Online Lesson 1: Introduction to Metabolism and Biochemical Reactions PDF

Summary

This document presents an online lesson on the introduction to metabolism and biochemical reactions. It covers catabolic and anabolic pathways, different types of organisms in terms of energy sources, and details five biochemical reactions frequently found in cells.

Full Transcript

Online Lesson 1
Introduction to Metabolism
and Biochemical Reactions
 Lesson Outcomes

By the end of this lesson, you should be able
to:
– Explain how metabolic pathways are organized
and regulated within a living cell.
– Compare autotrophs and heterotrophs, aerobic
and anaerobic organisms.
– Compare nucleophilic substitutions, nucleophilic
additions, carbonyl condensations, eliminations,
and oxidations and reductions biochemical
reactions.
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 Introduction to Metabolism

Metabolism describes all biochemical
reactions in living cells.
Catabolism pathways are the sum of all
metabolic processes by which complex
molecules are broken down to simpler
ones.
Catabolism is generally accompanied by
the net release of chemical energy.
3
 Introduction to Metabolism
(Cont.)
Anabolism pathways are the sum of all
metabolic processes by which complex
molecules are built up from simpler ones.
Anabolism is generally accompanied by the
consumption of chemical energy.
Metabolites are small molecules of
(intermediates and metabolism products)
that serve as intermediates in catabolic and
anabolic pathways.
4
 Introduction to Metabolism
(Cont.)
Catabolic and anabolic
pathways stages are
numbered and colored
Catabolic pathways are in
red, anabolic pathways
are in blue.

Appling, Dean, R. et al. Biochemistry: Concepts and Connections. (2nd Edition), 2018.

5
 Introduction to Metabolism
(Cont.)
Most organisms get raw materials and the
energy for biosynthesis from organic
molecules such as glucose.
Organisms can make a living, based on
the source of their energy molecules, in
two different ways:
– Autotrophs
– Heterotrophs

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 Introduction to Metabolism
(Cont.)
Autotrophs (self-feeding):
– Synthesize glucose and all their other organic
compounds from inorganic carbon, supplied
as carbon dioxide. E.g., plants.

Heterotrophs (feeding on others):
– Synthesize their organic metabolites only by
consuming other organic compounds. E.g.,
animals.
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 Introduction to Metabolism
(Cont.)
Almost all multicellular organisms and
many bacteria are aerobic organisms.
Aerobic organisms depend on cellular
respiration process.
Cellular respiration is a process that
generate cellular energy by oxidizing
nutrient molecules using O2 as the
electron acceptor.
8
 Introduction to Metabolism
(Cont.)
Some microorganisms can or must grow in
anaerobic environments.
Anaerobic environments refers to the
absence of oxygen or the absence of a
need for oxygen.
Any biological processes that must or can
occur without oxygen are called
anaerobic process.
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 Introduction to Metabolism
(Cont.)
Glycolysis:
– A catabolic pathway that converts a glucose
into two pyruvate molecules and energy in
both aerobic and anaerobic cells.
The main input to glycolysis process is glucose,
and it comes either from polysaccharides or dietary
carbohydrates.
– In the absence of oxygen, pyruvate is reduced
to lactate or ethanol and CO2 molecules by
anaerobic processes called fermentations.
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 Introduction to Metabolism
(Cont.)
Oxidative metabolisms:
– When oxygen is present, pyruvate undergoes
oxidative metabolism (respiration) where
pyruvate is oxidized to acetyl-coenzyme A
(acetyl-CoA).
– Acetyl-CoA undergoes oxidation in the citric
acid cycle.
Citric acid cycle may also accept acetyl-CoA from
lipids or proteins to completes the oxidative
metabolisms.

11
 Introduction to Metabolism
(Cont.)
Citric acid cycle:
– Oxidation reaction of citric acid cycle
produces reduced electron carriers.
Examples of high energy electron carriers:
– Nicotinamide adenine dinucleotide (NAD+)
– Flavin adenine dinucleotide (FAD)
– Electron carriers can be reoxidized to
synthesis adenosine triphosphate (ATP)
from adenosine diphosphate (ADP+).

12
 Introduction to Metabolism
(Cont.)
Electron transport chain:
– A sequence of electron carrier
molecules in a cell where electrons pass
from one carrier to the next.
– The chain captures the energy released
when high energy electron carrier
molecules are oxidized
– The energy is used to synthesis ATP.

13
 Introduction to Metabolism
(Cont.)
Phosphorylation: adding phosphate
group
– The phosphorylation of adenosine
diphosphate (ADP+) to adenosine
triphosphate (ATP).
– It occurs in conjunction with the flow of
electrons in the electron transport chain
of the inner mitochondrial membrane.

14
 Introduction to Metabolism
(Cont.)
Gluconeogenesis:
– A process by which glucose is synthesized
from noncarbohydrate precursors
– Examples of noncarbohydrate precursors are:
Glycerol
Lactate
Some amino acids
Acetyl-CoA (in plants)

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 Introduction to Metabolism
(Cont.)
Photosynthesis:
– A process by which energy from light is
captured by green plants and used to
synthesis carbohydrate from CO2 and H2O.
– The light energy is used to produce energy
(ATP) and nicotinamide adenine
dinucleotide phosphate (NADPH).
– Both ATP and NADPH are used for
carbohydrate synthesis as a source of energy.

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Types of Biochemical Reactions

The five types of chemical reactions
commonly found in cells and catalyzed by
cellular enzymes are:
– Nucleophilic substitution reactions
– Nucleophilic addition reactions
– Carbonyl condensation reactions
– Elimination reactions
– Oxidation/reduction reactions

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Types of Biochemical Reactions
(Cont.)
Carbonyl group:
– Most of biological reactions involve polar carbonyl
group because most biological molecules contain
one or more carbonyl groups.
– The electron-poor C atom has a partial positive
charge (δ+) and the electron-rich O atom has a
partial negative charge (δ−).

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Types of Biochemical Reactions
(Cont.)
Nucleophiles (Nu):
– Are negatively polarized, electron-rich atoms
that can form a bond by donating a pair of
electrons to an electron-poor atoms.
E.g., include hydroxide ion, alkoxides, or ionized
carboxylates, thiolates, carbanions, deprotonated
amines, and the imidazole side chain of histidine.

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Types of Biochemical Reactions
(Cont.)
Electrophiles:
– Are positively polarized, electron-poor atoms
that can form a bond by accepting a pair of
electrons from an electron-rich atoms.
E.g., includes protonated imines, phosphate
groups, and protons.

Appling, Dean, R. et al. Biochemistry: Concepts and Connections. (2nd Edition), 2018.

20
Types of Biochemical Reactions
(Cont.)
Nucleophilic substitution reaction:
One nucleophile replaces a second
nucleophile.
The best leaving nucleophilic groups are
those that are stable as anions.
Halides (e.g., CL−, Br−, and I−) and the
conjugate bases of strong acids (e.g., PO43−)
are good leaving groups

21
Types of Biochemical Reactions
(Cont.)
Nucleophilic addition reactions:
– The addition of nucleophilic atoms to carbonyl
carbon of aldehydes and ketones.
– Carbonyl carbon in aldehydes and ketones is
bonded to C and H atoms that are not best
leaving nucleophilic groups.
– Carbonyl groups typically undergo
nucleophilic addition reactions instead of
substitution reactions.

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Types of Biochemical Reactions
(Cont.)
Carbonyl condensation reactions:
– Forms new C-C bond between a carbonyl
carbon of one reactant and the α carbon of
another carbonyl molecule.
– If the second carbonyl is an aldehyde or
ketone, the reaction is called an aldol
condensation.
If the second carbonyl is an ester, then the
reaction is called a Claisen condensation.

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Types of Biochemical Reactions
(Cont.)
Elimination reactions:
– The removal of two atoms (substitutes) from a
molecule to form a C=C bond.
– The most common elimination mechanism
involves a carbanion intermediate produced
by the lose of OH− to form the C-C double bond
(where X=OH).

Appling, Dean, R. et al. Biochemistry: Concepts and Connections. (2nd Edition), 2018.

24
Types of Biochemical Reactions
(Cont.)
Oxidation-reduction (redox) reactions:
– Energy producing reactions in most cells
involving oxidation of energy molecules like
glucose.

– A reversible electron transfer reaction from an
electron donor (the reductant) to an electron
acceptor (the oxidant).

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 Metabolic Control Mechanisms

Living cell uses different metabolic control
mechanisms, and these includes:
– Control of enzyme level
– Control of enzyme activity:
Substance concentration
Allosteric control
Covalent modification of enzymes
– Compartmentation
– Hormonal regulation
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 Metabolic Control Mechanisms
(Cont.)
Control of enzyme level:
– Enzyme levels in a cell may change in
response to changes in metabolic needs.
– Enzyme induction: the synthesis of an
enzyme increases in a response to the
appearance of its substrate.
– Enzyme repression: the termination of
enzyme synthesis in a response to the
presence of end products of a metabolism.

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 Metabolic Control Mechanisms
(Cont.)
Substance concentration:
– Substrates are usually present within cells at
concentrations lower than the KM values for
the enzymes that act on them.
– KM (Michaelis constant) value refers to the
concentration substrate at which half of the
enzyme active sites are saturated.
– This means, reaction velocities respond to
small changes in substrate concentration.

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 Metabolic Control Mechanisms
(Cont.)
​Substances that block enzyme activity are
called inhibitors.
– Competitive inhibitors are shaped such that
they fit into an enzyme’s active site and
prevent the normal substrate from binding.
Permanent inhibitors results in permanent loss of
enzymatic activity
Reversible inhibitors cannot cause permanent
loss of enzymatic activity and can be overcome by
an increase in the [substrate molecules].
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 Metabolic Control Mechanisms
(Cont.)
​Competitive inhibition of enzyme activity:

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 Metabolic Control Mechanisms
(Cont.)
​Reversible inhibition of enzyme activity:

31
 Metabolic Control Mechanisms
(Cont.)
Non-competitive inhibitors:
– Do not attach to the active site but instead
bind to an allosteric site on the enzyme.
– Alters the shape of the active site so that
enzymatic activity is reduced or blocked
completely.
– Some enzymes have some inhibitory sites
and activation sites to regulate enzyme
function precisely.
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 Metabolic Control Mechanisms
(Cont.)
Allosteric site control:
– An enzyme can be activated or inhibited by
binding to allosteric effectors at allosteric site
of an enzyme.
– Allosteric sites are a region on enzyme that are
located away from the active site of the enzyme.
– The binding of allosteric effectors to an
allosteric site causes the enzyme’s active site
to change shape and become active.

33
 Metabolic Control Mechanisms
(Cont.)
Covalent modification of enzymes:
– Covalent modification of enzyme is the
addition or removal of atoms or molecules
from or to the enzymes one or more amino
acids.
– The addition or removal of atoms or
molecules regulate the enzyme activity.

34
 Metabolic Control Mechanisms
(Cont.)
Covalent modification of enzymes:
– Phosphorylation or dephosphorylation: the
addition or removal of a phosphate group.
– Adenylylation: the transfer of an adenylate
from ATP.
– ADP-ribosylation: the transfer of an ADP-
ribosyl from NAD+.
– Acetylation: the transfer of an acetyl group
from acetyl-coenzyme A.

35
 Metabolic Control Mechanisms
(Cont.)
Compartmentation: division of labor
– Enzymes that participate in the same
metabolic mechanisms are localized to a
particular compartment within the cell.
– For example,
RNA polymerases are found in the nucleus and
nucleolus, where DNA transcription occurs,
Enzymes of the citric acid cycle are all found in
mitochondria where citric acid cycle occurs.

36
Compartmentation: Division of
Labor

Appling, Dean, R. et al. Biochemistry: Concepts and Connections. (2nd Edition), 2018.
37
 Metabolic Control Mechanisms
(Cont.)
Hormonal regulation:
– Are mechanisms that dispatch messages to
regulate metabolic mechanisms.
– The process of transmitting and receiving
such messages and then responding with
metabolic changes is called signal
transduction.
Hormones are one type of messengers that
interact with specific receptors to cause specific
metabolic changes in the target cell.

38
 Reference
Appling D. R., Anthony-cahill S. J., & Mathews C. K. (2018). Biochemistry: Concepts and Connections.

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