CHEM30111 Lecture 1 Handouts - Organic Cofactors PDF

Summary

This document is a lecture handout on organic cofactors in biocatalysis. It covers definitions, roles, structure-function relationships, and different types of cofactors. The lecture also emphasizes the importance of organic cofactors in enhancing enzyme activity and specificity. The handout includes examples and comparisons of cofactors.

Full Transcript

CHEM30111, Lecture 1:
Overview & Introduction
Organic Green
cofactors chemistry
applications
What are
they? Bio-
What is their inspired/
role? biomimetic
How do they catalysis
function? Electron density for enzyme
bound cofactor PLP and
substrate

1
Why should we care?

2
 Syllabus & ILOs
Definition and overview of organic cofactors (Lect 1)
Covalent catalysis by PLP/TPP (Lect 2-3)
Workshop (Lect 4)
Redox catalysis by FAD/FMN/NAD(P)H (Lect 5-6)
Workshop (Lect 7)

ILO1 – Describe the role of organic cofactors in biocatalysis and identify
various cofactors based on their structure
ILO2 – Explain how the structure of organic cofactors is tailored to the
corresponding biocatalytic function
ILO3 – Evaluate the effect(s) on protein binding and/or biocatalytic function
of cofactor structure modifications
ILO4 – Rationalise the component steps in mechanisms of covalent
catalysis by PLP/TPP and highlight aspects under enzyme control
ILO5 – Rationalise the component steps in redox mechanisms catalysed by
FAD/FMN/NAD(P)H and highlight aspects under enzyme control

3
 Enzymes, proteins & amino
acids
Substantial rate
enhancement, often >>
105

Regio- and stereo-selective

Operate under narrow
window of ambient
conditions (i.e. pH,
temperature, solvent etc)
Activity often highly
dependent on conditions

Relatively narrow substrate
specificity
Vast majority is protein
based 4
 Enzymes, proteins & amino
acids
Proteins are
polypeptides
Majority has a defined
3D-structure linked to
function
Structure only stable
under a narrow window
of ambient conditions
(i.e. pH, temperature,
solvent etc)
Sequence governs
structure/function
20 amino acids,
average protein ~300
amino acids
20300 sequences!!!
5
 Enzymes, proteins & amino
acids
Proteins are flexible
Considerable flexibility in the
structure, often also linked to
(catalytic) function
Sequence governs
structure/function and thus
also the dynamic behaviour

Recap on proteins:

https://www.youtube.com/watch?
time_continue=3&v=wvTv8TqWC48

6
 Enzymes, proteins & amino
acids
20 amino acids
Diverse set of chemical functionalities
But limited to acid/base or weak
nucleophiles

s
nucleophilie
Weak
No electrophiles
Little scope for redox chemistry
(exception is disulphide formation), or
radical chemistry

Hence for ~50% of enzymes:
Recruitment of additional chemical

electrophiles
Weak
functionality through (non)-covalent
binding of (in)organic cofactors/metal
ions or, on more rare occasions,
chemical modification of amino acids.

Binding/cofactor specificity is property
of protein structure/sequence

Enzyme will exploit synergy between 7
 Cofactors, coenzymes & prostetic groups
Definition of cofactors: any non-protein substance required for an
enzyme to be
catalytically active.

Some cofactors are inorganic, such as metal ions in various
oxidation states. Others, such as most vitamins, are organic
molecules. Cofactors are either bound tightly or may be loosely
associated with the enzyme. They may also be important for
structural integrity, i.e. in their absence the enzyme does not
Organic
fold properly
Inorganic or becomes unstable.
In/Organic

A 4Fe4S cluster, bound by 4 Cys A heme cofactor, consisting of a The flavin cofactor FAD
residues central Fe bound by a tetrapyrrol
8
ligand
 Cofactors, coenzymes & prostetic groups
Hence, not all cofactors are directly involved in catalytic
mechanism! To exclude a pure allosteric mode of action,
coenzymes are defined as cofactors that must be present in the
active (i.e. substrate binding) site of an enzyme.

Active
Example:
site/Substrate
binding site

prFMN

K+

Metal
binding Mn2+
site

Activity is prFMN dependent,
Activity is Mn2+ and K+
and this cofactor is
dependent, but neither
responsible for the key
involved in chemistry, role is
chemistry, so this is a
to aid in prFMN binding, so
coenzyme in this case 9
cofactors, but not
 Cofactors, coenzymes & prostetic groups

We can also further differentiate between coenzymes, which
bind to an enzyme at the beginning of a catalytic cycle and
leave the active site afterwards, and prosthetic groups,
which are tightly bound within an enzyme and remain there
throughout many reaction cycles.
Examples:

prFMN

K+

Metal
binding Mn2+
site

In this system, the FMN flavin cycles The prFMN coenzyme
between two protein components, remains bound throughout
per total reaction cycle, and is thus a multiple cycles: prosthetic
coenzyme for the luciferase but not a group
 Organic cofactors: overview
A complete overview of organic
cofactors:

Too many to cover in one 7 lecture unit!!!
We will mainly focus on 4 cofactors : PLP, TPP, the flavins FMN and FAD
and NAD(P)H 11
 Organic cofactors: overview
Focus on 4 cofactors : PLP, TPP, the flavins FMN/FAD and NAD(P)H

PLP (pyridoxal
phosphate)

FMNH2 (flavin
mononucleoti
de)

TPP (thiamine
pyrophosphate) NAD+ (nicotinamide
Anything these have in common? dinucleotide 12
 Organic cofactors: overview
Focus on 4 cofactors : PLP, TPP, the flavins FMN/FAD and NAD(P)H

PLP (pyridoxal
phosphate)

FMNH2 (flavin
mononucleoti
de)

TPP (thiamine
pyrophosphate) NAD+ (nicotinamide
Why so large/complex? dinucleotide 13
 Organic cofactors: overview
Focus on 4 cofactors : PLP, TPP, the flavins FMN/FAD and NAD(P)H

PLP (pyridoxal
phosphate)

FMNH2 (flavin
mononucleoti
de)

TPP (thiamine
pyrophosphate) NAD+ (nicotinamide
Can you highlight the most reactive dinucleotide 14
positions?
15
 Organic cofactors: overview
phosphate groups appear in all, most also have aromatic systems (ie
largely 2D)

PLP (pyridoxal
phosphate)

FMNH2 (flavin
mononucleoti
de

TPP (thiamine
pyrophosphate) NAD+ (nicotinamide
dinucleotide 16
 Organic cofactors: overview
Active groups only form part of (much) larger entities… why?

PLP (pyridoxal
phosphate)

FMNH2 (flavin
mononucleoti
de

TPP (thiamine
pyrophosphate) NAD+ (nicotinamide
The most reactive positions highlighted dinucleotide 17
in blue
 Analogy: Cofactors as tools
X Acts on Y
using tool

Business
end/actual
tool

Handle

Tool specific
Handle!
18
 Organic cofactors
Structure is linked to activity
Group transfer, Redox active/group Redox active,
amine substrates transfer hydride transfer

PLP (pyridoxal
phosphate)

FMN (flavin
mononucleoti
de

TPP (thiamine
Grouppyrophosphate)
transfer, NAD+ (nicotinamide
carbonyl substrates dinucleotide 19
 Many cofactors are vitamins
Redox active,
Group transfer, Redox active/group
hydride transfer,
amine substrates, transfer, Vit B2
Vit B3
Vit B6

Vitamins are inactive precursors,
requiring modification to create suitable
“handle” and or activate the reactive
group.
Group transfer,
carbonyl substrates,
Vit B1 20
 Cofactor binding and activity
control
sit tive
Ac
e

21
 Cofactor binding and activity
control

Adaptive radiation of
finches (Darwin): beak
shape adapts to food
source
Enzymes evolve too: grey is cofactor
binding, red area controls substrate
binding and chemistry. 22
 Cofactor binding and activity
control

Enzymes often evolve as modular entities: red region has
become more diversified, leading to diverse chemistry
when considering a family of enzymes. Ie the active site 23
adapts to the substrate
 Studying Cofactor binding
proteins:
Spectroscopy, Structural biology

UV-Vis spectroscopy allows
direct monitoring of chemical
state of most cofactors

Why only possible to
observe/study above
300nm? 24
25
Cofactor versus protein

Protein absorbs <
300nm!

Similar problems with 1D NMR, IR,
protein effectively shields most
spectral features from the cofactor
26
 Studying Cofactor binding
proteins:
Spectroscopy, Structural biology
Working well are UV-Vis (> 300nm); mass spectrometry,
fluorescence, EPR

27
 Studying Cofactor binding
proteins:
Spectroscopy, Structural biology

Often in
conjunctio
n with Mechanistic
crystal interpretati
spectrosco on
py 28
 Studying Cofactor binding
proteins:
Spectroscopy, Structural biology

29
 Recap
Organic cofactors

What are they? Small
organic molecules (many
also vitamins) bound by
enzymes
What is their role? Provide
additional key chemical
functionality required for
function/catalysis
How do they function?
Electron density for enzyme
bound cofactor PLP and
substrate: The synergy of an

Protein able to control enzyme–cofactor
system enables a functional
level that could not be
activity and ensures achieved by
the cofactor or the enzyme
30
Next lecture: PLP chemistry

31
 Any questions?

[email protected]

Please put CHEM30111 in the email
header

32