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Global Annotation of the Protein Kinase Family Michael Gribskov University of California, San Diego.

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Presentation on theme: "Global Annotation of the Protein Kinase Family Michael Gribskov University of California, San Diego."— Presentation transcript:

1 Global Annotation of the Protein Kinase Family Michael Gribskov University of California, San Diego

2 Signaling Cascades

3

4 Statistics Arabidopsis 1028 putative kinase 58 Potentially alternatively spliced 82 % confirmed by full length cDNA Less than 100 experimentally investigated Rice 1565 putative kinases What are the functions of each protein kinase? Functional groupings Substrate prediction Pathway analysis and modeling

5 Targets Protein kinase Protein phosphatase Membrane transporters Proteasome complex

6 Some Receptor Kinases Class I (EGF receptor) Class II (Insulin receptor) Class III (FGF receptor)

7 Requirements for Functional Clustering Must handle very large number of objects (over 1200 for plants, over 9000 for all species) Must deal sensibly with paralogs from functional point of view Must be based on entire sequence, not just kinase catalytic domain Must be tolerant to sequence errors and omissions

8 Orthology vs Paralogy Relationships between genes in multigene families are complex Multiple genes may exist before speciation Genes may be lost and replaced along lineages “Function space” must be filled Species A Species B

9 Clustering

10

11 Clustering/Classification Maximum linkage

12 Clustering/Classification Pairwise distances All-against-all BLAST Uses entire sequence Alignments not required Longer matches, i.e. more domains, give better score

13 Basic Approach Maximum linkage clustering up to “natural” limit Recalculate average distances between groups Repeat until tree is complete

14 Complete Kinase Clustering

15 Statistics Class 1: RLKs (transmembrane) and RLCKs Class 2: “Raf-like” Class 3: Casein Kinase and CLK Class 4: Non-TM, Non-Receptor

16 BLAST Distance Entire Sequence

17 BLAST Distance Non-Kinase Domain

18 Yeast Signaling (MAPK)

19 Validating Transgenomic Predictions

20 SnRK At AKIN10 and AKin11 Rescue yeast SNF1 deletion Functional homolog

21 MAPK

22 MEME PSSM

23 PPC4.2.6 MEME Motifs

24 Summary Functional groups by clustering Functional assignment by transgenomic comparison Directed search for functional motifs by motif comparison Construction of public data resources

25 Bioinformatics Group Michael Gribskov Fariba Fana Degeng Wang Sheila Podell Tobey Tam * Jason Tchieu * Hannes Niedner Douglas Smith Guangfa Zhang * Jeff Harper Major Contributors Catherine Chan Alice Harmon Estelle Hrabak David Kerk Shinhan Shiu

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