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Doug Brutlag 2011 Genomics, Bioinformatics & Medicine Drug Development

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Presentation on theme: "Doug Brutlag 2011 Genomics, Bioinformatics & Medicine Drug Development"— Presentation transcript:

1 Doug Brutlag 2011 Genomics, Bioinformatics & Medicine http://biochem158.stanford.edu/ http://biochem158.stanford.edu/ Drug Development http://biochem158.stanford.edu/Drug-Development.html Doug Brutlag Professor Emeritus of Biochemistry and Medicine brutlag@stanford.edu

2 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Drug Discovery Animal Studies Clinical TestsCommercialization Courtesy of Doug Kalish

3 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Building a library of gene/protein (genome/proteome) sequences to mine for information Courtesy of Doug Kalish

4 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Look for proteins or mRNA expressed (or not expressed) in a disease. Comparative gene expression assays, Comparative proteomic profiles. Look for genes/proteins essential for infectious agent and distinct from host genes/proteins. Look for genes and gene modifications associated with a disease. Look for proteins or protein modifications associated with a disease. Find regulatory pathways required for disease process. Courtesy of Doug Kalish

5 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Molecular level Screen enzyme inhibitors or activators Cellular Level Verify the involvement of the protein in the disease state (often use gene silencing siRNAs). Understand the protein pathways and interactions. Organismal level Verify critical nature of target and uniqueness. Courtesy of Doug Kalish

6 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Discover leads that affect the target gene, protein or pathway Inhibit defective protein Activate a defective protein Inhibit expression of a protein/pathway Activate expression of required protein/pathway Stimulate protein modifications or cellular location Courtesy of Doug Kalish

7 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Evaluate leads to ‘cure’ the problem, e.g.: Replace missing or defective protein with gene therapy Anti-sense or siRNA to prevent protein expression Antibody to remove or inhibit protein target Stimulation of synthesis to replace or activate protein Stimulate protein modification or location Courtesy of Doug Kalish

8 Doug Brutlag 2011 Drug Discovery Methods Screening natural compound collections Courtesy of Doug Kalish

9 Doug Brutlag 2011 Natural Compound Collections

10 Doug Brutlag 2011 Natural Compound Library Screening

11 Doug Brutlag 2011 Drug Discovery Methods Screening natural compound collections Screening corporate compound collections In silico screening (Autodock) Courtesy of Doug Kalish

12 Doug Brutlag 2011 In silico screening with Autodock Gleevec (Imatinib) bound to BCR-Abl Protein

13 Doug Brutlag 2011 Drug Discovery Methods Screening natural compound collections Screening corporate compound collections In silico screening (Autodock) Rational drug design Courtesy of Doug Kalish

14 Doug Brutlag 2011 Rational Drug design for HIV Protease

15 Doug Brutlag 2011 Rational Drug Design for HIV Protease Indinavir bound to HIV Protease Resistance mutations shown in red and purple

16 Doug Brutlag 2011 Drug Discovery Methods Screening natural compound collections Screening corporate compound collections In silico screening (Autodock) Rational drug design Combinatorial chemistry Courtesy of Doug Kalish

17 Doug Brutlag 2011 Combinatorial Chemistry

18 Doug Brutlag 2011 Resin Linker with Code Blocks and Light Sensitive Cleavage sites

19 Doug Brutlag 2011 Combinatorial Chemistry

20 Doug Brutlag 2011 Privileged Scaffolds

21 Doug Brutlag 2011 Drug Discovery Methods Lead Discovery o Screening natural compound collections o Screening corporate compound collections o In silico screening (Autodock) o Rational drug design o Combinatorial chemistry Lead validation Lead optimization Courtesy of Doug Kalish

22 Doug Brutlag 2011 ADMET: Ideal Properties of Drugs Absorption - Passes GI track into blood stream Distribution - Gets to target tissue (blood brain barrier) Metabolism – Not readily metabolized Excretion – Not readily secreted Toxicity – Not toxic to other cells or tissues Courtesy of Doug Kalish

23 Doug Brutlag 2011 Chris Lipinski’s Rule of Five Lipinski and his Pfizer co-workers looked over a data set of drug candidates and noticed that there were some reasonably clear cutoffs for oral absorption and general cell permeability. They suggested that you need: 1. Fewer than five hydrogen bond donors (which can be estimated by counting the total number of OH and NH groups in the molecule.) 2. Fewer than 5 hydrogen-bond acceptors (estimated by the total of N and O atoms in the molecule.) 3. A molecular weight of less than 500 4. A partitioning coefficient (logP) of less than 5 The “rule of five” name came from the cutoffs all being multiples of five, in case you are wondering why there are only four rules. Courtesy of Doug Kalish

24 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Animal tests of toxicity and efficacy of therapy Rodents (mice and rats) Mammals (pigs) Primates (monkeys and chimpanzees) Mouse Lemurs (Microcebus) Courtesy of Doug Kalish

25 Doug Brutlag 2011 The New Primate: Mouse Lemurs (Microcebus margotmarshae)

26 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution Small group of healthy volunteers (10’s) to determine safety and toxicity. Maybe some members of target group Courtesy of Doug Kalish

27 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution 100’s of patient population to determine efficacy, dosage, safety Courtesy of Doug Kalish

28 Doug Brutlag 2011 The Pharma Value Chain Gene or Genome Sequencing Target Validation Target Discovery Lead Discovery Pre- Clinical Manufac -turing Clinical Phase I Clinical Phase II Clinical Phase III Distribution 1000’s of patients and controls (normals) to determine efficacy, dosage, safety, side effects, and interactions. Each prospective patient group (men, women, children, elderly and ethnic groups) Courtesy of Doug Kalish

29 Doug Brutlag 2011 Genetic and Biomarker Followup

30 Doug Brutlag 2011 The Impact of Genomics and Bioinformatics on Drug Discovery Times Courtesy of Doug Kalish

31 Doug Brutlag 2011 FDA Approved New Chemical Entities and Biological Derivatives Portfolio Management Solutions C. Thomas Caskey, Annu. Rev. Med. 2007. 58:1–16 Small Molecules (NCEs) Biologics (new BLAs)

32 Doug Brutlag 2011 FDA Approved New Chemical Entities and Biological Derivatives Portfolio Management Solutions C. Thomas Caskey, Annu. Rev. Med. 2007. 58:1–16

33 Doug Brutlag 2011 Short Market Time Portfolio Management Solutions C. Thomas Caskey, Annu. Rev. Med. 2007. 58:1–16

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