Advanced Molecular and Cellular Biotechnology
A.Y. 2021/2022
Learning objectives
The main objective of the course is to gain a deep cellular and molecular knowledge of structures and functions of cells and genomes. Innovative approaches and methodologies will be described, with direct implication for biotechnology. While we strive to keep overlaps with other courses to a minimum, our course touches several aspects of genome and cell biology, with specific reference to biotechnology applications, that are also discussed in structural biology, bioinformatics, and genome engineering courses.
Expected learning outcomes
After attending the course, the students will be able to discuss a critical points, experimental designs and interpretation of the results about the topics presented., specifically:
- principles, origin and uses of tissue cultures;
- the use of engineered mice to study gene function in physiology and pathology;
- Drosophila melanogaster as a genetic model for disease;
- rudiment of cell cell signaling and its alterations in tumorigenesis;
- introductions to other experimental model systems (Zebrafish, organoids, biofabrications);
- data protection, ethics of science and research integrity;
- basic and advanced concepts of DNA damage response (DDR);
- basic and advanced concepts of recombination DNA repair;
- basic concepts of cancer therapy approaches, with specific reference to DDR.
- principles, origin and uses of tissue cultures;
- the use of engineered mice to study gene function in physiology and pathology;
- Drosophila melanogaster as a genetic model for disease;
- rudiment of cell cell signaling and its alterations in tumorigenesis;
- introductions to other experimental model systems (Zebrafish, organoids, biofabrications);
- data protection, ethics of science and research integrity;
- basic and advanced concepts of DNA damage response (DDR);
- basic and advanced concepts of recombination DNA repair;
- basic concepts of cancer therapy approaches, with specific reference to DDR.
Lesson period: Second semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course cannot be attended as a single course. Please check our list of single courses to find the ones available for enrolment.
Course syllabus and organization
Single session
Responsible
Lesson period
Second semester
More specific information on the delivery modes of training activities for the academic year 201/22 will be provided over the coming months, based on the evolution of the public health situation.
Course syllabus
The program will cover different molecular aspects of cell biology with implications for biotechnology.
Part A (3 CFU; Prof. Vaccari). An Introduction to model system biology; How to connect cell biology data to tissue and organismal contexts; Genetic tools for cell and tissue biology: The case of Drosophila; Forward and reverse genetic approaches for understanding of gene function; Signal transduction biology: The case of Notch and membrane trafficking; In vivo modeling of monogenic diseases.
Part B (2CFU; Prof. Biffo). Principles of cell culture; Established and primary cell lines. Other types of cell cultures: tissue slices and the development of 3D-models; Modern analytical methods. Concepts of differentiation and oncogenesis at work in cell culture.
Part C (5 CFU; Pellicioli). The problem of genome integrity maintenance. Specific arguments: keys factors and mechanisms of the DNA repair and DNA damage checkpoint pathways; DNA recombination mechanisms that drive genome rearrangements and instability; molecular perspective to understand cancer development and treatment; exploiting DNA damage response pathways for genome engineering.
Part A (3 CFU; Prof. Vaccari). An Introduction to model system biology; How to connect cell biology data to tissue and organismal contexts; Genetic tools for cell and tissue biology: The case of Drosophila; Forward and reverse genetic approaches for understanding of gene function; Signal transduction biology: The case of Notch and membrane trafficking; In vivo modeling of monogenic diseases.
Part B (2CFU; Prof. Biffo). Principles of cell culture; Established and primary cell lines. Other types of cell cultures: tissue slices and the development of 3D-models; Modern analytical methods. Concepts of differentiation and oncogenesis at work in cell culture.
Part C (5 CFU; Pellicioli). The problem of genome integrity maintenance. Specific arguments: keys factors and mechanisms of the DNA repair and DNA damage checkpoint pathways; DNA recombination mechanisms that drive genome rearrangements and instability; molecular perspective to understand cancer development and treatment; exploiting DNA damage response pathways for genome engineering.
Prerequisites for admission
Good knowledge of Molecular Biology, Genetics and Biochemistry is required.
Teaching methods
Teaching mode: Traditional lectures supported by slides and more interactive lectures with open discussion on selected aspects (Journal and data club). Attendance is highly recommended.
Teaching Resources
Scientific papers and reviews will be indicated during the course and made available to students through the website (https://tvaccariamcb.ariel.ctu.unimi.it). The material is made available only to registered students of the Degree Course in Molecular Biotechnology and Bioinformatics and should not be distributed to others.
Assessment methods and Criteria
The exam is written with half of the evaluation based on open questions (Pellicioli), and a half on multiple-choice questions (Biffo & Vaccari). The two parts can be taken separately in two distinct exam sessions, with Pellicioli's part as second. Questions attain to subjects discussed during the course and will concur to define the overall mark by weighting equally on both parts.
BIO/06 - COMPARATIVE ANATOMY AND CYTOLOGY
BIO/11 - MOLECULAR BIOLOGY
BIO/11 - MOLECULAR BIOLOGY
Lectures: 80 hours
Professor(s)
Reception:
Wednesday 10.30-12.30 and Friday 10.30-11.30
Office