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13th International Conference on Proteomics, Genomics and Bioinformatics, will be organized around the theme “Leading Edge Innovations in Life Sciences”

Proteomics 2020 is comprised of 19 tracks and 104 sessions designed to offer comprehensive sessions that address current issues in Proteomics 2020.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

Register now for the conference by choosing an appropriate package suitable to you.

Bioinformatics is an interdisciplinary field that develops methods and software tools for understanding biological data. As an interdisciplinary field of science, bioinformatics combines computer science, statistics, mathematics, and engineering to analyse and interpret biological data.

  • Track 1-1Protein sequence databases and their use
  • Track 1-2Protein sequence data in UniProt
  • Track 1-3Protein sequence data in UniProt
  • Track 1-4Post-translational modifications
  • Track 1-5Standardisation of proteomics data
  • Track 1-6MS proteomics repositories and the ProteomeXchange consortium
  • Track 1-7PRIDE and PRIDE-related tools
  • Track 1-8Proteogenomics

Computational Biology involves the improvement and application of statistics-analytical and theoretical methods, mathematical modelling and computational simulation techniques to the study of organic, behavioural, and social structures. The field is widely described and includes foundations in biology, applied mathematics, data, biochemistry, chemistry, biophysics, molecular biology, genetics, genomics, pc technological know-how and evolution.

Computational biology is different from biological computing, that's a subfield of computer technology and computer engineering using bioengineering and biology to build computer systems but is just like bioinformatics, that is an interdisciplinary science using computer systems to store and system biology information.

  • Track 2-1Data mining and Machine Learning
  • Track 2-2Computational anatomy
  • Track 2-3Artificial Intelligence
  • Track 2-4Computational biomodeling

Protein structure is the three-dimensional arrangement of atoms in a protein molecule. Proteins are polymers specifically polypeptides formed from sequences of amino acids, the monomers of the polymer. A single amino acid monomer may also be called a residue indicating a repeating unit of a polymer. Proteins form by amino acids undergoing condensation reactions, in which the amino acids lose one water molecule per reaction in order to attach to one another with a peptide bond. By convention, a chain of 30 amino acids is often identified as a peptide, rather than a protein. This is the topic of the scientific field of structural biology, which employs techniques such as X-ray crystallography, NMR spectroscopy, and dual polarisation interferometry to determine the structure of proteins.


  • Track 3-1Structure classification
  • Track 3-2Computational prediction of protein structure
  • Track 3-3Protein structure databases
  • Track 3-4Protein Sequence Analysis
  • Track 3-5Protein structure determination
  • Track 3-6Protein stability
  • Track 3-7Protein folding
  • Track 3-8Protein dynamics
  • Track 3-9Levels of protein structure

Electrospray ionization (ESI) is a technique used in mass spectrometry to produce ions using an electrospray in which a high voltage is applied to a liquid to create an aerosol. Liquid chromatography is an analytical chemistry technique that combines the physical separation capabilities of liquid chromatography (or HPLC) with the mass analysis capabilities of mass spectrometry (MS). Multidimensional Protein Identification Technology (MudPIT) is used to analyze the proteomes of organisms. Protein purification is a series of processes intended to isolate one or a few proteins from a complex mixture, usually cells, tissues or whole organisms. Imaging mass spectrometry (IMS) using matrix-assisted laser desorption ionization (MALDI) is a new and effective tool for molecular studies of complex biological samples such as tissue sections.


  • Track 4-1Protein identification
  • Track 4-2De novo (peptide) sequencing
  • Track 4-3Protein quantitation
  • Track 4-4Protein structure determination
  • Track 4-5Proteogenomics

The proteome of each living cell is dynamic, altering in response to the individual cell's metabolic state and reception of intracellular and extracellular signal molecules, and many of the proteins which are expressed will be post-translationally altered. Thus if the purpose of the proteome analysis is to aid the understanding of protein function and interaction, then it is the identification of the proteins in their final state which is required: for this mass spectrometric identification of individual proteins, indicating site and nature of modifications, is essential.


  • Track 5-1Gel based proteomics
  • Track 5-2Shotgun proteomics
  • Track 5-3Studies in biological fluids
  • Track 5-4Salinity Tolerance
  • Track 5-5Photosynthesis
  • Track 5-6Late-Embryogenesis Abundant (LEA) Proteins
  • Track 5-7Oxidative Stress/Antioxidants

Epigenomics is the study of the complete set of epigenetic modifications on the genetic material of a cell, known as the epigenome. The field is analogous to genomics and proteomics, which are the study of the genome and proteomeof a cell.  Epigenetic modifications are reversible modifications on a cell’s DNA or histones that affect gene expression without altering the DNA sequence. Epigenetics are stable heritable traits (or "phenotypes") that cannot be explained by changes in DNA sequence. Epigenetics often refers to changes in a chromosome that affect gene activity and expression but can also be used to describe any heritable phenotypic change that doesn't derive from a modification of the genome, such as prions. Such effects on cellular and physiological phenotypic traits may result from external or environmental factors, or be part of the normal developmental program. The standard definition of epigenetic requires these alterations to be heritable, either in the progeny of cells or of organisms.

  • Track 6-1DNA methylation
  • Track 6-2Histone modification
  • Track 6-3ChIP-Chip and ChIP-Seq
  • Track 6-4Genome wide approaches
  • Track 6-5Direct detection

Proteins are a primary constituent of living things and one of the chief classes of molecules studied in biochemistry. Proteins provide most of the molecular machinery of cells. Many are enzymes or subunits of enzymes. Other proteins play structural or mechanical roles, such as those that form the struts and joints of the cytoskeleton. Each protein is linear polymers built of amino acids.


Genomics refers to the study of the genome in contrast genetics which refers to the study of genes and their roles in inheritance. Genomics can be considered a discipline in genetics. It applies recombinant DNA, DNA sequencing methods, and bioinformatics to sequence, assemble and analyse the function and structure of genomes (the complete set of DNA within a single cell of an organism). Advances in genomics have triggered a revolution in discovery-based research to understand even the most complex biological systems such as the brain. The field includes efforts to determine the entire of DNA sequence organisms and fine-scale genetic mapping.

  • Track 8-1Functional genomics
  • Track 8-2Structural genomics
  • Track 8-3Epigenomics
  • Track 8-4Metagenomics
  • Track 8-5Model systems


<p style="\&quot;text-align:" justify;\"="">\r\n Structural genomics seeks to depict the 3-dimensional structure of each protein encoded by a given genome. This genome-based approach takes into consideration a high-throughput technique for structure assurance by a combination of experimental and modelling approaches. The important contrast between structural genomics and traditional structure prediction is that structural genomics endeavors to decide the structure of each protein encoded by the genome, instead of concentrating on one specific protein. With full-genome arrangements accessible, structure prediction should be possible all the more rapidly through a combination of experimental and modelling approaches, particularly in light of the fact that the accessibility of expansive number of sequenced genomes and beforehand explained protein structures enables researchers to display protein structure on the structures of previously solved homologs


  • Track 9-1Modelling Threading
  • Track 9-2Structure databases
  • Track 9-3Traditional structural prediction
  • Track 9-4Structural homology
  • Track 9-5Structural homology
  • Track 9-6Structural bioinformatics

Systems biology is the computational and mathematical modelling of complex biological systems. An emerging engineering approach applied to biological scientific research, systems biology is a biology-based interdisciplinary field of study that focuses on complex interactions within biological systems, using a holistic approach (holism instead of the more traditional reductionism) to biological research. Computational biology involves the development and application of data-analytical and theoretical methods, mathematical modelling and computational simulation techniques to the study of biological, behavioural, and social systems. The field is broadly defined and includes foundations in computer science, applied mathematics, animation, statistics, biochemistry, chemistry, biophysics, molecular biology, genetics, homology, genomics, ecology, evolution, anatomy, neuroscience, and visualization.


  • Track 10-1Multicellular systems biology
  • Track 10-2Pathways and networks
  • Track 10-3Application of LC-MS in plant metabolomics
  • Track 10-4Neurodegenerative diseases
  • Track 10-5Xenobiotics

Biomedical research is in general simply known as medical research. It is the basic research, applied research, or translational research conducted to aid and supports the development of knowledge in the field of medicine. An important kind of medical research is clinical research, which is distinguished by the involvement of patients. Other kinds of medical research include pre-clinical research, for example on animals, and basic medical research, for example in genetics.

  • Track 11-1Critical use of clinical information
  • Track 11-2Translational medicine
  • Track 11-3Clinical product development
  • Track 11-4Conceptual frameworks from top-down

Protein sequencing is the practical process of determining the amino acid sequence of all or part of a protein or peptide. This may serve to identify the protein or characterize its post-translational modifications. Typically, partial sequencing of a protein provides sufficient information (one or more sequence tags) to identify it with reference to databases of protein sequences derived from the conceptual translation of genes.

Molecular Interactions are attractive or repulsive forces between molecules and between non-bonded atoms. Molecular interactions are important in diverse fields of protein folding, drug design, material science, sensors, nanotechnology, separations, and origin of life. Molecular interactions are also known as non-covalent interactions or intermolecular interactions. Molecular interactions are not bonds.

  • Track 12-1Determining amino acid composition
  • Track 12-2N-terminal amino acid analysis
  • Track 12-3C-terminal amino acid analysis
  • Track 12-4Edman degradation
  • Track 12-5Identification by mass spectrometry
  • Track 12-6Predicting from DNA/RNA sequences

Machine learning is closely related to computational statistics, which also focuses on prediction-making through the use of computers. It has strong ties to mathematical optimization, which delivers methods, theory and application domains to the field. Machine learning is sometimes conflated with data mining, where the latter subfield focuses more on exploratory data analysis and is known as unsupervised learning.


  • Track 13-1Microarrays
  • Track 13-2Stroke Diagnosis
  • Track 13-3Text mining

Immunogenetics has a critical part in the examination of single characteristics of genes and their part in the manner in which traits or conditions are passed beginning with one time then onto the following. The examination of the atomic and cell parts that include the protected structure, including their ability and association turns into the central craft of immunology. Immune system infections, for example, type 1 diabetes, are complex genetic characteristics which result from defects in the immune system Distinguishing proof of qualities characterizing the insusceptible deformities may recognize new target qualities for remedial methodologies. Then again; genetic assortments can in like manner describe the immunological pathway provoking illness.


  • Track 14-1Granulocyte Immunology
  • Track 14-2Genes and Immunity
  • Track 14-3Immunogenetics and Pharmacogenetics
  • Track 14-4Vasculitis and Autoimmune Disease
  • Track 14-5Platelet Immunology
  • Track 14-6Genetics of Allo Antigens
  • Track 14-7Genetic control of immune cell activation
  • Track 14-8Chronic Inflammation
  • Track 14-9Immunogenicity

Current transcriptomic profiling techniques include DNA microarray, cDNA amplified fragment length polymorphism (cDNA-AFLP), expressed sequence tag (EST) sequencing, serial analysis of gene expression (SAGE), massive parallel signature sequencing (MPSS), RNA-seq etc. The most recent technology for transcriptomic profiling is RNA-Seq which is considered as a revolutionary tool for this purpose. Eukaryotic transcriptomic profiles are primarily analyzed with this technique and it has been already applied for transcriptomic analysis of several organisms including Saccharomyces cerevisiae, Schizosaccharomyces pombe, Arabidopsis thaliana, mouse and a human cell.

  • Track 15-1Isolation of RNA
  • Track 15-2Expressed sequence tags
  • Track 15-3Expressed sequence tags
  • Track 15-4Image processing
  • Track 15-5Diagnostics and disease profiling
  • Track 15-6Human and pathogen transcriptomes

Pharmacogenomics is the study of the role of the genome in drug response. Its name (pharmacy + genomics) reflects it’s combining of pharmacology and genomics. Pharmacogenomics analyzes how the genetic makeup of an individual affects his/her response to drugs. It deals with the influence of acquired and inherited genetic variation on drug response in patients by correlating gene expression or single-nucleotide polymorphisms with pharmacokinetics (drug absorption, distribution, metabolism, and elimination) and pharmacodynamics (effects mediated through a drug's biological targets).


  • Track 16-1Drug-metabolizing enzymes
  • Track 16-2Predictive prescribing
  • Track 16-3Clinical implementation
  • Track 16-4Polypharmacy
  • Track 16-5Drug labeling

The high demand for low-cost sequencing has driven the development of high-throughput sequencing, which also goes by the term next-generation sequencing (NGS). Thousands or millions of sequences are concurrently produced in a single next-generation sequencing process. Next-generation sequencing has become a commodity. With the commercialization of various affordable desktop sequencers, NGS has become within the reach of traditional wet-lab biologists. As seen in recent years, the genome-wide scale computational analysis is increasingly being used as a backbone to foster novel discovery in biomedical research.


  • Track 17-1Illumina (Solexa) sequencing
  • Track 17-2Roche 454 sequencing
  • Track 17-3Ion Torrent: Proton / PGM sequencing

Genetic Counselling is the procedure by which the patients or relatives at risk of an acquired disorder (or might convey a kid at risk) are advised with the outcomes and nature of the disorder, the likelihood of creating or transmitting it, and the choices open to them in management and family planning. This mind boggling procedure can be isolated into indicative (the real estimation of hazard) and supportive aspects.


  • Track 18-1Gene Polymorphism
  • Track 18-2Regenerative Medicine
  • Track 18-3Gene Editing and CRISPR Based Technologies
  • Track 18-4Viral Gene Therapy
  • Track 18-5Ethical issues Related to Gene Therapy
  • Track 18-6Advanced Therapy production


<p style="\&quot;text-align:" justify;\"="">\r\n The nanomaterial has admired qualities to equilibrate boss components which pick biocatalysts proficiency, including a particular surface territory, mass exchange confirmation and productive compound stacking. This review displays the current circumstance and frameworks in compound immobilization. A couple of methods are used which are capable to join proteins/synthetic substances with nanoparticles. Immobilization process is to overhaul the operational execution of an impetus for mechanical applications. So far different cross sections have been portrayed in the written work to improve the execution of the immobilized proteins. With the incident to nanotechnology, the nanomaterial due to their one of a kind physical - substance properties constitute novel and charming frameworks for compound immobilization.




  • Track 19-1Enzyme nanoparticles
  • Track 19-2DNA nanotechnology
  • Track 19-3Nanotechnology products
  • Track 19-4DNA microarray
  • Track 19-5Nanopolymers
  • Track 19-6Nanotechnology in targeted drug delivery
  • Track 19-7Immobilization using nanoparticles
  • Track 19-8Nanotechnology enabled enzyme activity