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Introduction to bioinformatics Lecture 2 Genes and Genomes

C. E. N. T. E. 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. Introduction to bioinformatics Lecture 2 Genes and Genomes. Organisational. Course website: http://ibi .vu .nl/teaching/mnw_2year/mnw2_200 7 .php

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Introduction to bioinformatics Lecture 2 Genes and Genomes

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  1. C E N T E 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 Introduction to bioinformaticsLecture 2Genes and Genomes

  2. Organisational • Course website:http://ibi.vu.nl/teaching/mnw_2year/mnw2_2007.php • or click on • http://ibi.vu.nl • (>teaching >Introduction to Bioinformatics) • Course book:Bioinformatics and Molecular Evolution by Paul G. Higgs and Teresa K. Attwood (Blackwell Publishing), 2005, ISBN (Pbk) 1-4051-0683-2 • Lots of information about Bioinformatics can be found on the web.

  3. DNA sequence .....acctc ctgtgcaaga acatgaaaca nctgtggttc tcccagatgg gtcctgtccc aggtgcacct gcaggagtcg ggcccaggac tggggaagcc tccagagctc aaaaccccac ttggtgacac aactcacaca tgcccacggt gcccagagcc caaatcttgt gacacacctc ccccgtgccc acggtgccca gagcccaaat cttgtgacac acctccccca tgcccacggt gcccagagcc caaatcttgt gacacacctc ccccgtgccc ccggtgccca gcacctgaac tcttgggagg accgtcagtc ttcctcttcc ccccaaaacc caaggatacc cttatgattt cccggacccc tgaggtcacg tgcgtggtgg tggacgtgag ccacgaagac ccnnnngtcc agttcaagtg gtacgtggac ggcgtggagg tgcataatgc caagacaaag ctgcgggagg agcagtacaa cagcacgttc cgtgtggtca gcgtcctcac cgtcctgcac caggactggc tgaacggcaa ggagtacaag tgcaaggtct ccaacaaagc aaccaagtca gcctgacctg cctggtcaaa ggcttctacc ccagcgacat cgccgtggag tgggagagca atgggcagcc ggagaacaac tacaacacca cgcctcccat gctggactcc gacggctcct tcttcctcta cagcaagctc accgtggaca agagcaggtg gcagcagggg aacatcttct catgctccgt gatgcatgag gctctgcaca accgctacac gcagaagagc ctctc.....

  4. Genome size Organism Number of base pairs X-174 virus 5,386 Epstein Bar Virus 172,282 Mycoplasma genitalium 580,000 Hemophilus Influenza 1.8  106 Yeast (S. Cerevisiae) 12.1  106 Human 3.2  109 Wheat 16  109 Lilium longiflorum 90  109 Salamander 100  109 Amoeba dubia 670  109

  5. Four DNA nucleotide building blocks G-C is more strongly hydrogen-bonded than A-T

  6. DNA transcription mRNA translation Protein A gene codes for a protein CCTGAGCCAACTATTGATGAA CCUGAGCCAACUAUUGAUGAA PEPTIDE

  7. Central Dogma of Molecular Biology Transcription Translation Replication DNA mRNA Protein Transcription is carried out by RNA polymerase (II) Translation is performed on ribosomes Replication is carried out by DNA polymerase Reverse transcriptase copies RNA into DNA Transcription + Translation = Expression

  8. But DNA can also be transcribed into non-coding RNA … • tRNA (transfer): transfer of amino acids to theribosome during protein synthesis. • rRNA (ribosomal): essential component of the ribosomes (complex with rProteins). • snRNA (small nuclear): mainly involved in RNA-splicing(removal of introns). snRNPs. • snoRNA (small nucleolar): involved in chemical modifi-cations of ribosomal RNAs and other RNA genes. snoRNPs. • SRP RNA (signal recognition particle): form RNA-protein complex involved in mRNA secretion. • Further: microRNA, eRNA, gRNA, tmRNA etc.

  9. Eukaryotes have spliced genes … • Promoter: involved in transcription initiation (TF/RNApol-binding sites) • TSS: transcription start site • UTRs: un-translated regions (important for translational control) • Exonswill be spliced together by removal of theIntrons • Poly-adenylation siteimportant for transcription termination (but also: mRNA stability, export mRNA from nucleus etc.)

  10. DNA makes mRNA makes Protein

  11. DNA makes RNA makes Protein … yet another picture to appreciate the above statement

  12. Some facts about human genes • There are about 20.000 – 25.000 genes in the human genome (~ 3% of the genome) • Average gene length is ~ 8.000 bp • Average of 5-6 exons per gene • Average exon length is ~ 200 bp • Average intron length is ~ 2000 bp • 8% of the genes have a single exon • Some exons can be as small as 1 or 3 bp

  13. DMD: the largest known human gene • The largest known human gene is DMD, the gene that encodes dystrophin: ~ 2.4 milion bp over 79 exons • X-linked recessive disease (affects boys) • Two variants: Duchenne-type (DMD) and becker-type (BMD) • Duchenne-type: more severe, frameshift-mutationsBecker-type: milder phenotype, “in frame”- mutations Posture changes during progression of Duchenne muscular dystrophy

  14. Nucleic acid basics nucleotide nucleoside • Nucleic acids are polymers • Each monomer consists of 3 moieties

  15. Nucleic acid basics (2) • Purines and Pyrimidines can base-pair (Watson- Crick pairs) • A base can be of 5 rings Watson and Crick, 1953

  16. Nucleic acid as hetero-polymers • DNA and RNA strands • Nucleosides, nucleotides (Ribose sugar, RNA precursor) (2’-deoxy ribose sugar, DNA precursor) REMEMBER: • DNA = deoxyribonucleotides;RNA = ribonucleotides (OH-groups at the 2’ position) • Note thedirectionality of DNA (5’-3’ & 3’-5’) or RNA (5’-3’) • DNA = A, G, C, T ; RNA = A, G, C, U (2’-deoxy thymidine tri- phosphate, nucleotide)

  17. So … RNA DNA

  18. Stability of base-pairing • C-G base pairing is more stable than A-T (A-U) base pairing (why?) • 3rd codon position has freedom to evolve (synonymous mutations) • Species can therefore optimise their G-C content (e.g. thermophiles are GC rich) (consequences for codon use?) Thermocrinis ruber, heat-loving bacteria

  19. Single Letter Code DNA codons Amino Acid Isoleucine   I ATT, ATC, ATA Leucine   L CTT, CTC, CTA, CTG, TTA, TTG Valine V GTT, GTC, GTA, GTG Phenylalanine   F TTT, TTC Methionine M, Start ATG Cysteine  c TGT, TGC Alanine       A GCT, GCC, GCA, GCG Glycine   G GGT, GGC, GGA, GGG Proline       P CCT, CCC, CCA, CCG Threonine   T ACT, ACC, ACA, ACG Serine        S TCT, TCC, TCA, TCG, AGT, AGC Tyrosine   Y TAT, TAC Tryptophan   W TGG Glutamine   Q CAA, CAG Asparagine   N AAT, AAC Histidine  H CAT, CAC Glutamic acid   E GAA, GAG Aspartic acid  D GAT, GAC Lysine        K AAA, AAG Arginine   R CGT, CGC, CGA, CGG, AGA, AGG Stop codons Stop TAA, TAG, TGA

  20. DNA compositional biases • Base compositions of genomes: G+C (and therefore also A+T) content varies between different genomes • The GC-content is sometimes used to classify organism in taxonomy • High G+C content bacteria: Actinobacteriae.g. in Streptomyces coelicolor it is 72%Low G+C content: Plasmodium falciparum (~20%) • Other examples:

  21. Genetic diseases: cystic fibrosis • Known since very early on (“Celtic gene”) • Autosomal, recessive, hereditary disease (Chr. 7) • Symptoms: • Exocrine glands (which produce sweat and mucus) • Abnormal secretions • Respiratory problems • Reduced fertility and (male) anatomical anomalies 3,000 20,000 30,000

  22. cystic fibrosis (2) • Gene product: CFTR (cystic fibrosis transmembrane conductance regulator) • CFTR is an ABC (ATP-binding cassette) transporter or traffic ATPase. • These proteins transport molecules such as sugars, peptides, inorganic phosphate, chloride, and metal cations across the cellular membrane. • CFTR transports chloride ions (Cl-) ions across the membranes of cells in the lungs, liver, pancreas, digestive tract, reproductive tract, and skin.

  23. cystic fibrosis (3) • CF gene CFTR has 3-bp deletion leading to Del508 (Phe) in 1480 aa protein (epithelial Cl- channel) • Protein degraded in Endoplasmatic Reticulum (ER) instead of inserted into cell membrane Theoretical Model of NBD1. PDB identifier 1NBD as viewed in Protein Explorer http://proteinexplorer.org Diagram depicting the five domains of the CFTR membrane protein (Sheppard 1999). The deltaF508 deletion is the most common cause of cystic fibrosis. The isoleucine (Ile) at amino acid position 507 remains unchanged because both ATC and ATT code for isoleucine

  24. Let’s return to DNA and RNA structure … • Unlike three dimensional structures of proteins, DNA molecules assume simple double helical structures independent of their sequences. • There are three kinds of double helices that have been observed in DNA: type A, type B, and type Z, which differ in their geometries. • RNA on the other hand, can have as diverse structures as proteins, as well as simple double helix of type A. • The ability of being both informational and diverse in structure suggests that RNA was the prebiotic molecule that could function in both replication and catalysis (The RNA World Hypothesis). • In fact, some viruses encode their genetic materials by RNA (retrovirus)

  25. Three dimensional structures of double helices Side view: A-DNA, B-DNA, Z-DNA Space-filling models of A, B and Z- DNA Top view: A-DNA, B-DNA, Z-DNA

  26. Major and minor grooves

  27. 5’ 3’ 3’ 5’ Forces that stabilize nucleic acid double helix • There are two major forces that contribute to stability of helix formation: • Hydrogen bonding in base-pairing • Hydrophobic interactions in base stacking Same strand stacking cross-strand stacking

  28. Types of DNA double helix • Type B major conformation DNA Right-handed helix Long and thin • Type Z minor conformation DNA Left-handed helix Longer and thinner • Type A major conformation RNA minor conformation DNA Right-handed helix Short and broad

  29. Secondary structures of Nucleic acids • DNA is primarily in duplex form • RNA is normally single stranded which can have a diverse form of secondary structures other than duplex.

  30. Non B-DNA Secondary structures • Slipped DNA • Cruciform DNA • Triple helical DNA Hoogsteen basepairs Source: Van Dongen et al. (1999) , Nature Structural Biology6, 854 - 859

  31. More Secondary structures • Cloverleaf rRNA structure • RNA pseudoknots 16S rRNA Secondary Structure Based onPhylogenetic Data Source: Cornelis W. A. Pleij in Gesteland, R. F. and Atkins, J. F. (1993) THE RNA WORLD. Cold Spring Harbor Laboratory Press.

  32. 3D structures of RNA :transfer-RNA structures • Tertiary structure of tRNA • Secondary structure of tRNA (cloverleaf)

  33. Ban et al., Science289 (905-920), 2000 3D structures of RNA :ribosomal-RNA structures • Tertiary structure of large rRNA subunit • Secondary structure of large rRNA (16S)

  34. 3D structures of RNA :Catalytic RNA • Tertiary structure of self-splicing RNA • Secondary structure of self-splicing RNA

  35. Some structural rules … • Base-pairing is stabilizing • Un-paired sections (loops) destabilize • 3D conformation with interactions makes up for this

  36. Three main principles • DNA makes RNA makes Protein • Structure more conserved than sequence • Sequence Structure Function

  37. How to go from DNA to protein sequence A piece of double stranded DNA: 5’attcgttggcaaatcgcccctatccggc 3’ 3’ taagcaaccgtttagcggggataggccg 5’ DNA direction is from 5’ to 3’

  38. How to go from DNA to protein sequence 6-frame conceptual translation using the codon table: 5’attcgttggcaaatcgcccctatccggc 3’ 3’ taagcaaccgtttagcggggataggccg 5’ So, there are six possibilities to make a protein from an unknown piece of DNA, only one of which might be a natural protein

  39. Remark • Identifying (annotating) human genes, i.e. finding what they are and what they do, is a difficult problem • First, the gene should be delineated on the genome • Gene finding methods should be able to tell a gene region from a non-gene region • Start, stop codons, further compositional differences • Then, a putative function should be found for the gene located

  40. Evolution and three-dimensional protein structure information Isocitrate dehydrogenase: The distance from the active site (in yellow) determines the rate of evolution (red = fast evolution, blue = slow evolution) Dean, A. M. and G. B. Golding: Pacific Symposium on Bioinformatics2000

  41. Genomic Data Sources • DNA/protein sequence • Expression (microarray) • Proteome (xray, NMR, • mass spectrometry) • Metabolome • Physiome (spatial, • temporal) Integrative bioinformatics

  42. Genomic Data Sources Vertical Genomics genome transcriptome proteome metabolome physiome Dinner discussion: Integrative Bioinformatics & Genomics VU

  43. DNA makes RNA makes Protein(reminder)

  44. DNA makes RNA makes Protein:Expression data • More copies of mRNA for a gene leads to more protein • mRNA can now be measured for all the genes in a cell at ones through microarray technology • Can have 60,000 spots (genes) on a single gene chip • Colour change gives intensity of gene expression (over- or under-expression)

  45. Proteomics • Elucidating all 3D structures of proteins in the cell • This is also called Structural Genomics • Finding out what these proteins do • This is also called Functional Genomics

  46. Protein-protein interaction networks

  47. Metabolic networksGlycolysis and Gluconeogenesis Kegg database (Japan)

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