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1-month Practical Course Genome Analysis Protein Structure-Function Relationships Centre for Integrative Bioinformatics VU (IBIVU) Vrije Universiteit Amsterdam.

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Presentation on theme: "1-month Practical Course Genome Analysis Protein Structure-Function Relationships Centre for Integrative Bioinformatics VU (IBIVU) Vrije Universiteit Amsterdam."— Presentation transcript:

1 1-month Practical Course Genome Analysis Protein Structure-Function Relationships Centre for Integrative Bioinformatics VU (IBIVU) Vrije Universiteit Amsterdam The Netherlands www.ibivu.cs.vu.nl heringa@cs.vu.nl C E N T R F O R I N T E G R A T I V E B I O I N F O R M A T I C S V U E

2 Genome/DNA Transcriptome/mRNA Proteome Metabolome Physiome Transcription factors Ribosomal proteins Chaperonins Enzymes Protein function

3 Not all proteins are enzymes:  -crystallin: eye lens protein – needs to stay stable and transparent for a lifetime (very little turnover in the eye lens)

4 Protein function groups Catalysis (enzymes) Binding – transport (active/passive) –Protein-DNA/RNA binding (e.g. histones, transcription factors) –Protein-protein interactions (e.g. antibody-lysozyme) –Protein-fatty acid binding (e.g. apolipoproteins) –Protein – small molecules (drug interaction, structure decoding) Structural component (e.g.  -crystallin) Regulation Transcription regulation Signalling Immune system Motor proteins (actin/myosin)

5 What can happen to protein function through evolution Proteins can have multiple functions (and sometimes many -- Ig). Enzyme function is defined by specificity and activity Through evolution: Function and specificity can stay the same Function stays same but specificity changes Change to some similar function (e.g. somewhere else in metabolic system) Change to completely new function

6 How to arrive at a given function Divergent evolution – homologous proteins –proteins have same structure and “same- ish” function Convergent evolution – analogous proteins – different structure but same function Question: can homologous proteins change structure (and function)?

7 Protein function evolution Chymotrypsin ‘Modern’ 2-barrel structure Putative ancestral barrel structure Active site (combination of ancestral active site residues) Activity 1000-10,000 times enhanced

8 How to evolve Important distinction: Orthologues: homologous proteins in different species (all deriving from same ancestor) Paralogues: homologous proteins in same species (internal gene duplication) In practice: to recognise orthology, bi-directional best hit is used in conjunction with database search program (this is called an operational definition)

9 How to evolve By addition of domains (at either end of protein sequence or at loop sites [see next slides]) Often through gene duplication followed by divergence Multi-domain proteins are a result of gene fusion (multiple genes ending up in a single ORF). Repetitions of the same domain in a single protein occur frequently (gene duplication followed by gene fusion)

10 Protein structure evolution Insertion/deletion of secondary structural elements can ‘easily’ be done at loop sites These sites are normally at the surface of a protein

11 Example -- Flavodoxin fold 5(  ) fold

12 Flavodoxin family - TOPS diagrams (Flores et al., 1994) 12345 1 234 5 These are four variations of the same basic topology (bottom) Do you see what is inserted as compared to the basic topology? = alpha-helix = beta-strand A TOPS diagram is a schematic representation of a protein fold

13 Protein structure evolution Insertion/deletion of structural domains can ‘easily’ be done at loop sites N C

14 The basic functional unit of a protein is the domain A domain is a: Compact, semi-independent unit (Richardson, 1981). Stable unit of a protein structure that can fold autonomously (Wetlaufer, 1973). Recurring functional and evolutionary module (Bork, 1992). “Nature is a ‘tinkerer’ and not an inventor” (Jacob, 1977).

15 Delineating domains is essential for: Obtaining high resolution structures (x-ray, NMR) Sequence analysis Multiple sequence alignment methods Prediction algorithms (SS, Class, secondary/tertiary structure) Fold recognition and threading Elucidating the evolution, structure and function of a protein family (e.g. ‘Rosetta Stone’ method – next lecture) Structural/functional genomics Cross genome comparative analysis

16 Pyruvate kinase Phosphotransferase  barrel regulatory domain  barrel catalytic substrate binding domain  nucleotide binding domain 1 continuous + 2 discontinuous domains Structural domain organisation can be nasty…

17 Complex protein functions are a result of multiple domains An example is the so-called swivelling domain in pyruvate phosphate dikinase (Herzberg et al., 1996), which brings an intermediate enzymatic product over about 45 Å from the active site of one domain to that of another. This enhances the enzymatic activity: delivery of intermediate product not by a diffusion process but by active transport

18 The DEATH Domain Present in a variety of Eukaryotic proteins involved with cell death. Six helices enclose a tightly packed hydrophobic core. Some DEATH domains form homotypic and heterotypic dimers. http://www.mshri.on.ca/pawson

19

20 Globin fold  protein myoglobin PDB: 1MBN

21  sandwich  protein immunoglobulin PDB: 7FAB

22 TIM barrel  /  protein Triose phosphate IsoMerase PDB: 1TIM

23 A fold in  +  protein ribonuclease A PDB: 7RSA The red balls represent waters that are ‘bound’ to the protein based on polar contacts

24

25 434 Cro protein complex (phage) PDB: 3CRO

26 Zinc finger DNA recognition (Drosophila) PDB: 2DRP..YRCKVCSRVY THISNFCRHY VTSH...

27 Characteristics of the family: Function: The DNA-binding motif is found as part of transcription regulatory proteins. Structure: One of the most abundant DNA-binding motifs. Proteins may contain more than one finger in a single chain. For example Transcription Factor TF3A was the first zinc-finger protein discovered to contain 9 C2H2 zinc-finger motifs (tandem repeats). Each motif consists of 2 antiparallel beta-strands followed by by an alpha-helix. A single zinc ion is tetrahedrally coordinated by conserved histidine and cysteine residues, stabilising the motif. Zinc-finger DNA binding protein family

28 Binding: Fingers bind to 3 base-pair subsites and specific contacts are mediated by amino acids in positions - 1, 2, 3 and 6 relative to the start of the alpha-helix. Contacts mainly involve one strand of the DNA. Where proteins contain multiple fingers, each finger binds to adjacent subsites within a larger DNA recognition site thus allowing a relatively simple motif to specifically bind to a wide range of DNA sequences. This means that the number and the type of zinc fingers dictates the specificity of binding to DNA Characteristics of the family: Zinc-finger DNA binding protein family

29 Leucine zipper (yeast) PDB: 1YSA..RA RKLQRMKQLE DKVEE LLSKN YHLENEVARL...

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