1. FARNESYL TRANSFERASE INHIBITORS
ANTICANCER AGENTS
FARNESYL TRANSFERASE INHIBITORS
Chapter 21

2. Ras Protein
Notes
Signalling protein that is crucial to cell growth and division
Abnormal form is present in 30% of cancers
Prevalent in colonic and pancreatic cancers
Abnormal Ras is coded by a mutated ras gene
Small G-protein
Binds GDP in resting state and GTP in active state
Active Ras normally autocatalyses hydrolysis of GTP back to GDP
Abnormal Ras fails to hydrolyse GTP
Abnormal Ras remains permanently active
Three human Ras proteins (H-Ras, N-Ras and K-Ras)

3. Farnesyl transferase Notes Zinc metalloproteinase
Catalyses attachment of a farnesyl group to Ras
Hydrophobic farnesyl group anchors Ras to the inner part of the cell membrane
Farnesylation is necessary for Ras to become activated during signal transduction
Inhibition of farnesyl transferase should inhibit this process

4. Farnesyl transferase Enzyme mechanism FTase Further processing
Methyl ester

5. Farnesyl transferase Notes
Farnesyl diphosphate (FPP) binds first to the active site
FPP aids binding of Ras protein to the active site
Magnesium and iron ions are present as cofactors
Magnesium ion interacts with the pyrophosphate group
Results in a better leaving group
Iron ion interacts with the thiol group of cysteine
Results in a better nucleophile

6. FT Substrates
Substrates share a terminal tetrapeptide moiety called the CaaX peptide
C-a-a-X
Substrate
C = cysteine
a = valine, isoleucine or leucine
X = methionine, glutamine or serine

7. FT Inhibitors Aims Good inhibitory activity vs enzyme
Ability to cross the cell membrane to reach the enzyme
Metabolic stability
Aqueous solubility
Oral absorption
Favourable pharmacokinetic properties

8. FT Inhibitors C-a-a-X Substrate C-a-Phe-X Inhibitor C = cysteine
a = valine, isoleucine or leucine
X = methionine, glutamine or serine
Notes
Inhibitors were developed to mimic the terminal tetrapeptide moiety - CaaX peptide
Tetrapeptides having Phe next to X act as inhibitors
Serve as lead compounds

9. Lead compound
Cys
Val
Phe
Met
Disadvantages
Terminal carboxylic acid likely to be ionised - bad for absorption
Peptide bonds are susceptible to enzyme-catalysed hydrolysis
Poor stability to digestive or metabolic enzymes (e.g. aminopeptidases)

10. Drug design Peptidomimetic Lead compound Peptidomimetic Peptidomimetic
Peptide bond isostere
Ester
Methylene-
amino link
Peptidomimetic
Lead compound
Cys
Val
Phe
Met
Ester
Methylene-
amino link
Peptidomimetic
Peptidomimetic
Methylene-
amino link
Peptidomimetic
Notes
Modifications carried out to remove peptide nature - peptidomimetics
Ester masks polar carboxylic acid or carboxylate ion - acts as prodrug
Methyleneamino link replaces N-terminal peptide bond
Methyleneamino link introduces a resistance to aminopeptidases
Peptide bond isostere introduced to mimic central peptide bond
Isostere should be capable of mimicing any binding interactions
Isostere should be stable to enzyme-catalysed hydrolysis

11. Examples of FT Inhibitors
Peptide bond
isostere
Stable methylene-amino link
Stable methylene-amino link
Terminal
amino group
Thiol
Aromatic
substituent
R=H FTI 276
R=iPr FTI 277
Notes
Thiol group forms important interactions with the zinc ion cofactor
Methyleneamino link is stable to aminopeptidases
Aromatic substituent is important for inhibitory activity
Aromatic ring acts as a peptide bond isostere
Terminal amino group is ionised
Terminal amino group forms an ionic bond to the phosphate group of FPP
Terminal carboxylate group is important to binding

12. Stable methylene-amino link
Examples of FT Inhibitors
Peptide bond
isostere
Stable methylene-amino link
Sulfone
Aromatic
substituent
Terminal
amino group
Thiol
R=H L739750
R=iPr L744832
Notes
Thiol group forms important interactions with the zinc ion cofactor
Methyleneamino link is stable to aminopeptidases
Aromatic substituent is important for inhibitory activity
Methyleneoxy group acts as the peptide bond isostere
Terminal amino group is ionised
Terminal amino group forms an ionic bond to the phosphate group of FPP
Terminal carboxylate group is important to binding
Sulfone increases activity over a methylthio group

13. Examples of FT Inhibitors
Peptide bond
isostere
Masking group
AZD-3409
Masking group
AZD-3409
AZD-3409
Pyrrolidine
Aromatic substituent
Notes
Thiol and carboxylic acid groups are both masked in the prodrug
Lowers the toxicity risk of the thiol group
Protects the thiol from possible metabolism
Pyrrolidine ring introduces conformational rigidity
Potent inhibitor (Ki < 1 nM)
Also inhibits geranylgeranyltransferase - catalyses prenylation with geranylgeranyl diphosphate
Agents inhibiting both enzymes are potentially advantageous

14. Examples of FT Inhibitors
Imidazole ring
Structure I
IC nM
Structure I
IC nM
Notes
Non-peptide inhibitor
Imidazole ring acts as the zinc ligand
Decreases the risk of toxicity due to a free thiol group

15. Examples of FT Inhibitors
Lonafarnib
IC nM
Notes
Non-peptide inhibitor
Developed from lead compound discovered by screening compound libraries
10,000 times more active than the lead compound
No ligand for the zinc cofactor is present!

16. Examples of FT Inhibitors
Lonafarnib
IC nM
Imidazole
ring
Steric
shield
Sch
IC nM
Steric
shield
Sch
IC nM
Sch
IC nM
Non-peptide inhibitor
Developed from lonafarnib by structure-based drug design
Imidazole ring introduced as zinc ligand
Aromatic ring introduced as a steric shield vs metabolism

17. Development of Tipifarnib
Imidazole
Quinolone
I; IC nM
I; IC nM
Lead compound
Identified from screening compound libraries
Imidazole ring present - zinc ligand
Both aromatic rings are important to activity

18. Development of Tipifarnib
Imidazole
Quinolone
I; IC nM
II; IC50 35 nM
Strategy - variation of substituents
Activity increases with introduction of meta-chloro substituent

19. Development of Tipifarnib
Imidazole
Quinolone
I; IC nM
III; IC50 15 nM
II; IC50 35 nM
Strategy - variation of substituents
Activity increases with addition of N-methyl substituent

20. Strategy - variation of ring substitution Activity increases
Development of Tipifarnib
Imidazole
Quinolone
I; IC nM
II; IC50 35 nM
III; IC50 15 nM
IV; IC nM
Strategy - variation of ring substitution
Activity increases

21. Development of Tipifarnib
Imidazole
Quinolone
I; IC nM
III; IC50 15 nM
II; IC50 35 nM
Tipifarnib; IC nM
Extension strategy
Extra functional group
Extra binding interactions
Activity increases
IV; IC nM

22. FT-Inhibitors show potential as anticancer agents
Other Factors
Notes
FT-Inhibitors show potential as anticancer agents
Anticancer activity may not necessarily be due solely to FT-inhibition
FTIs inhibit farnesylation of H-Ras, N-Ras and K-Ras
But N-Ras and K-Ras can by prenylated by GGTase
GGTase provides alternative mechanism of attaching Ras to cell membranes
FTI’s still have anticancer activity in cells expressing excess K-Ras
Inhibition of FT may affect other cellular processes other than Ras