computer-aided drug design Flashcards
1
Q
ligand-based methods
A
- list of molecules known to have some activity
- sometimes also inactive ones
- develop QSAR models
- screen QSARs and test for activity
- evaluate best hits
2
Q
QSAR
A
- quantitative structure activity relationship
- linear or 3D
- equation connecting chemical structure to biological activity
- uses experimental data and set of variables to describe structure
3
Q
use of QSAR models
A
- establish correlation between activity and properties of drugs
- determine contributions of properties
- predict activity of untested drug molecules
- only work on congeneric datasets
- common core and different substituents
- not scaffold hopping
4
Q
3D QSAR
A
- superposed set of molecules
- comfa program
- use steric relationship between pharmocophore and ligand
- correlation between 3D structure of set of molecules and activity
- limited to similar molecules
5
Q
cresset
A
- determines where receptor-interacting features are likely to be
- decide which ligand shape fits best
- use in 3D QSAR to generate new molecule and evaluate
- need shape of field and molecule
6
Q
INDDEx
A
- 3D QSAR method
- series with known activity
- fragment into substructures
- ML to derive rules for QSAR
- logic-based
- molecule is active if:
- positive charged centre
- sp2 orbital nitrogen 5.2A away
- better than equation
- molecule is active if:
7
Q
ligand based screening
A
- use QSAR to find new active molecules
- create QSAR for set with known activity
- build chemical library of possible molecules for testing
- take each QSAR in set and predict those likely to be high scoring
- test for activity
8
Q
ligand based screening
small molecule databases
A
- ZINC
- mathematical library of 20m molecules
- 10m drug like (worth screening)
- databases store:
- molecule formula and 3D coordinates of lowest energy structure
9
Q
ligand based screening
evaluation
A
- training data and QSAR
- from zinc take out molecules you’ve learnt on
- distinct training and testing set
- test best hits
- top of list has good number of active molecules
- is this by chance?
- how many times better than by chance are these molecules here?
- enrichment factor
10
Q
DUD
A
- database of useful decoys
- 40 typical drug targets
- each has <500 active molecules
- 500 - 15,000 inactive decoys
- provides challenging testing set
- decoys:
- similar MW and number of H bonds
- focused and difficult to test on
- if successful here the program is powerful
- don’t waste time on easy areas
11
Q
enrichment factor
A
- (no of actives in top X%/total in top X%)/(total no actives/total no of molecules)
- ie fraction of actives in top X% divided by fraction actives in whole set
12
Q
ligand and receptor docking
A
- when receptor structure known but ligand unknown
- docking algorithm
- can consider all locations or restrict to a binding site/pocket (e.g. enzyme)
- ideally want to minimise number of molecules to test
13
Q
docking algorithm
A
- explore internal rotatable ligand bonds
- may not always adopt lowest energy conformation once bound
- sample range of favourable conformations upon docking
- not lock and key
- protein side chains can rotate
- some algorithms alter main chain too
14
Q
ligand receptor docking
workflow
A
- get structural info
- px/NMR
- homology modelling (if high identity, esp at active site)
- identify potential binding regions
- generate ligand-protein conformations
- identify preferred binding conformations
- optimise conformations and score
15
Q
docking
degrees of freedom
A
- with rigid body docking:
- 6 DoF
- free movement around an axis
- translaitonal and rotational freedom
- flexible docking:
- many more DoFs to search
16
Q
FPOCKET
A
- narrows down search by pcoket identification
- most active sites on largest surface cleft
- alpha spheres that touch 4 protein atoms
- flatter surface gives larger sphere
- search for cluster of spheres of the right size to identify pockets
- put coordinates into server tp determine pocket location
17
Q
docking
scorig
A
- different methods consider different features
- VDW and electrostatics
- hydrophobic effect
- simple schemes based on no of contact between different atom types
- e.g. methyl with methyl
- derived empirically by counting how many times this occurs
- favourable score if often
- more lenient
18
Q
AutoDock vina
A
- simplified scoring function
- models steric, hydrophobic and H bonding
- allows rotation of bonds in ligands and side chains
- not main chain
- dock in 10 mins
19
Q
virtual screening/docking
benchmarking
A
- how many hgihs coring molecules are active
- dock ligand to protein and create series of poses
- each has associated score
- test each one
- how close to px structure is best scoring pose
- how close are top 10 scoring poses
- improves prediction quality
- involve EFs
- highest fold improvement at 0.5% EF
- predict binding affinities
20
Q
docking
limitations of evaluation
A
- target protein structure is in correct conformation for docking
- don’t know the structure after docking
- unrealistic scenario
- don’t know the structure after docking
- overcome with blind trials
- dock into closed conformation (bound to a different ligand)
- evaluate correlation of predicted and actual binding affinity
- still can’t cover all 1 billion molecules
- 1 million/day
21
Q
known docked structures
process
A
- solve structure series of protein and ligand docked
- examine computationally with molecular graphics
- detailed energy calculations
- VDW, electrostatics
- map pharmacophore to suggest substitutions
- suggest ligand modifications to alter binding
- explore different ligands with docking
- e.g. gleevec (leukaemia)
22
Q
allosteric modulation
A
- recent method of interest
- drug in active site = orthosteric
- but modulators can bind distal sites = allosteric
- opens up drug space
- high specificity
- surface more variable
- can modulate
23
Q
current status
A
- chemical HTS
- docked structures successfully solved
- docking for suggesting inhibitors
- ligand based screening complements
