Course

Unit 1

Lectures 8

Cellular basis of life: Universal features of cells and how these features separate the living world from non-living world, Cells and laws of thermodynamics; Cell membrane: Membrane structure and how it supported origin of life, Role of membrane asymmetry in cellular functions, Membrane proteins and how they support cellular diversity, Transport of small molecules across the membranes and electrical properties of membranes, Types of membrane transport and examples of molecular mechanisms involved in transport;

Unit 2

Lectures 9

Internal organization of cells: Intracellular compartments and protein sorting: Compartmentalization of cells, Transport of proteins between intracellular compartments, Molecular mechanisms underlying protein sorting and transport across intracellular compartments, Glycosylation and its significance; Intracellular membrane traffic: Intracellular vesicular transport and underlying molecular mechanisms, Maintenance of compartmental diversity, Molecular mechanisms underlying specificity of molecular transport, Molecular mechanisms underlying transport into the cell from the plasma membrane and transport from trans-golgi network to cell exterior;

Unit 3

Lectures 8

Communication between cells and the exterior: Cell signaling: General principles governing cell signaling, Types of cell communication, Negative feedback, Positive feedback, Signaling through GPCRs and enzyme-coupled surface receptors; Cytoskeleton: Types of cytoskeletal filaments, Molecular mechanisms involved in self-assembly and dynamic structure of cytoskeletal filaments, Polymerization and depolymerization of cytoskeletal filaments coupled to cellular functions, Molecular motors and their significance in intracellular transport, Cytoskeleton in cell division;

Unit 4

Lectures 8

Cellular reproduction, the basis of sustenance of life on earth: Cell cycle: Role of templated polymerization of DNA in cellular reproduction and sustenance of life, Cell cycle control system in each phase of cell cycle, Regulation of cell cycle control system in different phases of cell cycle, Molecular mechanisms underlying cell cycle regulation, Control of cell growth; Apoptosis: Different types of cell death, Molecular pathways underlying cell death, Biological significance of cell death; Cancer from a cell’s perspective: Cancer as a microevolutionary process resulting from failure of cellular surveillance system;

Unit 5

Lectures 4

Cells in their social context: Contacts between cell to cell and cells to extracellular
matrix: Cell adhesions, Extracellular matrix, Types of junctions between cells and cells and matrix, Role of junctions in tissue formation and functions of organs;

Unit 6

Lectures 4

How cells ensure continuity of life as well as genetic diversity on earth: Germ cells and sexual reproduction: Germ cells as the cells equipped to transfer genetic information between generations, Sexual reproduction as a cellular process ensuring genetic diversity at the organismal levels;

Unit 7

Lectures 4

Cells during development: Developmental dynamics of cells: How cells undergo commitment, specification and lineage diversification during development, Contribution of cells in pattern formation, Developmental biology of cells from the perspective of diseases and tissue maintenance;

Pre-requisites: Basic understanding of biology

Total number of classes: 45

Course Outcome

CO1 To comprehend cell as the basic unit of life by studying the universal features of cells that distinguish the living and non-living

CO2 To understand the internal organization of cells, molecular bases of membrane transport, intracellular membrane traffic, cell communication and cytoskeleton

CO3 To understand cell cycle and cell death as the bases for sustenance of life and cancer as a microevolutionary process originating from failure of cellular surveillance

CO4 To perceive about a cell in its social context by studying cell – cell adhesions and cell – matrix associations

CO5 To appreciate contribution of cells in reproduction and maintenance of genetic diversity, and the dynamic changes cells undergo during development

Program Outcomes. (PSO)

PO1: Bioscience Knowledge

PO2: Problem Analysis

PO3: Design/Development of Solutions

PO4: Conduct Investigations of complex problems

PO5: Modern tools usage

PO6: Bioscientist and Society

PO7: Environment and Sustainability

PO8: Ethics

PO9: Individual & Team work

PO10: Communication

PO11: Project management & Finance

PO12: Lifelong learning

0 – No affinity; 1 – low affinity; 2 – Medium affinity; 3 – High affinity

Program Specific Outcomes. (PSO)

PSO1. Demonstrate comprehensive knowledge of stem cell biology and their clinical and research relevance.

PSO2. Apply core laboratory techniques for stem cell isolation, characterization, and manipulation.

PSO3. Integrate principles of tissue engineering and biomaterials for regenerative applications.

PSO4. Analyze drug delivery, pharmacokinetics, and bioinformatics relevant to stem cell-based therapies.

PSO5. Evaluate ethical, regulatory, and translational aspects of stem cell product development.

PSO6. Bridge basic science with translational approaches in regenerative medicine and gene therapy.

PSO7. Design and interpret experimental strategies for stem cell-based disease

modeling and preclinical studies.

Evaluation Pattern: 50+50 = 100

Textbook

Alberts B, Johnson A, Lewis J, Raff M, Roberts K and Walter P, “Molecular Biology of the Cell”, Fifth and Sixth Editions, Garland Publishing Inc. 2008.

Reference

Gerald Karp, “Cell and Molecular Biology”, Fifth Edition, John Wiley, 2008.