochondia

Pyruvate

oxaloacetate

Glycerol
Various aa’s

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

*NADH,
FADH2

Citrate
Citric
Acid
Cycle

Ketones

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Glycogenolysis
Liver and muscle breakdown glycogen for different
reasons
Liver
Releases glucose to raise blood sugars levels when they
are low

Muscles
Why do you think?

Glucose – What do we do with it if have
more than we need?
Store it
Glycogenesis

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

*NADH,
FADH2

Citrate
Citric
Acid
Cycle

Ketones

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Glycogenesis
This is an anabolic
process – where is the
energy input?

Glycogen

Cytosol

UDP-glucose

ATP
Not recuperated via
glycolysis

UTP
What is UTP?
Breaking P off of UTP
is similar to breaking
P off of ATP

UTP

Glucose
ATP

Glucose 6-P

Glucose – What else can we do with it?
Send it into the pentose phosphate shunt
Makes:
NADPH – used for fatty acid synthesis, antioxidation
5-C sugars - such as ribose -5- P for nucleotide synthesis

Can feed sugars back into glycolysis (“shunt”) if needed

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

*NADH,
FADH2

Citrate
Citric
Acid
Cycle

Ketones

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Breakdown of fatty acids for energy
Beta oxidation
What type of energy is produced?
What are the fats broken down into?
What happens to this molecule next if you want more
energy?

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

*NADH,
FADH2

Citrate
Citric
Acid
Cycle

Ketones

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Making fatty acids
Excess glucose can divert to make fatty acids
What is one connection between excess glucose and
fatty acid synthesis?
NADPH
Glucose

Glucose 6-P

5-C sugars
Fatty
Acids

Pyruvate
Acetyl
CoA

Lipogenesis
If you don’t need your fatty acids for energy, how
do you store them for later retrieval and use?

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

*NADH,
FADH2

Citrate
Citric
Acid
Cycle

Ketones

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Lipolysis
Releases fatty acids from triglycerides
How does this contribute to energy production?

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

*NADH,
FADH2

Citrate
Citric
Acid
Cycle

Ketones

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Triglycerides for energy
Compared to glycogen, TG’s take up less space
Based on their structures, why do you think this is?

This is one reason they can
store more energy

https://commons.wikimedia.org/wiki/File:Glycogen_chain.png

https://commons.wikimedia.org/wiki/File:220_Triglycerides-01.jpg

Ketones
Ketogenesis
The liver can make ketone bodies from acetyl CoA
These ketone bodies can then be used by other
tissues (such as cardiac muscle, smooth muscle,
brain) when energy is needed

Ketolysis
The breakdown of ketone bodies to release acetyl
CoA
How does this help with energy production?
Note: The liver only makes ketone bodies, it cannot
use them itself

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

Citrate
Citric
Acid
Cycle

Ketones

*NADH,
FADH2

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

Citric Acid Cycle
Any cycle that can lead to the production of acetyl
CoA can feed into CAC to make more energy
What 3 catabolic pathways can feed into CAC?

Cytosol

Glycogen

ATP
Glucose 6-P

Glucose

NADPH

ATP
Pyruvate

Glycerol

PentoseP-Sugars

ATP

*NADH

Triglycerides

Fatty AcylCoA

*NADH

Fatty Acids

Oxaloacetate
*NADH
Pyruvate

ATP

AcetylCoA

Oxaloacetate

Mitochondria
CO2
*NADH, FADH2

O2

*NADH, FADH2

Citrate
Citric
Acid
Cycle

Ketones

*NADH,
FADH2

Fatty
AcylCoA

ATP

Electron Transport Chain

ATP

ATP

H2O

Acetyl
CoA

ETC
Found in the inner mitochondrial membrane
Takes electrons from NADH and FADH2
Passes them down a chain of electron carriers with
increasing electron affinity
Eventually donates them to oxygen to make water
Energy from electron movement used to pump H+ into
the intermembrane space
Creates an H+ gradient that is used to drive the production
of ATP