Chapter !4 - Comparative Genomics Code : KSI0013
<Index of Chapter 4>
Introduction
It's likely that life originated on Earth about 3.5 billion years ago. the first cellular life forms were undoubtedly prokaryotes. Eukaryotes appeared about 2 billion year later. There are enough residual similarities among living things to suggest a common ancestory of us all. The great diversity of living forms is therefore, the result of divergence.
Unity and diversity of life
Binomial /DNA barcoding
Taxonomy based on sequences
- Traditional linnaean biological nomenclature assigns names to species, and classifies apecies according to evolutionary relationships. It's often difficult todraw boundaries between species, especially for microorganisms.
- Bacteria/ archaea / Eukarya / phylogenetic tree. / horizontal gene transfer ( Please pass the genes)
Sizes and organization of genomes
Genome sizes
Genome sequences/ RNA and protein expression patterns/ The spatial organization of individual macromolecules, their complexes, organelles, entire cells, tissues, and bodies
/ regulatory networs, the internal structure and logic of adaptive control systems.
The term C-value has been used to refer to the amount of DNA in a haploied cell. the letter C refers to the constancy of the amount of DNA per cell in a pspecies.
Viral genomes
Recombinant viruses
BOth HIV- 1 and influenza viruses have become major threats to human health after jumping from animal hosts. Their high mutation rates with severe clinical consequences- reflect the fact that their genomes are RNA
Influenza : a past and current threat
Types of viral genome
- SSDNA
- DSDNA
- SSRNA
- DSRNA
Genome Organization in prokaryotes
Replication and transcription
Gene transfer
- transformation / conjugation / trnasduction
Some but not all prokaryote genomes contain Insertion sequences mobile genetic elements similar to eukaryotic transposons.
Prokaryotes have several mechanisms for sharing genetic material : Transformation by naked DNA conjugation and transfer via viruses.
Genome Organization in eukaryotes
Photosynthetic sea slugs : endosymbiosys of chloroplasts
Mitochondria and chloroplasts carry out their own protein synthesis. Chchloroplasts and plant mitochondria translate their genes according to the standard genetic code, but animal mitochondria use variants.
Traffic between the mitochondrial and nuclear genomes.
How genomes differ
Variation at the level of individual nucleotides
Duplications
Comparisions at the chromosome level : synteny
What can happen to a gene?
- During evolution
-1 A gene may pass to descendants, accumulating favourable or unavourable mutations or dirifting neutrally.
2. A gene may be lost
3. A gene may be dulicated followed by divergence or by loss of one of the pair
4. A gene may undergo horizontal transfer to an organism of another species.
5. A gene may undergo complex patterns of fusion fission or rearrangemnet perhaps involving regions encoding individual protein domains
Homologues / Paralogues/ orthologues
Neutral evolution
Positive selection
Purifying selection
What makes us human?
Comparative genomics
Combining the approaches : the FOXP2 gene
Comparative genomics and study of huan diseases
Genomes of chimpanzees and humans
Genomes of mice and rats
Model organisms for study of human diseases
The genome of Caenorhabditis elegans
The genome of Drosophilia melanogaster
Homologous genes in humans, worms, and flies
The ENCODE project
The modENCODE project
is a systematic development and application of comparative genomics .
It has the ultimate goal of developing methods for comprehensive identification of functional regions of the human genome.
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