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CELB30090

Academic Year 2024/2025

Advanced Cell Biology (CELB30090)

Subject:
Cell Biology
College:
Science
School:
Biology & Environment Science
Level:
3 (Degree)
Credits:
5
Module Coordinator:
Professor Jeremy Simpson
Trimester:
Spring
Mode of Delivery:
On Campus
Internship Module:
No
How will I be graded?
Letter grades

Curricular information is subject to change.

Cells are the basic functional units of eukaryotic organisms, and a deeper knowledge of their structure and organisation is an essential aspect of our wider understanding of health and disease. Drawing on information gained in earlier modules, this module integrates concepts in molecular biology, biochemistry and genetics to provide an understanding of processes and functions carried out in eukaryotic cells. Topics covered include membranes and compartmentalisation; roles of the nucleus, and transport between the cytoplasm and nucleus; functions and properties of the endoplasmic reticulum, Golgi complex, trans-Golgi network, endosomes, lysosomes, peroxisomes, mitochondria, extracellular vesicles and primary cilia; roles played by cytoskeleton elements in transport and structure; specialisation of the cytoskeleton; and functions of the plasma membrane. Molecular detail of events such as cell division, programmed cell death, autophagy, secretion, endocytosis, protein translocation, protein targeting, protein degradation, signalling, and regulation through the use of GTPases will also be given. Strong emphasis will also be paid to approaches using living cells. Throughout the module, links to human disease associated with cell dysfunction will be illustrated.

About this Module

Learning Outcomes:

This module is designed to expand your knowledge of eukaryotic cell organisation and function. Prior to this module you are expected to have a good knowledge of cells, the organelles within them, and the basic roles of these organelles. This module will expand this knowledge by providing the molecular detail of various processes and functions required to maintain cellular homeostasis.

On completion of this module, registrants will have a clear understanding of the basic structure and function of eukaryotic cells. This understanding will include the important role of subcellular compartmentalisation in achieving cellular efficiency, and how specific molecular events contribute to overall cell function.

Indicative Module Content:

- INTRODUCTION: Overview of the module, its organisation, content and assessment. General introduction to the contribution of cell biology approaches within the arena of biological sciences. Overview of internal membranes in eukaryotic cells, the importance of subcellular architecture and introduction to internal transport and communication pathways. Introduction to key roles of the endoplasmic reticulum, Golgi complex, and the endosomal-lysosomal system.

- VESICLES AND COATS IN MEMBRANE TRANSPORT: General concepts of transport between internal organelles, membrane budding, transport and fusion. Introduction to cytoplasmic coat proteins and their molecular composition and regulation. Form and function of the COPII coat, the COPI coat, the clathrin coat and retromer.

- CONTROL OF ORGANELLES AND MEMBRANE IDENTITY: Regulatory molecules associated with membrane transport including Rab GTPases, tethers and SNAREs. The general role of the GTPase cycle in regulating cell organisation. Dysfunction of the endomembrane system and links to disease.

- THE CELL SURFACE: Structure and function of the plasma membrane, including lipid and protein composition. Asymmetry of the plasma membrane and its importance in signalling. Mobility of lipids and proteins at the cell surface and the types, roles and molecular composition of cell-cell contact structures, including anchoring junctions, occluding junctions, channel forming junctions and tunnelling nanotubes.

- ENDOCYTOSIS: Introduction to endocytosis and endocytic mechanisms, including phagocytosis, caveolin- and clathrin-mediated endocytosis. Molecular details of these processes including the protein composition of these endocytic structures and their importance. Structure-function of clathrin and the AP-2 complex.

- THE ENDOSOMAL-LYSOSOMAL SYSTEM: Entry into the endocytic pathway, types of endosomes, sorting in early endosomes, including trafficking of LDL receptors, transferrin receptors, opioid receptors. Maturation of late endosomes, multivesicular bodies and transcytosis in polarised cells. Role of Rab proteins in endosomal sorting.

- THE ENDOPLASMIC RETICULUM (FORM AND FUNCTION): Overview of the key roles of the endoplasmic reticulum (ER), including rough ER, smooth ER, and transitional ER. Molecular mechanisms of soluble and trans-membrane protein import into the ER, and the importance of the Sec61 translocon. Protein folding and glycosylation in the lumen of the ER, protein quality control and the ER associated degradation pathway for misfolded proteins, the proteasome. The unfolded protein response.

- THE SECRETORY PATHWAY: Introduction to the secretory pathway and its organisation in eukaryotes. Transport between the ER and Golgi complex, recycling back to the ER, the KDEL system. Transport through the Golgi complex, including descriptions of the three proposed models. Transport from the trans-Golgi network to the lysosomal system. Introduction to regulated secretion.

- TRANSPORT ACROSS BIOLOGICAL MEMBRANES: Principles of crossing biological membranes, transporters and channels, active and passive transport, ion gradients, ATP-driven pumps, ABC transporters. Transport between the cytoplasm and nucleus, the nuclear pore complex, role of Ran GTPase.

- CELL DIVISION (overview): An overview of the cell cycle, components of the cell cycle control system, intracellular control of cell cycle events – the role of cyclins, cyclin-dependent kinases (cdks) and Cdk inhibitory proteins. The cell cycle checkpoints.

- CONTROL OF MITOSIS AND CYTOKINESIS: Molecular mechanism of nuclear division (mitosis) and cytoplasmic division (cytokinesis). The role of microtubules in spindle assembly and function. The spindle assembly checkpoint.

- PROGRAMMED CELL DEATH: An introduction to different forms of Programmed Cell Death during growth and development of multicellular organisms. The role of the mitochondrion and endoplasmic reticulum during programmed cell death. The intrinsic and extrinsic cell death pathways.

- AUTOPHAGY: An introduction to autophagy - classification and regulation. The role of metabolic stress in autophagy induction. Cross-talk between autophagy and apoptosis. Autophagy and disease.

- CYTOSKELETON I - microtubules: Introduction to the cytoskeleton in eukaryotic cells, including general properties and its role in cell stability and cell dynamics. Molecular composition of microtubules, microtubule dynamics and accessory proteins. Microtubule organisation and the centrosome. Motors of microtubules, including molecular details of dynein and kinesin.

- CYTOSKELETON II - intermediate filaments: Molecular composition of intermediate filaments and their role in cells. Variety of intermediate filament types, five subgroups. Variety of keratins and their functions. Nuclear lamins and disease.

- CYTOSKELETON III - actin and cell motility: Molecular composition of the actin cytoskeleton, actin binding proteins, and myosin motors. Molecular mechanism of actin nucleation and its role in cell motility. Importance and role of the Rho family of small GTPases in actin cytoskeleton regulation and remodelling.

- CYTOSKELETON IV - focal adhesions and the ECM: Molecular composition of focal adhesions, linkage to internal cytoskeleton elements. Variety and role of integrins. The extracellular matrix (ECM) and its role in connective tissue. Composition of the ECM, hyaluronic acid, proteoglycans, collagens, and fibronectin. Assembly and processing of collagen. ECM degradation.

- THE CILIUM ORGANELLE I - a case study of intracellular transport and membrane trafficking: Introduction to cilium structure/function in multiple cell types and organisms. Mechanistic basis of cilium formation from centriole-nucleated basal bodies and subsequent elongation via kinesin-2 and cytoplasmic dynein-driven intraflagellar transport.

- THE CILIUM ORGANELLE II: Outline of membrane transport to cilia, highlighting the role of various key small G-proteins and secretory/endocytic components. Description of key experimental models (e.g., photoreceptor cells) used to address ciliary membrane transport.

- THE CILIUM ORGANELLE III: Overview of transport defects associated with ciliary disease such as Bardet Biedl syndrome and retinitis pigmentosa.

- EXTRACELLULAR VESICLES: Eukaryotic extracellular vesicles (EVs): exosomes and microvesicles. Formation and cargo composition. Prokaryotic EVs from gram-negative and gram-positive bacteria. EVs functions in intercellular, inter-species and cross-kingdom communication. Natural EVs as a source of diagnostics biomarkers. Engineered EVs as drug delivery systems.

- EXOGENOUS RNA: Natural and artificial exogenous RNA. RNA receptors and nucleic acids immunity. Exogenous RNA in cross-kingdom communication. Coding and non-coding RNA therapeutics. RNA modifications. Drug delivery systems for RNA therapeutics.

Student Effort Hours:
Student Effort Type Hours
Lectures

22

Specified Learning Activities

18

Autonomous Student Learning

85

Total

125


Approaches to Teaching and Learning:
This module is taught through lectures and interactive discussion, supported by specific assignments.

Requirements, Exclusions and Recommendations
Learning Recommendations:

Students will be expected to have a basic understanding of cell structure and function. Students should have taken modules that cover basic cell biology such as CELB20060 Principles of Cell & Molecular Biology or BIOL11010 Cell Biology & Genetics


Module Requisites and Incompatibles
Equivalents:
Cell Biology (Level 3) (CELB30070)


 

Assessment Strategy
Description Timing Component Scale Must Pass Component % of Final Grade In Module Component Repeat Offered
Quizzes/Short Exercises: MCQ / short answer quiz on part 1 of the module Week 4 Alternative linear conversion grade scale 40% No
30
Yes
Quizzes/Short Exercises: MCQ / short answer quiz on part 2 of the module Week 8 Alternative linear conversion grade scale 40% No
30
Yes
Exam (In-person): Short answer questions End of trimester
Duration:
2 hr(s)
Alternative linear conversion grade scale 40% No
40
Yes

Carry forward of passed components
Yes
 

Remediation Type Remediation Timing
In-Module Resit Prior to relevant Programme Exam Board
Please see Student Jargon Buster for more information about remediation types and timing. 

Feedback Strategy/Strategies

• Feedback individually to students, on an activity or draft prior to summative assessment
• Group/class feedback, post-assessment

How will my Feedback be Delivered?

Not yet recorded.

Name Role
Professor Oliver Blacque Lecturer / Co-Lecturer
Professor Jeremy Simpson Lecturer / Co-Lecturer
Dr Paola Valentini Lecturer / Co-Lecturer

Timetabling information is displayed only for guidance purposes, relates to the current Academic Year only and is subject to change.
Spring Lecture Offering 1 Week(s) - 20, 21, 23, 24, 25, 26, 29, 31, 33 Mon 09:00 - 09:50
Spring Lecture Offering 1 Week(s) - 32 Mon 09:00 - 09:50
Spring Lecture Offering 1 Week(s) - 20, 21, 22, 24, 25, 26, 30, 31, 32, 33 Wed 09:00 - 09:50
Spring Lecture Offering 1 Week(s) - 23 Wed 09:00 - 09:50
Spring Lecture Offering 1 Week(s) - 29 Wed 09:00 - 09:50