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Fundamental Concepts of Bioinformatics Dan E. Krane

Fundamental Concepts of Bioinformatics By Dan E. Krane

Fundamental Concepts of Bioinformatics by Dan E. Krane


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Summary

A bioinformatics primer for undergraduates, this text focusses on fundamentally important algorithms at the core of bioinformatics. Easy-to-do 'paper and pencil' calculations make them unintimidating for biology students and accessible to students with limited experience in computer programming.

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Fundamental Concepts of Bioinformatics Summary

Fundamental Concepts of Bioinformatics: United States Edition by Dan E. Krane

Fundamental Concepts of Bioinformatics is the first book co-authored by a biologist and computer scientist that is specifically designed to make bioinformatics accessible and provide readers for more advanced work. Readers learn what programs are available for analyzing data, how to understand the basic algorithms that underlie these programs, what bioinformatic research is like, and other basic concepts. Information flows easily from one topic to the next, with enough detail to support the major concepts without overwhelming readers. Problems at the end of each chapter use real data to help readers apply what they have learned so they know how to critically evaluate results from both a statistical and biological point of view.

Table of Contents

I. MOLECULAR BIOLOGY AND BIOLOGICAL CHEMISTRY.

The genetic material.

Nucleotides.

Orientation.

Base pairing.

The central dogma of molecular biology.

Gene structure and information content.

Promoter sequences.

The genetic code.

Open reading frames.

Introns and exons.

Protein structure and function.

Primary structure.

Secondary, tertiary and quaternary structure.

The nature of chemical bonds.

Anatomy of an atom.

Valence.

Electronegativity.

Hydrophilicity and hydrophobicity.

Molecular biology tools.

Restriction enzymes.

Gel electrophoresis.

Blotting, hybridization and microarrays.

Cloning.

Polymerase chain reaction (PCR).

DNA sequencing.

Genomic information content.

C value paradox.

Reassociation kinetics.

II. DATA SEARCHES AND PAIRWISE ALIGNMENTS.

Dot plots.
Simple alignments.
Scoring.
Gaps.

Simple gap penalties.

Origination and length penalties.

Scoring matrices.
Dynamic programming: The Needleman and Wunsch algorithm.
Local and global alignments.

Global and Semi-global alignments.

The Smith-Waterman algorithm.

Database searches.

BLAST and its relatives.

Other algorithms.

Multiple sequence alignments.

III. SUBSTITUTION PATTERNS.

Patterns of substitutions within genes.

Mutation rates.

Functional constraint.

Synonymous vs. nonsynonymous changes.

Indels and psuedogenes.

Substitutions vs. mutations.

Fixation.

Estimating substitution numbers.

Jukes/Cantor model.

Transitions and transversions.

Kimura's two-parameter model.

Models with even more parameters.

Substitutions between protein sequences.

Variations in substitution rates between genes.
Molecular clocks.

Relative rate tests.

Causes of rate variation in lineages.

Evolution in organelles.

IV. DISTANCE-BASED METHODS OF PHYLOGENETICS.

History of molecular phylogenetics.
Advantages to molecular phylogenies.
Phylogenetic trees.

Terminology of tree reconstruction.

Rooted and unrooted trees.

Gene vs. species trees.

Character and distance data.

Distance matrix methods.

UPGMA.

Estimation of branch lengths.

Transformed distance method.

Neighbor's relation method.

Neighbor-joining methods.

Maximum likelihood approaches.
Multiple sequence alignments.

V. CHARACTER-BASED APPROACHES TO PHYLOGENETICS.

Parsimony.

Informative and uninformative sites.

Unweighted parsimony.

Weighted parsimony.

Inferred ancestral sequences.
Strategies for faster searches.

Branch and bound.

Heuristic.

Consensus trees.
Tree confidence.

Bootstrapping.

Parametric tests.

Comparison of phylogenetic methods.
Molecular phylogenies.

The tree of life.

Human origins.

VI. GENOMICS AND GENE RECOGNITION.

Prokaryotic genomes.
Prokaryotic gene structure.

Promoter elements.

Open reading frames.

Conceptual translation.

Termination sequences.

GC-content.
Prokaryotic gene density.
Eukaryotic genomes.
Eukaryotic gene structure.

Promoter elements.

Regulatory protein binding sites.

Open reading frames.

Introns and exons.

Alternative splicing.

CpG islands.

GC-content.

Isochores.

Codon usage bias.

Gene expression.

cDNAs and ESTs.

Serial analysis of gene expression (SAGE).

Microarrays.

Transposition.
Repetitive elements.
Eukaryotic gene density.

VII. PROTEIN FOLDING.

Polypeptide composition.

Amino acids.

Backbone flexibility, phi and psi.

Secondary structure.

Accuracy of predictions.

Chou-Fasman/GOR method.

Tertiary and quaternary structure.

Hydrophobicity.

Disulfide bonds.

Active structures vs. most stable structures.

Protein folding.

Lattice models.

Off-lattice models.

Energy functions and optimization.

Structure prediction.

Comparative modeling.

Threading: Reverse protein folding.

Predicting RNA secondary structures.

VIII. PROTEOMICS.

From genomes to proteomes.
Protein classification.

Enzyme nomenclature.

Families and superfamilies.

Folds.

Experimental techniques.

2D electrophoresis.

Mass spectrometry.

Protein microarrays.

Inhibitors and drug design.
Ligand screening.

Docking.

Database screening.

X-ray crystal structures.
Empirical methods and prediction techniques.
Postranslational modification prediction.

Protein sorting.

Proteolytic cleavage.

Glycosylation.

Phosporylation and sulfation.

Appendix 1: A gentle introduction to programming and data structures.

Introduction.
The basics.

Creating and compiling computer programs.

Variables and values.

Data typing.

Basic operations.

Program control.

Statements and blocks.

Conditional execution.

Loops.

Readability.

Structured programming.

Comments.

Descriptive variable names.

Data structures.

Arrays.

Pointers and dynamic memory allocation.

Strings in PERL.

Input and output.

Appendix 2: Enzyme kinetics.

Enzymes as biological catalysts.
The Henri-Michaelis-Menten equation.

Vmax and Km.

Direct plot.

Lineweaver-Burk reciprocal plot.

Eadie-Hofstee plot.

Simple inhibition systems.

Competitive inhibition.

Noncompetitive inhibition.

Reversible and irreversible inhibition.

Effects of pH and temperature.

Appendix 3: Sample programs in PERL and worksets.

Conceptual translation.
Dot matrix.
Relative rate test.
UPGMA.
Common ancestor.
Splice junction recognition.
Hydrophobicity calculator.
DNA binding domains.
Lineweaver-Burk plot.

Additional information

CIN0805346333VG
9780805346336
0805346333
Fundamental Concepts of Bioinformatics: United States Edition by Dan E. Krane
Used - Very Good
Hardback
Pearson Education (US)
20021004
320
N/A
Book picture is for illustrative purposes only, actual binding, cover or edition may vary.
This is a used book - there is no escaping the fact it has been read by someone else and it will show signs of wear and previous use. Overall we expect it to be in very good condition, but if you are not entirely satisfied please get in touch with us

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