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SY – Master Presentation Bioinformatics and Synthetic Biology Lab., KAIST Multi-Model, Multi-Omics Convergence in Drug Discovery2 Link Clinical Phenotype, Animal Model Phenotype and Cell System Phenotypes with Advanced Cell Function Assay System and Omics Marker oriented Bioinformatics Bioinformatics and Synthetic Biology Lab., KAIST Cell Function Assay based Disease Profiling Efficacious Disease Phenotypes Bioinformatics and Synthetic Biology Lab., KAIST 3 Cell Oriented Multi Dimensional Omics Marker Mapping 4 Animal Disease Model Marker Expression Profile Link Clinical Omics Marker, Animal Model Omics Marker and Cell System Omics Marker with Multi-Omics Integration Strategy Multi-Omics Integration & Multi Dimension Correlation Patient Clinical Marker & Omics Marker Expression Profile Bioinformatics and Synthetic Biology Lab., KAIST Disease Cell Model System Marker Expression Profile Technological Mission Overview Computational Research Feature Extraction & Feature Mapping Feature Extraction Algorithms Drug Synergism Prediction HT Cell Image Analysis Omics Integration and Model Generation Pharm.-pore Screen & 3D Dock Pursuit of Expertise HT-Experiments HCS - Phenome Analysis MCMT Drug Discovery Drug Research Bioinformatics and Synthetic Biology Lab., KAIST 5 Multi Dimensional Fat Cell Biology for T2DM Drug Discovery Literature Survey Browning Literature Survey Animal and Clinical Studies Literature and Trend Survey (Basic Knowledge & Cell Assays) Fat Cell Controlling Agents Discovery Knowledge Build up T2DM Bioinformatics (Patient Sample & Animal Model Fat Cell Bioinformatics (Expression Marker & Controlling Agents) Fat Cell HCS (Assay Systems and Bio-image Informatics) HCS based Phenotype Discovery Bioinformatics and Synthetic Biology Lab., KAIST Fat-Cell Bioinformatics 6 Type 2 Diabetes Mellitus Drug Discovery: Case Studies 7 Drug Discovery Case Studies • JNK-JIP Inhibitor: BI-78D3 • PPARg ligand blocker: SR1664 • PPARg agonist: Harmine • GLP-1R G-protein-biased agonist: P5 • Browning Agent: R406 Multi-target/Multi-Component Drug discovery • Horizon Discovery • OncoReference Data Set • Chalice Analyzer • Dream Challenge • Dream NCI • Dream AstraZeneca Fat Cell Disease Model - Regulatory Network Learning • Dream Challenge 8 Bioinformatics and Synthetic Biology Lab., KAIST Type 2 Diabetes Mellitus Drug Discovery: Case Studies 8 High-throughput Phenotype Screening for T2DM Drug Discovery Bioinformatics and Synthetic Biology Lab., KAIST 9 Bioinformatics and Synthetic Biology Lab., KAIST Type 2 Diabetes Mellitus Drug Discovery: Current Practice10 1. Metabolic Disease Drug Discovery—‘‘Hitting the Target’’ Is Easier Said Than Done, Cell Metabolism, 2012 2. Suneng Fu et al., Phenotypic assays identify azoramide as a small-molecule modulator of the unfolded protein response with antidiabetic activity, Sci. Trs. Med., 2015 3. Disease Modeling and Phenotypic Drug Screening for Diabetic Cardiomyopathy using Human Induced Pluripotent Stem Cells, Cell Reports, 2014 4. Autocrine selection of a GLP-1R G-protein biased agonist with potent antidiabetic effects, Nat. Comm., 2015 Bioinformatics and Synthetic Biology Lab., KAIST Diet and Fat Metabolism Free Fatty Acids, FFA Monoglycerides Triglyceride, TG Lipase 11 + Dietary Fat Chylomicrons Bioinformatics and Synthetic Biology Lab., KAIST Fat Storage and Release Bioinformatics and Synthetic Biology Lab., KAIST 12 Energy Metabolism Bioinformatics and Synthetic Biology Lab., KAIST 13 Lipolisys Bioinformatics and Synthetic Biology Lab., KAIST 14 Lipolisys 15 The different shades of fat Vivian Peirce, Stefania Carobbio & Antonio Vidal-Puig Nature 510, 76–83 (05 June 2014) doi:10.1038/nature13477 Bioinformatics and Synthetic Biology Lab., KAIST Fatty Acids, Glycerol and Trigrycerides Stearic Acid – saturated fatty acid Esterification RCO2H + R’OH RCO2R’ + H2O 3SA + 1G 1TG + 3H2O Triglyceride Bioinformatics and Synthetic Biology Lab., KAIST 16 Mono, di, and triglycerides Monoglyceride Diglyceride Triglyceride Bioinformatics and Synthetic Biology Lab., KAIST 17 Historical Perspectives in Fat Cell Biology Bioinformatics and Synthetic Biology Lab., KAIST 18 History of Fat Cell Biology 19 Around beginning of the 20th century, adipose tissue was considered to be a connective tissue filled with droplets of fat. Adipose tissue was believed to be limited in the body to an insulating role against heat loss and to provide mechanical support for certain tissues. In the 1940s, deuterium oxide was used to study the conversion of carbohydrates to fatty acids. Shapiro and Wertheimer (1948) showed conversion of carbohydrates to fat in adipose tissue and the direct effect of insulin on the transformation of glucose into fatty acids. They proposed that adipose tissue was metabolically active and that deposition and mobilization of fat are regulated by nervous and endocrine factors. In 1965, over 4,000 references on adipose tissue was published in handbook of physiology Bioinformatics and Synthetic Biology Lab., KAIST History of Fat Cell Biology 20 In the 19th Century, discovery of adipocyte In 1957, Two major fat cell types – white and brown cells were discovered In 1957, Study of histology of adipose tissue • Histology of adipose tissue is similar in several species • Morphologies of developing white fat and brown fat are similar • During the differentiation of white fat, the cells go through a stage (e.g., multilocular stage) that, at the level of light microscopy, has the morphological appearance of brown fat cells. Bioinformatics and Synthetic Biology Lab., KAIST 연구요약 21 신규 당뇨 약물 발굴 기법 개발 1. Literature Survey I. II. 당뇨 연구 동향 신규 당뇨 치료 기전 발굴 <RYGB에 의한 당뇨 치료기전 연구> 1. Literature Survey 당뇨 약물 개발 동향 I. RYGB에 의한 당뇨 치료 III. 당뇨 약물 발굴 기법 동향 II. RYGB에 의한 당뇨 치료 기전 연구 2. 신규 당뇨 약물 표적발굴 Scheme 3. Current Status 2. Network 기반 RYGB Induced 당뇨 치료 기전 발굴 연구 Scheme 3. Current Status <BAT 분화 촉진 약물 발굴> <BAT Thermogenesis에 의한 당뇨치료> 1. 1. Literature Survey Literature Survey I. Biology of FAT 연구 동향 I. Biology of FAT 연구 동향 II. Beige Adipocyte 분화 관련 연구 동향 II. Beige Adipocyte 분화 관련 연구 동향 2. WA to BA 분화 약물 발굴 연구 Scheme 3. Current Status 2. Network 기반 WA to BA 분화 마커 발굴 연구 Scheme 3. Current Status 신규 당뇨약물 표적발굴 Bioinformatics and Synthetic Biology Lab., KAIST 당뇨 연구동향 23 Monogenic Multi-genic, Heterogenic, Systemic One drug therapy Managing overall patient condition (body weight, personalized and combinatorial drugs usage, complications) Target specific organ Target chronic inflammation and fat accumulation Causal gene study Causal multi-factor study (genes, SNPs, microbiome, etc.) Subtyping subtypes T2DM class separation (Obesity vs non-obesity, genetic vs environmental origin of T2DM) • Li Li et al., Science translational medicine 2015 Bioinformatics and Synthetic Biology Lab., KAIST 당뇨약물 개발동향 24 Current Options • Insulin 계열 – Enhance PK properties of Insulin • Metformin 계열 – Suppressing Hepatic glucose production (target mitochondria GPD) • Sulphonylureas 계열 - Stimulate insulin release (KATP target) in Pancreas • TZDs 계열 (Glitazones) - PPARg agonist • GLP-1 and GIP – Increase insulin secretion and decrease glucagon secretion • DPP-4 Inhibitors – Inhibit degradation of GLP-1 • SGLT2 Inhibitors – inhibit glucose re-absorbption in kidney • Amylinomimetic 계열 – reducing glucagon secretion & reduces appetite (amylin analog) • Alpha-glucosidase inhibitors – inhibit starch to glucose reaction • Dopamine Agonist – Unknown, possibly regulating hepatic glucose production Combinatorial Drugs – combine drugs which have different target and mechanism • Metformin, Sulphonylureas, Tzds, and Alpha-glucosidase inhibitors • GLP and DPP-4 inhibitors • A + SGLT2 inhibitors 당뇨약물 개발동향 Clinical Trial 동향 • 세포 Signaling Target (MAPK, GPR, etc.) • TF Target (PPAR Family, RXR) • Immuno-Modulators (IL, TNF, CD protein Target) • Incretin Modulators (GLP, GIP, L-cell Target) • Diabetes-CVD Co-targeted Drugs (ACE Inhibitors, ACC Inhibitors, etc.) • Hormonal Targets (Glucagon R, Dopamine R, Serotonin R, etc.) • Enzyme Targets (GSK, GK, Hyaluronic acid, etc.) • Unusual Targets (VEGF, FGFR, Microbiome, etc.) 25 List of Candidate Targets 26 IGF-1, PTP-1B, CD3, RIP140, GCGR, HSP60, CTLA-4, FGFR-21, IL-1B, PTHR, GCCR, JNK, Antidiuretic hormone, GR, PPAR-a, PPAR-g, ACE, C-II, PR, 11beta-HSD, AMPK, MTP, ZR, CB1R, VCAM-1, SGLT-1/2, FBPase, GKA, NA, SR, DP, Beta3AR, GCP, GDIR, SIRT1, DGAT1, 5-HT2C, CB1, CCK A, PPAR-d, SGK-1, CB1R, IL-6R, CB1R/2R, Ghrelin-R, CCR2, ABC-T, IL-1R, GPR119, Sykk, Let-7, GAD, CPT-I, Hyaluronic acid, MC1R/MC4R, GP, Y2R, GPR40, NPY1, HM74a, Mnk, BAR, BMP4R-1a, Sirtuin 1, DG070, IL-1B, GSK-3, HSP65, s-EH, SCD-1, Sigma-1R, IL-18, Amylin and leptin R, CD80, CD86, CD52, MNC4 R, MetAP2, NNR-alpha7, ACC, RXR, GPR120, C-peptide R, Calcitonin R, EGFR, Gastrin R, VEGF-B, ApoA-1, ACL, NK cell R, SERCA2b, IBAT, TGR5 in L cells, CD28, MCH R, IL-7R, IAPP, PDHK Z:\2012-21-MCMT\0-사업단\2단계공통소재\소재후보_이관수\References\기 타 Reference\Diabetes-Clinical-Trials(All).xlsx Diabetes-CVD Co-target 발굴전략 1. Constructing Diabetes Related Genetic Network 2. Constructing CVD related Genetic Network 3. Combine 2 Networks 4. Annotate the combined network with current drug options 5. Set the rule for the co-target discovery (Guilt-by-Association, Network Propagation, Context Associated Hub) 6. Searching Candidate Drug for the target 7. Experimental validation Bioinformatics and Synthetic Biology Lab., KAIST 27 Current Status Diabetes Associated Gene List – 확보 & update 중 • Diabetes associated genes (mechanistically) • Disease associated SNPs and related genes • Drug target & Drug target related genes • Z:\3-Disease\1-Diabetes-기민난영\ Disease-gene-in-T2DM.xls Network Analysis Methods • BIML 2016 Network Modeling and Analysis for Data-driven Biology 강의 수강 • Resource & Tools Study 중 • 해당 Protocol Update 예정 Bioinformatics and Synthetic Biology Lab., KAIST 28 RYGB에 의한 당뇨 치료기전 발굴 Bioinformatics and Synthetic Biology Lab., KAIST RYGB and remission of T2DM 30 After RYGB, 80% of T2DM patients show remission of T2DM (Filip K. Knop, diabetes cares, 2013) Patients who treated with insulin, After 12 month later, 62% of patients stop insulin treatment (Ali Ardestani et al, diabetes cares, 2015) Currently no clear mechanism has been proposed. There are two main arguments – food restriction and GI factors (Incretin and other GI derived hormones) There are some study also proposed microbiome effects RYGB에 의한 당뇨 치료기전 연구 31 Clinical Study • Sarah Steven et al., Diabetes Care, 2015 • Comparing between RYGB patients who have T2DM and have normal glucose tolerance. • After Surgery, weight loss was similar in two groups but physiological factors related to T2DM remarkably improved in T2DM patient group compared to NGT group. This phenotype related to decreased in pancreatic fat. • They concluded that the fall in intra-pancreatic triacylglycerol in T2DM, which occurs during weight loss, is associated with the condition itself rather than decreased total body fat. • Carsten Dirksen et al., Diabetes Cares, 2010 • Comparing peroral feeding (위를 통과하도록 관을 연결하여 영양분 주입) and gastroduodenal feeding (장까지 관을 연결시켜 영양분 주입) in T2DM patients who had RYGB • In two cases, there are no significant difference in GIP level but both beta cell function (2 fold) and GIP level (5 fold) were significantly improved than pre-operational levels. • They concluded that Improvement in postprandial glucose metabolism after gastric bypass is an immediate and direct consequence of the gastrointestinal rearrangement, associated with exaggerated GLP-1 release and independent of changes in insulin sensitivity, weight loss, and caloric restriction. Bioinformatics and Synthetic Biology Lab., KAIST RYGB에 의한 당뇨 치료기전 연구 32 Animal Study • Jibin Li et al., Molecular Medicine, 2012 • For 60 male GK rats (non obese diabetic animal model, shows spontaneous T2DM phenotype), comparing RYGB, Sham operation, and control. • After 20 to 30 days, PPARg and GLUT4 protein level increased in fat cell (site is not specified) of RYGB group compared to control group. Phosphorylation of PI3K was also increased. Instead, TNF-alpha level was decreased. • They concluded that, RYGB may improve insulin resistance and treat T2DM through upregulation of the PPARγ2 protein, downregulation of TNFα mRNA transcription, through the autocrine pathway, upregulation of PI3Kp85α expression, upregulation of GLUT4 mRNA transcripts and by inducing translocation of GLUT4 in adipose tissue • Hongwei Yu et al., J Gastrointest Surg, 2013 • For GK rats, gene expression profile of islets and GI hormone levels were assessed. • After surgery, GI Hormone level was improved and Ca2+ concentration changed in pancreas. Ca2+ channel activity also improved and RYGB induced pancreatic islet beta-cell proliferation and improve function of beta-cell. • They concluded that, RYGB promoted a new metabolic environment while triggering changes to adapt to the new environment. These changes promoted the cellular proliferation of islets and improved the function of beta cells. The quantity of beta cells increased, and their quality improved, ultimately leading to insulin secretion enhancement. RYGB에 의한 당뇨 치료기전 발굴전략 1. RYGB Gene expression Data 수집 (rat, human) 2. Co-expression network 구축 3. Gene Set Enrichment Analysis 수행 4. Negative case 분석 수행 (human trial 중 T2DM remission 실패한 case) 5. 공통 기전 분석 및 결론 도출 Bioinformatics and Synthetic Biology Lab., KAIST 33 Current Status 34 RYGB Gene expression data 수집 • GSE8314 – rat RYGB Dataset (Hypothalamus, subcutaneous abdominal fat) • GSE68812 – rat RYGB Dataset (small intestine) • GSE5109 – human RYGB Dataset (obesity, muscle) • GSE24297 – human RYGB Dataset (subcutaneous adipose) • GSE32575 – human RYGB Dataset (circulating monocyte) • GSE69248 – human RYGB Dataset (32 gene signature in liver) Co-expression network 구축 및 분석 수행 중 • MAQC I~III (2006 ~ 2014) – Micro array Quality Control Study paper 분석 • MAQC I – microarray quality control • MAQC II – microarray prediction quality control • MAQC III – SEQC, RNA-seq quality contorl • Probe selection & gene-probe mapping, platform-to-platform variation control guideline study 중 (NIH Standard) Bioinformatics and Synthetic Biology Lab., KAIST Beige Adipose Target 약물 및 치료기전 발굴 Bioinformatics and Synthetic Biology Lab., KAIST White, Beige, and Brown Adipose Tissues There is persuasive evidence from animal models that enhancement of the function of brown adipocytes, beige adipocytes or both in humans could be very effective for treating type 2 diabetes and obesity. Moreover, there are now an extensive variety of factors and pathways that could potentially be targeted for therapeutic effects, including PPAR-gamma – the target of TZD. 36 Adipocyte Browning Agent 37 Adipocyte Browning Agent Bioinformatics and Synthetic Biology Lab., KAIST 38 Dietary Adipocyte Browning Agent Bioinformatics and Synthetic Biology Lab., KAIST 39 Why Browning Matter? 40 In humans, low BAT activity is correlated with ageing, obesity and measures of metabolic disease is pivotal. This relationship suggests a causal link between decreased BAT activity and weight gain. Most of the standard metabolic parameters routinely assessed by physicians, such as blood glucose and lipid levels, are influenced by the activity of brown (and possibly also beige) adipocytes. The induction of browning represents one important approach that could potentially convert deleteriously lipid-overloaded WAT into metabolically active and healthy BAT Bartelt, A. & Heeren, J. Nat. Rev. Endocrinol. 10, 24–36 (2014) Beige adipocyte 분화 연관 약물/기전 발굴 전략 41 1. Beige adipocyte 분화 연관 연구 Literature Survey 2. white/beige adipocyte gene expression Data 수집 3. 3T3 L1 기반 white/beige adipocyte gene expression Data 분석 및 genetic marker selection 4. 3T3 L1 derived beige adipocyte 분화 실험 Setting 5. 3T3 L1 derived white adipocyte browning agent 실험 및 phenotype 분석 6. Genotype, Phenotype 연계 분석 7. 약물 유사성 분석 기반 신규 Browning Agent 발굴 8. 신규 Browning Agent characterization – gene, protein expression, phenotype Bioinformatics and Synthetic Biology Lab., KAIST Current Status 42 1. Beige adipocyte 분화관련 Literature Survey – 관련 연구 정리 및 update 중 2. BAT 관련 Expression data 수집 • GSE8044 Mouse BAT, WAT tissue • GSE60441/2 Mouse White and EBF2 Over expressed adipose tissue • GSE55080 PRDM16 KO Brown adipose Tissue • GSE39562 Isolated Beige Adipocyte in mouse 3. 3T3 L1 관련 Expression data 수집 • GSE69313 3T3-L1, FTO KO • GSE53249 3T3-L1, FTO, METTL3 deficient RNA-Seq • GSE12929 3T3-L1, PPARg KO • GSE14810 3T3-L1, TZD (rosiglitazone) treatment • GSE1458 3T3-L1, TZD (pioglitazone, rosiglitazone, troglitazone) treatment • GSE64075 3T3-L1, TZD (rosiglitazone), NSAIDs (Diclofenac, Indomethacin, Ibuprofen) • GSE34150 3T3-L1, Insulin, Dexamethasone treatment • GSE56440 3T3-L1, Berberine Treatment • GSE49176 3T3-L1, control 4. 3T3 L1 expression data 분석 진행중 MCMT 당뇨연관 약물 및 치료기전 발굴 MCMT 당뇨 연관 약물/치료기전 발굴 주제 • 당뇨 및 심혈관 질환 공통 표적 약물 및 치료기전 발굴 • RYGB 치료기전 발굴 및 기전 유사 약물 발굴 • White Adipocyte Browning 약물 발굴 및 약물 작용 기전 분석 Current Status • 기본 Literature Survey • 필요 데이터 확보 • 분석 방법 Study 추후계획 • Literature Survey 결과 누적 Update • 데이터 분석 및 실험 검증 계획 구체화 Bioinformatics and Synthetic Biology Lab., KAIST 43 Method of organizing your research Writing paper is the best way of organizing your research Ask, • What is the problem • Why you trying to solve the problem • How are you solving it • What have you done • Who cares English • Outline • Words right • Strunk & White • Simple version of English, as clear as you can make it, as short as you can make it, Organize transparently, written flawlessly grammatically, using simple English words. 44 45 Background – Type 2 Diabetes and Drug Discovery Problem Setting Methods and Process Preliminary Data Future Plan Bioinformatics and Synthetic Biology Lab., KAIST