Introduction to Omics Science PDF

Summary

This document provides an introduction to omics science, detailing the different subcategories and their applications in various fields. It also discusses the role of bioinformatics in analyzing molecular data.

Full Transcript

Chapter-1: Introduction to omics science
 What is –Omics Sciences?
 In biological context. the suffice –omics is used to
refer study of large set of biological molecules.
 The realization of that DNA alone not regulate
complex biological process.
 as result of triggered rapid development of several
fields in molecular biology that together described
with the term OMICs

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The Omics term is used with suffix -ome to
address the study of field in
 genomics for genome,
 proteomics for proteome,
 metabolomics for metabolome, and
many more.
 Omics reflects the use of diverse technologies
to gain an insight into the complexity of
biomolecules influencing the structure and
function of organisms.

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 The omics-driven research has led to
understanding of complex regulatory
networks that controls:
gene expression,


 protein modification, and
 metabolite composition.
 Transcriptomics, metabolomics, bioinformatics, and
high-throughput DNA sequencing led to the
deciphering of diverse regulatory networks in different
systems resulting in enhanced understanding for its
potential applications in clinical diagnosis, prognosis,
and therapeutic purposes

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4 compiled by Tola B,
1.2 Types of Omics Sciences
 The field of -omics sciences has been
divided into the following main
categories :
 Genomics
 Trancriptomics
 Proteomics
 Metabolomics
 Bioinformatics (tool)

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 Genomics
 Genomics : the study of the genome in
totality and is further classified into several
sub branches:
comparative genomics
Structural genomics
Functional genomics
Epigenomics
Meta genomics
Personal genomics
Cogenetve genomics

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Comparative genomics
Comparative genomics: field of omics science in
which the genome features of different organisms are
compared.
 The genomic features may include the:
 DNA sequence
 Gene
 gene order
 regulatory sequences and
 other genomic structural landmarks

 provides an insight into the evolutionary
aspects of organisms compared based on the
sequences at whole genome level.
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 useful to understand the variability in terms of
functional DNA segments, such as coding exons,
noncoding RNAs, and also some gene regulatory
regions.
 The genome sequences are compared by aligning
them to score the match or mismatch between them.
 Various softwares and algorithms have been developed for the
alignment of several genome sequences simultaneously and
elucidate genome evolution and function.

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9 compiled by Tola B,
 Functional genomics
 Functional genomics :is the study of how genes and
intergenic regions of the genome contribute to
different biological processes.
 Uses means of genome-wide analysis through high-
throughput methods
 Focuses on the functional aspects such as:
 regulation of gene expression,
 functions and
 interaction of different genes, etc

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11 compiled by Tola B,
 Structural genomics
 It aims to decipher the 3D structure of all
proteins encoded by a particular genome
using either experimental tools or in silico
tools or sometimes both.
 The structure of the total number
of identified protein of particular
genome is determined while in
traditional structural prediction,
structure of only one particular
protein is determined.
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 Through the availability of full genome
sequences of number of organisms, structural
prediction can be done by using both the
experimental and modeling approaches, as well
as previously known protein structures.
Thesequence-structure–function
relationship provides an opportunity to
analyze the putative functions of the
identified proteins of an organism under
purview of structural genomics

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14 compiled by Tola B,
 Epigenomiics
 Epigenomccs :refers to the external modification of
DNA.
 It alters the physical structure of DNA without
altering the DNA sequence. E. g The DNA
methylations, that is, the addition of a methyl group,
or a “chemical cap,” to part of the DNA molecule and
histone modification
 focused on the epigenetic regulation of genome
expression.
 Study of epigenetic process (expression not involving
DNA on target (ultimately genome wide scale.

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 Metagenomics
 Metagenomics is emerging as an important discipline to access the
biocatalytic potential of uncultivable microorganisms.
 Despite very rich microbial diversity of the range of a million
species per 1 g of soil, very few microorganisms can be cultured
under in vitro conditions.
 With the advances made in the field of metagenomics, DNA can
be extracted from environmental samples from which
genomic library can be prepared. This library can be further
explored by screening the clones for biological activity to identify
clones possessing desired characteristics.
 A number of biocatalysts such as laccase, xylanase,
endoglucanase, exoglucanase, and lipase have been recently
identified from metagenomic libraries

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18 compiled by Tola B,
 Cognitive genomics
 Cognitive genomics is the sub-field
of genomics pertaining to cognitive function in
which the genes and non-coding sequences of
an organism's genome related to the health and
activity of the brains are studied

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20 compiled by Tola B,
 Personal genomics
 Single nucleotide polymorphism (SNP), copy number
variation, and complex structural variations can be typed with
the help of sequencing data.
 initiated to truly understand the genesis of most complex
human traits—from deadly diseases to the talents and other
features that makes every individual unique.
 useful for disease management and understanding of human
health. It also deals with the ethical, legal, and social issues
(ELSI) related to personal genomics.

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Trancritomics
 Trancriptomics :is the study of total RNAs in
particular cell or tissue or organism.
 focused on the genome expression
 The abundances of specific mRNAs transcripts in a
biological samples is reflection of the expression level of
the correspondent genes

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 Is used in gene expression profiling:
 The identification and characterization of the
mixture of mRNAs that is expressed in specific
samples
 Applicable :To associate different mRNAs mixture
from deferent group of individuals to phenotype
differences between the groups.
 Challenge: the trancriptoeme in contrast to genome is
highly variable over time between cell type s and
environmental change.

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 It deals with the study of the complete set of
RNAs/transcriptomes encoded by the genome of a cell or
organism at a specific time and under a specific set of
conditions.
 The techniques that are frequently used for genome-wide
analysis for gene expression are:
 complementary DNA (cDNA) microarrays and
protein microarrays,
 cDNA–amplified fragment length polymorphism
(AFLP), and
 serial analysis of gene expression (SAGE).

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26 compiled by Tola B,
Proteomics
 Proteomics is a comprehensive study of proteins in totality
identified in a cell, organ, or organism at a particular time’
Proteomics can categorized into the following
categories
 Expression proteomics
 Structural proteomics
 Functional proteomics

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 Expression proteomics
 Expression proteomics is the quantitative comparison of
protein expression throughout the entire proteome of
different samples. Structural proteomics
 Structural proteomics, or cell-map proteomics maps out
the structure of the proteins present in a specific cellular
organelle.
 It allows for the identification of all proteins, determines
where they are located and characterizes all of their
interactions. In turn, this helps to understand the overall
architecture of cells and provides an explanation for why
certain proteins result in unique phenotypes.
 Functional proteomics is area is aimed at discovering the
biological function of unknown proteins and defining
cellular mechanisms at the molecular level.
 E.g Proteome mining is a functional proteomics approach
that is used to extract as much protein information as
possible.

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 Metabolomics

 Metabolomics is a branch of omics associated
with study of metabolites of an organism in
totality. Important in:
 pharmacological studies,
 functional genomics,
 toxicology,
 drug discovery,
 nutrition,
 cancer, and diabetes

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 Metabolism

 The diverse chemical reactions leading to
growth and development of an organism is
often referred to as metabolism and
includes both anabolic and catabolic
reactions

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32 compiled by Tola B,
Bioinformatics
 Bioinformatics is the application of information technology
to the field of molecular biology.
 Bioinformatics is the field of science in which biology and
information technology merged into a single discipline.
 Bioinformatics is the science of managing, mining, integrating, and
interpreting information from biological data at the
genomic,metabalomic,proteomic, phylogenetic, cellular, or whole
organism levels

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 Biologist
Collect molecular data
DNA, RNA, gene &
protein etc Bioinformatics
Study biological
question by
analyzing
Computer scientist molecular data
Mathematics , statistics
Develop tools,
software, algorithm to
store and analyze data.

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35 compiled by Tola B,
1.3 Application of sciences of –omics in
different fields:
 The science of omics has diverse application as discussed in
the following
 Assessment of genome structure and function: A large
volume of information can be generated through high-
throughput screening, which in turn can be used for studying
structural and functional aspects of genomes.

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37 compiled by Tola B,
2. Application in plant metabolomics: Used to interpret
plant growth and functions based on metabolite analysis by
sophisticated tools influencing the quality of food or plant
derived medicines.
3.Toxicogenomics for assessment of environmental
pollution: Allows large-scale screening of huge number of
biological samples as potential toxicants.

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4. Therapeutic application of genomics: Useful for gene-
based diagnosis and treatment of individuals. Also helpful to
manage epidemics and develop new therapies.
5. Microbial omics and its approaches in biofuel
production: Complex microbial communities can be screened
by metagenomics for targeted screening of enzymes with
industrial applications in biofuel production.
6. In crop improvement: Genomics-based tools for crop
improvements are being used with the availability of genome
sequences of several crops. Several types of molecular
markers have been developed associated with different
agronomics traits.

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7. Evolution and diversity studies: Useful in studying
evolutionary relatedness.
8. Analysis of RNA editing: RNA editing is a post-
transcriptional event that recodes hereditary information.
 RNA editing is an integral step in generating the diversity
and plasticity of cellular RNA signatures.
9. Biomarker for medical research: Disease-related
biomarkers are helpful in disease prediction, which may develop
over time.
Tools for aligning sequences using pairwise and multiple-
sequence alignment.

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10. Drug discovery: Involved in the drug discovery process
ranging from screening hits to its efficacy, stability, and
bioavailability
11. Pathological studies: Pathology is the precise study and
diagnosis of disease.
12. Clinical toxicology: Involved in the improvement of the
drug safety assessment process

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