1. Alizadeh et. al. (2000) Stephen Ayers 12/2/01

2. Clustering “Clustering is finding a natural grouping in a set of data, so that samples within a cluster will be more similar to each other than they are to samples in other clusters.” Finding groups of correlated genes “signature groups” Genes without well established relationships Extract features of groups

3. Hierarchical Clustering Tiers of points from a bottom layer of 1 point in each of n clusters to top level of n points, all in one cluster Usually represented in dendrogram

4. Divisive Top-down Start with all samples and successively split into separate clusters

5. Agglomerative Bottom-up approach Less computationally intensive Start with n singletons and successively merge clusters –Place all values in separate clusters –Merge most similar clusters into higher clusters –Repeat until all clusters have been merged

6. Average-Linkage Method Available > 1.Compute similarity matrix 2.Scan matrix to find most highest similarity Uses form of the correlation coefficient 3.A node is created between these values 4.Values are replaced by node

7. Diffuse Large B-cell Lymphoma Most common subtype of non-Hodgkin’s Lymphoma 25,000 cases/year 40% of patients respond well Possible undetected heterogeneity Found 2 classes using clustering (Eisen 1998): Germinal Center B-like and Activated B-like

8. Lymphochip 17,856 cDNA clones total 12,069 germinal center B-cell library 2,338 lymphomic cancer genes 3,186 genes important to lymphocyte or cancer biology ¼ of genes = duplicates

9. Expression Analysis DLBCL, Follicular Lymphoma, Chronic Lympohcytic Leukemia Lymphocyte subpopulations with a range of conditions -normal human tonsils, lymph nodes -lymphoma, leukemia cell lines

10. Figure 1

11. Figure 2:

12. Figure 3:

13. Figure 4: GC Activated

14. Figure 5

15. Conclusions More categories likely Changes in treatment Possible drug targets