BIOCHEMISTRY AND MOLECULAR BIOLOGY

Subatomic technology is concerned with the subatomic premise of herbal action between the various frameworks of a cell, which include collaborations between various types of DNA, RNA, and proteins and their biosynthesis, and focuses on how these institutions are managed. It has a wide range of applications, including excellent disease sub-atomic system detection and remedial methodologies like cloning, articulation, and high-quality production. The study area includes fine articulation, epigenetics and chromatin shape and capacity, RNA making readiness, non-coding RNA elements, and translation. Molecular technology, DNA replication, repair and recombination, transcription, RNA handling, post-translational exchange, proteomics, mutation, site-coordinated mutagenesis, and other topics are currently being researched. Epigenetics, chromatin structure, and capacity, to name a few. Maladies' Molecular Systems

• DNA replication, repair and recombination
• Interpretation and Gene Expression
• RNA handling
• Atomic instruments of maladies
• DNA replication, repair and recombination
• Interpretation and Gene Expression
• Molecular cloning
• Protein Behaviour
• Macromolecular Interaction
• Chemical Biology
• Protein Function

The department of medicinal drugs requisite for such natural chemistry and digestion of human well-being and pollutants has been known as restorative natural chemistry. The therapeutic scientist is educated in the management and operation of clinical natural chemistry labs and works as an expert in all aspects of their use. The medical clinical expert controls clinical research facilities, counselling, and decisions, as well as treating patients with a variety of metabolic difficulties and biochemical irregularities. Medicinal natural chemistry explains the behaviour of common and pathologic creatures from a biochemical standpoint. One could gain a solid understanding of the consequences of natural chemistry while seducing the inquiry and exploratory aptitudes through modules in neurodegenerative disorders, difficulty, and restorative strength.

• Protein structure and dynamics
• Forensic biochemistry
• Histopathology
• Pharmacokinetics
• Pharmacodynamics

The investigation is managed by the examination of Nano scale structures, which use components or frameworks 109 times smaller than the average size of parts. Natural chemistry regulates various metabolic and biochemical processes at the interstices of residing animals. The combination of both of these breakthroughs resulted in the estimated start of Nano natural chemistry. This learning-based blend of connected science and natural chemistry will produce one-of-a-kind, inventive contraptions. The term "related science" in the natural sciences refers to the development of substances and devices that are specifically designed to function in the body.

• Biosensors
• Nano medicines and interactions
• Bio molecular detection strategies
• Structural DNA nanotechnology

Proteomics is the study of proteins on a large scale. Proteins are required by all living things and serve a variety of roles. The proteome is the entire group of proteins that can be added to or changed by a living structure or framework. These changes occur as a result of moments as well as distinctive essentials, or stresses, that such a cell or creature encounters. Antibodies to specific proteins or their altered systems have been used in organic chemistry and cellular technology. These are several well-known subatomic scientists' devices today. There are several specific strategies and conventions for using antibodies for protein recognition. Atomic technology is concerned with the subatomic premise of natural movement among biomolecules within the various structures of a living organism.

• Techniques of molecular biology
• Molecular engineering & microbiology
• Molecular modelling & protein structure prediction
• Clinical & structural biochemistry
• Molecular & analytical biochemistry
• Nano & medical biochemistry

Glycobiology is the study of the structure, composition, and technology of cosmopolitan saccharides. Sugars or saccharides are basic components of all living things that are being researched in particular therapeutic, herbal advanced technologies, and biotechnological fields. The study of such subatomic underpinnings as replication, interpretation, and cell painting methods is known as atomic technology. Despite being a distorted image of subatomic technology, the central authoritative opinion of subatomic technology, in which hereditary material is transcribed into RNA and then transformed into protein, serves as a good starting point for information in the field.

• Structural Glycobiology
• Microbial Glycobiology
• Cellular Glycobiology
• Systems Glycobiology
• Molecular Glycobiology

Plant organic chemistry is a linked body of scientific knowledge that has the ability to contribute to the assimilation of horticultural and pharmaceutical problems. Plants provide important modern raw materials, including fats and starch, and yet they may also be the source of pharmaceutics development. The study of different synthetic reactions that take place in advance within a group of animals over time is known as animal biochemistry. The study concentrated on animal natural chemistry, which is critical to comprehending actual elements of veterinary technology and creature farming in order to comprehend the digestion and capacity of creatures in health and illness.

• Inheritance study
• Disease diagnosis
• Extraction of energy from food
• Synthetic Biology
• Function of cells
• Plant & animal biotechnology

The medical, natural, and technological know-how art is concerned with the physical and compound attributes of traits, as well as their demeanour, which govern the progression and preservation of living beings. The field of medicinal hereditary qualities is still in its early stages, but it describes the reason for a few acquired diseases by means of acclimation. Infection typically causes the ageing of inconsistent proteins, as in haemophilia, as well as hundreds of "inalienable errors" of digestion that are interpreted in creatures. Mannosidosis and galactosemia are diseases caused by the lack of a specific protein or chemical that prevents sugar, protein, and fat digestion and thus provides medical advice.

• Clinical genetics
• Metabolic/biochemical genetics
• Cytogenetic
• Molecular genetics
• Mitochondrial genetics

The medical, natural, and technological know-how art is concerned with the physical and compound attributes of traits, as well as their demeanour, which govern the progression and preservation of living beings. The field of medicinal hereditary qualities is still in its early stages, but it describes the reason for a few acquired diseases by means of acclimation. Infection typically causes the ageing of inconsistent proteins, as in haemophilia, as well as hundreds of "inalienable errors" of digestion that are interpreted in creatures. Mannosidosis and galactosemia are diseases caused by the lack of a specific protein or chemical that prevents sugar, protein, and fat digestion and thus provides medical advice.

• Clinical genetics
• Metabolic/biochemical genetics
• Cytogenetic
• Molecular genetics
• Mitochondrial genetics

A smear is a method for more constantly shifting proteins, nucleic acids, and ribonucleic acids onto such a carrier than gel electrophoresis. Nucleic (Southern blotch) and ribonucleic (Northern smudge) acids can be evaluated for precise groupings via complementary strands, while protein blends (Western and Eastern smears) can be tested for precise proteins. Microarrays, which are plates with an infinitesimal pocket of correlating DNA, can also be used to examine DNA.

• Southern blotting
• Northern blotting
• Western blotting
• Eastern blotting

Bioorganic is a rapidly evolving logical path that combines herbal technology and organic chemistry. While herbal chemistry aims to understand herbal techniques via science, bioorganic technological know-how appears to be more technological in nature as it seeks to grow herbs artificially. Bioorganic technology encompasses bioinorganic science when examining metalloproteases and cofactors. When trying to represent subtle elements of atomic recognition using bioorganic technology, the term "biophysical natural science" is used. Some of the advanced biological chemistry pursuits include nucleic acids, DNA restoration, bio conjugate technology, peptides as well as peptidomimetics, glycol technology, bimolecular shape as well as capacity, imaging, and natural catalysis.

• Enzyme catalysis
• Biotransformation and enzyme inhibition
• Nucleic acids chemistry
• Natural product chemistry and natural product biosynthesis
• Biophysical chemistry
• Biomimetic chemistry

Auxiliary bioinformatics is the department of bioinformatics that is diagnosed with the exam and expectation of the three-dimensional shape of natural macromolecules, for example, proteins, RNA, and DNA. It manages speculations approximately macromolecular 3-D shape, for example, examinations of trendy folds and community topics, standards of atomic collapsing, development, and limiting associations, and shape/work connections, working both from tentatively tackled systems and from computational models. The term auxiliary has indistinguishable importance from in basic technology, and primary bioinformatics Auxiliary bioinformatics is a branch of bioinformatics concerned with the examination and prediction of the three-dimensional shape of natural macromolecules, including proteins, RNA, and DNA. It handles hypotheses about macromolecular 3-D shape, for example, examinations of current layers as well as community topics, standards of atomic collapsing, advancement, and restricting associations, and shape-work interactions, working both from tentatively addressed systems and from computational models. The term "auxiliary" is indisputable in basic technology, and primary bioinformatics can be considered a subset of computational fundamental technology. Auxiliary technological know-how is a division of subatomic science, herbal chemistry, and biophysics involved only with the subatomic structure of natural macromolecules, particularly amino and nucleic acids, how they acquire their systems, and how changes occur.

• Databases
• Algorithms
• Software
• Tools
• Protein behaviour
• Macromolecular interaction
• Chemical Biology
• Protein function

Molecular Development Biology is the science of how life forms, expands, and is generated only at molecular as well as hereditary levels. The examination focuses on the genetic control of cellular development, separation, enlargement, and morphogenesis.

• Developmental processes
• Embryonic development of animals
• Plant Development
• Developmental model organisms

There is a wide range of scales throughout Biochemistry, Quantitative Biology, and Biophysics, from atoms to cells to entire lifestyle bureaucracies. Its methods encompass a wide range of modern disciplines, including natural chemistry and atomic science, biophysics, cell technology, genomics and proteomics, computational technology, and primary technology. The interface between technology and the extra-quantitative sciences is quantitative technological know-how. Realizing the hidden standards of complex natural behaviour, including bodily and medical fashions, is one of the precise factors of quantitative biology. 

• Electron Microscopy
• X-ray Crystallography
• NMR Spectroscopy

Biochemical biomarkers track the evolution of creatures from ecologically artificial materials. They can also give dangerous proportions, for example, by relying on subatomic components that underpin lethality. In an ideal world, biomarkers would be sensitive, unique, easy to use, and inexpensive for the amount of material obtained using non-hazardous analysis techniques (e.g., of blood). Recently, there has been encouraging progress in the development of certain types of biomarkers. Serum "B" esterase estimation restraint to demonstrate the introduction of winged animals to organ phosphorus Trojan horse sprays The assessment of DNA damage caused by aromatic hydrocarbons The 32P-submit marking procedure was used to investigate DNA adduct arrangement. A few novel strategies are being investigated.

• Genetic Biomarkers
• Protein Biomarkers
• Basophil Activation as a Biomarker of Food Allergy and Asthma
• T-Regulatory Cells as Markers of Allergen Immunotherapy
• Recent Advancements in Biomarkers of Allergy

Interior protein sustenance refers to a wide range of proteins with capacities ranging from capacity to enzymatic motion. An acidic isoelectric point, abundance in the sustenance, ability to assimilate, and proximity to various, direct, i.e., prohibiting epitopes are all general characteristics of nourishment allergens. However, even among these extremely broad characteristics, there are exceptions, making it difficult to predict whether or not a protein is an allergen. Because the development of an IgE response to an allergen involves a progression of cooperation among antigen-presenting cells (APCs), T-cells, and B-cells, it is critical to continue characterising both B-cellular and T-cellular epitopes of known allergens.

• Food Allergy
• Allergy Clin Immunol
• Food Allergen
• Immunology Volume

Clinical Biochemistry & Immunology is the qualitative and quantitative examination of organic fluids such as blood, serum or plasma, urine, or tissues for specific chemical elements or physiologic processes. These outcomes are used by doctors to screen for, diagnose, or screen for diseases. Members of Clinical Biochemistry and Immunology are also involved in research to create new diagnostic medical laboratory exams to discover or reveal disorder, sickness processes, or disease treatment. Examples of tests developed with the assistance of Clinical Biochemistry & Immunology laboratories include:

• Evaluation of immune factors causing disease
• Evaluation of endocrine organ function
• Monitoring response to cancer treatment
• Assessment of transplant immunosuppression
• Evaluation of genetic variation on routine therapies
• Assessment of nutritional status
• Evaluation of drug and metal toxicity

Genomics is an interdisciplinary field of science that focuses on the structure, function, advancement, mapping, and modification of genomes. A genome is the entire DNA arrangement of a life form, including the majority of its characteristics. Rather than investigating individual qualities and their roles in legacy, genomics focuses on the aggregate portrayal and evaluation of qualities, which coordinate the generation of proteins with the assistance of compounds and ambassador particles. Proteins, for example, form body structures such as organs and tissues while also controlling concoction responses and conveying motions between cells. Genomics also includes the sequencing and analysis of genomes using high-throughput DNA sequencing and bioinformatics to collect and dissect the capacity and structure of whole genomes.

• Etymology
• Early Sequencing Efforts
• DNA-Sequencing Technology Developed
• Complete Genomics
• The “Omics” Revolution
• Functional Genomics
• Structural Genomics
• Epigenomics
• Metagenomics
• Genomic Medicine
• Synthetic Biology and Bioengineering

Next-generation sequencing and other high-throughput technologies are revolutionising how we address fundamental biological questions ranging from development to evolution to disease. Because of the unprecedented amounts of data made available by these technologies, we can begin to address biological questions in their entirety. Answering these questions is a highly interdisciplinary endeavour that necessitates the expertise of biologists, statisticians, computer scientists, and bioinformaticians.

• Human Genomes
• Structural Bioinformatics
• Applying grid technologies to bioinformatics
• Microbial genome database

Cancer genomics is the study of the genetic mutations that cause cancer through genome sequencing as well as bioinformatics. The goal of clinical genomics is to determine which sets of genes and gene interactions affect the different subsets of cancer in order to improve cancer treatment and outcomes. The International Cancer Genome Consortium (ICGC) is just a non-profit scientific organisation that facilitates collaboration between the world's top cancer and genomic researchers.

• Use of genomic information to optimize cancer chemotherapy
• Role of germ line genomic investigation in oncology
• GWAS studies in preclinical models
• Combining cell based models and clinical findings

Genome engineering refers to the strategies and techniques developed in recent years for the targeted, specific modification of living organisms' genetic information or genome. The CRISPR-cas9 system makes gene editing more efficient, accessible, and simple than ever before in many organisms and cells, including our own egg, sperm, and embryo. These ground-breaking capabilities have sparked discussions about the new system's ethics and applications, garnering significant attention around the world to make sure ethically correct usage. Proteomics is the large-scale study of proteins. Proteins are essential components of living organisms with numerous functions. The term "proteomics" has been coined in 1997 in reference to genomics, or the study of the genome.

• Field of genomics led to the development of proteomics
• Techniques used in proteomics to analyse proteins
• Ways in which cancer proteomics may lead to better treatments

Plant molecular biology is a specialised science that investigates plant cells and even modifies them to improve plant utility. Agriculture, food science, healthcare, environmental science, as well as teaching are all viable career options. Continue reading to learn more about plant molecular biology and working in the field.

• Agrobacterium transformation
• Advances in Gene Technology
• Programmed Cell Death in Higher Plants
• Practical applications of Plant Molecular Biology

Model systems and human pathogens are being used to contribute to basic and applied research on viruses and their hosts. The questions fall into three broad and overlapping categories: virus structure, viral mechanisms, as well as pathogenesis. Hepatitis B and C viruses, papillomaviruses, Brome mosaic virus, Sindbis virus, Reovirus, and others are among the systems used.

• Virus Structure
• Viral Mechanisms
• Pathogenesis

Many bacteria exist in nature's challenging and diverse environments. Although Escherichia coli can be easily grown in pure culture, its natural home is the mammalian gut, in which it competes for nutrients and space with the complex resident micro biome and wants to avoid the host immune system's defences. Microbiologists are investigating the fascinating mechanisms by which microbes survive in certain complex environments.

• Ecology in a molecular perspective
• Micro biome interaction with its host
• Endophyte–phytopathogen-plant interaction
• Microbial community’s interaction

The Department of Biology has a strong community of labs that focus on various aspects of chromosome biology, such as gene regulation, DNA replication, chromosome segregation, chromosome structure, the DNA damage response, and genome integrity. To study chromosome biology, our labs employ a variety of model systems, including budding yeast, plants, worms, fruit flies, mice, as well as human cells. Our research focuses on how chromosomes have been duplicated in S phase and segregated through M phase, how DNA breaks promote crossovers in meiosis, how DNA damage has been repaired, the role of mutations in evolution, and how epigenetic chromatin modifications regulate the cell cycle, gene silencing, and cancer.

The process of change in the sequence composition of cellular molecules such as DNA, RNA, and proteins over generations is known as molecular evolution. To explain patterns in these changes, molecular evolution employs principles from evolutionary biology and population genetics. The rates and effects of single nucleotide changes, neutral evolution against natural selection, the origins of new genes, the genetic nature of complex traits, the genetic basis of speciation, the evolution of development, and also how evolutionary forces influence genomic and phenotypic changes are all major topics in molecular evolution.

• Mutation
• Recombination
• Gene Conversion
• Genetic Drift
• Selection
• Intra genomic Conflict