Genome Lecture Notes PDF

Summary

This document presents a lecture on genomes, covering topics such as the definition of a genome, its structure, function, evolution, and mapping. It details different types of genomes, such as prokaryotic, eukaryotic, and viral genomes. The lecture also explains repetitive DNA, including microsatellites and tandem repeats.

Full Transcript

Genome

Prof DR Adel Khalil Gohar
Genome
“The branch of molecular biology
concerned with the structure,
function, evolution and mapping
of genomes.”
Genome

Genome: is all the DNA in a cell. - All
the DNA on all the chromosomes
Includes genes, intergenic
sequences, repeats - Specifically, it is
all the DNA in an organelle. -
Eukaryotes can have 2-3 genomes -
Nuclear genome - Mitochondrial
genome - Plastid genome - If not
specified, “genome” usually refers to
the nuclear genome.
Viral Genomes
Viral genomes: ssRNA, dsRNA, ssDNA,
dsDNA, linear or circular Viruses with
RNA genomes: - all ssRNA viruses
produce dsRNA molecules
Prokaryotic Genomes

Haploid, one dsDNA, circular chromosome,
anchored by proteins. Usually without introns.
- 98% of genome is coding. Relatively high gene
density (0.5-10 Mbp, 500-10000 genes).
- Transcription and translation take place in the
same compartment.
- Operons: polycistronic transcription units
- Often indigenous plasmids are present.
Plasmids
Plasmids as Extra chromosomal circular DNAs:
Found in bacteria, yeast and other fungi
Size varies (3,000bp to 100,000bp).
Replicate autonomously, may contain resistance genes
Ability to transfer from one bacterium to another or across kingdoms.
Multi-copy plasmids (~1 –2 up to 400 plasmids/per cell)
Eukaryotic Genome:
Eukaryotic cells package their DNA as 1 molecule/linear chromosome.
Six levels of chromosome packing:
1. DNA duplex (2 nm)
2. Nucleosome fiber(10 nm)
3. 30 nm chromatin fiber
4. Coiled chromatin fiber
5. Coiled coil
6. Metaphase chromosome.
Gene Numbers & Genome Sizes
(C, N and K values)
Gene Numbers: - Number of genes do not correlate with the complexity of
an organism.
Genome Sizes: - The C-value = the DNA content of the haploid genome. -
The units of length of nucleic acids in which genome sizes are expressed : -
Kilobase (Kb) 103 base pairs - Megabase (Mb) 106 base pairs
The 3 Genomic Paradoxes: - C-value paradox: Complexity does not correlate
with genome size. - N-value paradox: Complexity does not correlate with
gene number. - K-value paradox: Complexity does not correlate with
chromosome number.
Large vs. Small Genomes

Polyploidy: having more than 2 sets of chromosomes in the
genome -
Particularly relevant in plants (Auto- or Allopolyploidy).
The amount of non-coding DNA: - Highly repetitive DNA: >
100,000 copies/genome - Moderately repetitive DNA: 100 –
10,000 copies/genome
 Eukaryotic Genomes: - Located on several chromosomes - Relatively low gene density (50 genes
per mm of DNA in humans) - Contour length of DNA from a single human cell = 2 meters -
Approximately 1011 cells = total length 2 x 1011 km - Distance between sun and earth (1.5 x 108
km) - Human chromosomes vary in length over a 25 fold range - Carry organelles genome as well
Mitochondrial Genome (mtDNA)
- Multiple identical circular chromosomes - Size ~15 Kb in animals, - Size ~
200 kb to 2,500 kb in plants
- Over 95% of mitochondrial proteins are encoded in the nuclear genome.
- No introns and Very few repeats
- Often A+T rich genomes. - Mt DNA is replicated before or during mitosis
- 24 of 37genes are RNA coding: 22 mt tRNA and 2 mit ribosomal RNA (23S,
16S) - 13 of 37 genes are protein coding : (synthethized on ribosomes
inside mitochondria) some subunits of respiratory complexes and
oxidative phosphorylation enzymes
some subunits of respiratory complexes and oxidative phosphorylation
enzymes
Chloroplast Genome (cpDNA)
- Multiple circular molecules
- Size ranges from 120 kb to 160 kb
- Similar to mtDNA
- Many chloroplast proteins are
encoded in the nucleus (separate
signal sequence)
Gene

Molecular definition: Entire nucleic acid sequence necessary for the
synthesis of a functional polypeptide (protein chain) or functional
RNA.
Repetitive DNA
Tandem Repeats, Tandem repeats occur in DNA when a
pattern of two or more nucleotides is repeated, and the
repetitions are adjacent to each other.
 Microsatellite DNA

Microsatellite
- Unit - 1-6 bp. Repeat - on the order of 5-100 times. - Location -
Generally euchromatic.
Minisatellite DNA
Unit - 15-400 bp Location - Generally euchromatic. - Examples -
DNA fingerprints. Tandemly repeated but often in dispersed
clusters. Also called VNTR’s (variable number tandem repeats).
Disease due to tandem repeats
VNTR’s (variable number tandem repeats).
Tandemly Repetitive DNA Can Cause Diseases:
- Fragile X Syndrome: “CGG” is repeated hundreds or even
thousands of times creating a “fragile” site on the X
chromosome. It leads to mental retardation.
- Huntington's Disease: “CAG” repeat causes a protein to
have long stretches of the amino acid glutamine. Leads to a
neurological disorder that results in death
Interspersed Repetitive DNA
2) Interspersed Repetitive DNA: - Interspersed repetitive
DNA accounts for 25–40 % of mammalian DNA. They
are scattered randomly throughout the genome. - The
units are 100 – 1000 base pairs long. - Copies are similar
but not identical to each other. -
 Transposons: jumping genes
Interspersed repetitive genes are not stably integrated in the genome; they move from place to
place. These are:
a) Retrotransposons (class I transposable elements) (copy and paste): copy themselves to RNA
and then back to DNA (using reverse transcriptase) to integrate into the genome. Such as; LTR,
SINEs and LINEs.
b) Transposons (Class II TEs) (cut and paste): uses transposases to make makes a staggered sticky
cut.
Transposons (also called transposable elements, or “jumping genes”) are DNA
sequences that move from one genomic location to another. Repeat sequence units
of this type are usually 100 bp to over 10 kb in length, and may appear in over 1
million loci dispersed across the genome.
Noncoding Genomic Elements

Although protein-coding genes are the most studied genomic
element, they may not necessarily be the most abundant part of the
genome. Prokaryotic genomes are usually rich in protein-coding gene
sequences, for example, they account for approximately 90% of the E.
coli genome. In complex eukaryotic genomes, however, their
percentage is lower. For example, only about 1.5% of the human
genome codes for proteins
 - Definition: A gene family is a group of genes that share important
characteristics.
These may be :
a) Structural: have similar sequence of DNA building blocks
Types and (nucleotides). Their products (such as proteins) have a similar
structure or function.
examples of 1) Classical gene families (overall conservativeness) Histones, alpha
Gene Families and beta-globines.
2) Gene families with large conservative domains (other parts could
be low conservative) HLH/bZIP box transcription factors.
Gene families with short conservative motifs e.g. DEAD box (Asp-
Glu-Ala-Asp), WD (TrpAsp) repeat.
Functional gene family : have proteins
produced from these genes work together as
a unit or participate in the same process.

1) Regulatory protein gene families
2) Immune system proteins
3) Motor proteins
4) Signal transducing proteins
5) Transporters
Multigene Families - The classic examples of
multigene families of nonidentical genes- Are two
related families of genes that encode globins.
 Pseudogenes are defective copies of genes. They have lost
their protein-coding ability :
have stop codons in middle of gene
they lack promoters, or
truncated
just fragments of genes.
Pseudogenes accumulation of multiple mutations
Processed pseudogenes copied from mRNA and
incorporated into the chromosome but lack of
protein-coding ability (no intron/ poly-A tail present/
no promoter).
pseudogenes
Non-processed pseudogenes are the result of tandem gene
duplication or transposable element movement. When a functional
gene get duplicated, one copy isn’t necessary for life. Duplicated
Genes. Encode closely related (homologous) proteins, Clustered
together in genome.
Formed by duplication of an ancestral gene followed by mutation.
CpG Islands
Region of the genome with high frequency of CpG sites than the rest
of the genome. Formal Definition - CpG island is a region with at least
200 bp, and a GC percentage that is greater than >50%.
CpG is shorthand for “—C—phosphate—G—” that is, cytosine and
guanine separated by only one phosphatZ CpG islands located in the
promoter regions of genes; therefore, can play important roles in
gene silencing.
Housekeeping genes : Almost all housekeeping genes are associated
with at least one CpG island. Tissue specific genes: About 40 % tissue
specific genes are associated with islands
Genome Sizes
For the least sophisticated organisms, such as Mycoplasma genitalium,
a minimal genome is sufficient. For increased organismal complexity,
more genetic information and, therefore, a larger genome is needed. As
a result, there is a positive correlation between organismal complexity
and genome size, especially in prokaryotes. In eukaryotes, however, this
correlation becomes much weaker, largely due to the existence of
noncoding DNA elements in varying amounts in different eukaryotic
genomes. In terms of total gene number, the currently documented
range is 182 in the genome of Candidatus Carsonella
 The protein-coding regions are the part of the genome that
Protein- we foremost study and know most about. The content of these
regions directly affects protein synthesis and protein diversity
Coding in cells. In prokaryotic cells, functionally related protein-
coding genes are often arranged next to each other and
Regions of the regulated as a single unit known as an operon.

Genome The gene structure in eukaryotic cells is more complicated.
The coding sequences (CDSs) of almost all eukaryotic genes
are not continuous and interspersed among noncoding
sequences. The noncoding intervening sequences are called
introns (int for intervening), whereas the coding regions are
called exons.
During gene transcription, both exons and introns are
transcribed. In the subsequent mRNA maturation process,
introns are spliced out and exons are joined together for
protein translation.
 , the average number of exons per gene is 8.8. The titin gene,
coding for a large abundant protein in striated muscle, has 363
In the human exons, the most in any single gene, and also has the longest single
exon (17,106 bp) among all currently known exons. The total
genome, number of currently known exons in the human genome is around
180,000. With a combined size of 30 Mb, they constitute 1% of the
exome, human genome.
This collection of all exons in the human genome, or in other
trascriptome eukaryotic genomes, is termed as the exome. Different from the
transcriptome, which is composed of all actively transcribed
clinical exome mRNAs in a particular sample, the exome includes all exons
contained in a genome. Although it only covers a very small
percentage of the genome, the exome represents the most
important and the best annotated part of the genome. Sequencing
of the exome has been used as a popular alternative to whole
genome sequencing. While it lacks on coverage, exome sequencing
is more cost effective, faster, and easier for data interpretation.
DNA Sequence Mutation and Polymorphism

Although DNA replication is a high-fidelity process and the nucleus maintains an
army of DNA repair enzymes, sequence mutation does happen, though at a very
low frequency. In general, the rate of mutation in prokaryotic and eukaryotic cells
is at the scale of 10–9 per base per cell division. In multicellular eukaryotic
organisms, germline cells have a lower mutation rate than somatic cells. In these
organisms, because most cells, including germline cells, undergo multiple
divisions in the organisms’ lifetime, the per-generation mutation rate is
significantly higher. For example, whole genome sequencing data collected
from human blood cell DNA estimates a mutation rate of 1.1 × 108 per base
per generation, corresponding to about 70 new mutations in each human diploid
genome. Depending on the nature of the change, mutations may have deleterious,
neutral, or, rarely, beneficial effects on the organism.
 There are various forms of DNA mutations, from single nucleotide
substitutions, to small insertions/deletions (or indels), to structural
variations (SVs) that involve larger genomic regions. Among these
different types of mutations, single nucleotide substitutions, also
called point mutations, are the most common. These substitutions
can be either transitions or transversions. Transitions involve the
substitution of a purine for the other purine (i.e., A↔G) or a
pyrimidine for the other pyrimidine (i.e., C↔T).
Genome Evolution

Mutation
The spontaneous mutations that lead to sequence variation and
polymorphism in a population are also the fundamental force. Gradual sequence change and diversification of early genomes, over
billions of years, have evolved into the extremely large number of genomes
that had existed or are functioning in varying complexity today. In this
process, existing DNA sequences are constantly modified, duplicated, and
reshuffled. Most mutations in protein-coding or regulatory sequences
disrupt the protein’s normal function or alter its amount in cells, causing
cellular dysfunction and affecting organismal survival. Under rare
conditions, however, a mutation can improve existing protein function or
lead to the emergence of new functions. If such a mutation offers its host a
competitive advantage, it is more likely to be selected and passed on to
future generations.
Genome evolution : duplication
Gene duplication provides another major mechanism for genome
evolution. If a genomic region containing one or multiple gene(s) is
duplicated resulting in the formation of an SV, the duplicated region is
not under selection pressure and therefore becomes substrate for
sequence divergence and new gene formation. Although there are
other ways of adding new genetic information to a genome such as
interspecies gene transfer, DNA duplication is believed to be a major
source of new genetic information generation.
Gene family as model (olfactory receptors)
Gene duplication often leads to the formation of gene families. Genes in the
same family are homologous, but each member has its specific function and
expression pattern. As an example, in the human genome there are 339 genes in
the olfactory receptor gene family. Odor perception starts with the binding of
odorant molecules to olfactory receptors located on olfactory neurons inside the
nose epithelium. To detect different odorants, a combination of different
olfactory receptors that are coded by genes in this family is required. Based on
their sequence homology, members of this large family can be even further
grouped into different subfamilies.
DNA recombination role in genome evolution
DNA recombination, or reshuffling of DNA sequences, also plays an
important role in genome evolution. Although it does not create new
genetic information, by breaking existing DNA sequences and rejoining
them, DNA recombination changes the linkage relationships between
different genes and other important regulatory sequences. Without
recombination, once a harmful mutation is formed in a gene, the mutated
gene will be permanently linked to other nearby functional genes, and it
becomes impossible to regroup all the functional genes into the same DNA
molecule. Through this regrouping, DNA recombination makes it possible
to avoid gradual accumulation of harmful gene mutations. Most DNA
recombination events happen during meiosis in the formation of gametes
(sperm or eggs) as part of sexual reproduction.
Genome Sequencing and Disease Risk
New sequencing technologies, has uncovered extensive sequence variation in individual
genomes within a population. The extensiveness in sequence variation was not envisioned
in early days of genetics, not even when the Human Genome Project was completed in
2003.
This has gradually led to a paradigm shift in disease diagnosis and prevention. As a result,
the public becomes more aware of the role of individual genomic makeup in disease
development and predisposition.
In addition, the easier accessibility to our DNA sequence has further prompted us to look
into our genome and use that information for preemptive disease prevention. The
declining cost of genome sequencing has also enabled the biomedical community to dig
deeper into the genomic underpinnings of diseases, by unraveling the linkage between
sequence polymorphism in the genome and disease incidence.
Following is a brief overview of the major categories of human diseases that have an
intimate connection with DNA mutation, polymorphism, genome structure, and
epigenomic abnormality.
Mendelian Single-Gene Diseases
The simplest form of hereditary diseases is caused by mutation(s) in a single gene, and
therefore called monogenic or Mendelian diseases. For example, sickle cell anemia is
caused by a mutation in the HBB gene located on the human chromosome 11.
This gene codes for the β subunit of hemoglobin, an important oxygen-carrying protein
in the blood. A mutation of this gene leads to the replacement of the sixth amino acid,
glutamic acid, with another amino acid valine in the coded protein. This change of a
single amino acid causes conformational change of the protein, leading to the generation
of sickle-shaped blood cells that die prematurely. This disease is recessive, meaning that
it only appears when both copies (or alleles) of the gene carry the mutation. In dominant
diseases, however, one mutant allele is enough to cause sickness.
Huntington’s disease, a neurodegenerative disease that leads to gradual loss of mental
faculties and physical control, is such a dominant single-gene disease. It is caused by
mutation in a gene called HTT on the human chromosome 4, coding for a protein called
huntingtin. The involved mutation is an expanded and unstable trinucleotide (CAG)
repeat. Individuals carrying one copy of the mutant HTT gene usually develop the disease
later in life.
2 Complex Diseases That Involve Multiple
Genes
Most common diseases, including heart disease, diabetes, hypertension,
obesity, and Alzheimer’s disease (AD), are caused by multiple genes. In the
case of AD, while its familial or early-onset form can be attributed to one of
three genes (APP, PSEN1, and PSEN2), the most common form, sporadic
AD, involves a large number of genes.
In this type of complex diseases, the contribution of each gene is modest,
and it is the combined effects of mutations in these genes that predispose
an individual to these diseases. Besides genetic factors, lifestyle and
environmental factors often also play a role in these complex diseases. For
example, a history of head trauma, lack of mentally stimulating activities,
and high cholesterol levels are all risk factors for developing AD. Because of
the number of genes involved and their interactions with nongenetic
factors, complex multigene diseases are more challenging to study than
single-gene diseases.
Diseases Caused by Genome Instability
Diseases can also occur as consequences of large-scale genomic changes such as
rearrangement of large genomic regions, alterations of chromosome number, and
general genome instability. For example, when a genome becomes unstable in an
organism, it can cause congenital developmental defects, tumorigenesis,
premature aging, and so forth. Dysfunction in genome maintenance, such as DNA
repair and chromosome segregation, can lead to genome instability.
Fanconi anemia, a disease caused by genome instability, is characterized by
growth retardation, congenital malformation, bone marrow failure, high cancer
risk, and premature aging. The genome instability in this disease is caused by
mutations in a cluster of DNA repair genes, and manifested by:
increased mutation rates, cell cycle disturbance, chromosomal breakage, and
extreme sensitivity to reactive oxygen species and other DNA damaging agents.

Diseases Caused by Genome Instability
Aside from the gene-centered disease models introduced earlier, diseases can also occur as
consequences of large-scale genomic changes such as rearrangement of large genomic regions,
alterations of chromosome number, and general genome instability. For example, when a genome
becomes unstable in an organism, it can cause congenital developmental defects, tumorigenesis,
premature aging, and so forth. Dysfunction in genome maintenance, such as DNA repair and
chromosome segregation, can lead to genome instability. Fanconi anemia, a disease caused by
genome instability, is characterized by growth retardation, congenital malformation, bone
marrow failure, high cancer risk, and premature aging. The genome instability in this disease is
caused by mutations in a cluster of DNA repair genes, and manifested by increased mutation
rates, cell cycle disturbance, chromosomal breakage, and extreme sensitivity to reactive oxygen
species and other DNA damaging agents.
Cancer, to a large degree, is also caused by genome instability. This can be hinted by the fact that
two well-known high-risk cancer genes, BRCA1 and BRCA2, are both DNA damage repair genes.
Mutations in the two genes greatly increase the susceptibility to tumorigenesis, such as breast
and ovarian cancers. In general, many cancers are characterized by chromosomal aberrations and
genome structural changes, involving deletion, duplication, and rearrangement of large genomic
regions. The fact that genome instability is intimately related to major aspects of cancer cells,
such as cell cycle regulation and DNA damage repair, also points to the important role of genome
instability in cancer development.
 Epigenomic/Epigenetic Diseases
Besides gene mutations and genome instability, abnormal epigenomic/ epigenetic patterns can
also lead to diseases. Examples of diseases in this category include fragile X syndrome, ICF
syndrome, Rett syndrome, and Rubinstein-Taybi syndrome.
In ICF syndrome, for example, the gene DNMT3B is mutated leading to the deficiency of DNA
methyltransferase 3B. Patients with this disease invariably have DNA hypomethylation, and have
symptoms such as facial anomaly, immunodeficiency, and chromosome instability.
Cancer, as a genome disease that is caused by more than one genetic/genomic factor, is also
characterized by abnormal DNA methylation, including both hypermethylation and
hypomethylation.
The hypermethylation is commonly observed in the promoter CpG islands of tumor suppressor
genes, which leads to their suppressed transcription. The hypomethylation is mostly located in
highly repetitive sequences, including tandem repeats in the centromere and interspersed
repeats. This lowered DNA methylation has been suggested to play a role in promoting
chromosomal rearrangements and genome instability.
 Thank you