Molecular Genetics
A.Y. 2021/2022
Learning objectives
This course provides an exhaustive overview of the fundamental principles guiding molecular genetics approaches. Key learning objectives include:
- understanding the concept of inheritance of genetic information and genes action, including dominance, epistasis and their contribution to the manifestation of traits;
- understanding the contribution of transcriptional and post-transcriptional events toward gene expression, and the related techniques/approaches that enable to distinguish between these two processes;
- understanding the strategies and the design of genetic screens, including the use of genetic variability as a means to understand gene regulatory networks.
- understanding the concept of inheritance of genetic information and genes action, including dominance, epistasis and their contribution to the manifestation of traits;
- understanding the contribution of transcriptional and post-transcriptional events toward gene expression, and the related techniques/approaches that enable to distinguish between these two processes;
- understanding the strategies and the design of genetic screens, including the use of genetic variability as a means to understand gene regulatory networks.
Expected learning outcomes
After this course, the student will be able to:
- critically evaluate and describe hierarchies in gene action and regulation by applying the principles of transmission genetics;
- design genetic experiments as a mean to gain molecular insights into biological processes and support/reject working hypothesis;
- correctly interpret and communicate results pertaining gene regulation under physiological and pathological conditions.
- critically evaluate and describe hierarchies in gene action and regulation by applying the principles of transmission genetics;
- design genetic experiments as a mean to gain molecular insights into biological processes and support/reject working hypothesis;
- correctly interpret and communicate results pertaining gene regulation under physiological and pathological conditions.
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 academic year 2021/22 will be provided over the coming months, based on the evolution of the public health situation.
Course syllabus
- Multilevel gene regulation during evolution. Case studies: Sex determination in Drosophila vs mammals as examples of the different interplay of transcriptional and post-transcriptional events. Dosage compensation: hyperactivation and inactivation of chromosome X as an example of epigenetic regulation of traits.
- Complex genomes and hereditability of complex traits. Genetic and physical maps: DNA polymorphisms as markers.
- Concepts in positional cloning, from phenotypes to genes. Case studies: Duchenne muscular dystrophy. Genetic, cytogenetic and physical mapping, cloning and expression analysis of DMD gene and its mutations, clinical applications.
- Functional genomics, from sequences to gene functions, redundancy and epistasis. Case studies: the genetics of timekeeping and environmental perception in Arabidopsis. Tools for functional genomics: sensitized genetic background screens. Quantitative effects of mutations, the molecular basis of genetic dominance. Examples of genome-enabled genetics and genome-wide association.
- Research approaches to nutrigenomics, genomic imprinting and examples of nutriepigenetics.
- Complex genomes and hereditability of complex traits. Genetic and physical maps: DNA polymorphisms as markers.
- Concepts in positional cloning, from phenotypes to genes. Case studies: Duchenne muscular dystrophy. Genetic, cytogenetic and physical mapping, cloning and expression analysis of DMD gene and its mutations, clinical applications.
- Functional genomics, from sequences to gene functions, redundancy and epistasis. Case studies: the genetics of timekeeping and environmental perception in Arabidopsis. Tools for functional genomics: sensitized genetic background screens. Quantitative effects of mutations, the molecular basis of genetic dominance. Examples of genome-enabled genetics and genome-wide association.
- Research approaches to nutrigenomics, genomic imprinting and examples of nutriepigenetics.
Prerequisites for admission
An intermediate level of understanding of Mendelian genetics and molecular biology is highly recommended.
Teaching methods
Regular attendance and active participation during classes are strongly encouraged to improve the understanding of the topics and improve communication skills. In order to facilitate active discussions, handouts will be made available before class through the Ariel website.
Lectures will be strongly oriented to presenting empirical evidence to gain insights into potential mechanisms and to formulate working hypotheses. Students are invited to participate in this process, defining competing/alternative hypotheses.
Lectures will be strongly oriented to presenting empirical evidence to gain insights into potential mechanisms and to formulate working hypotheses. Students are invited to participate in this process, defining competing/alternative hypotheses.
Teaching Resources
Students may refer to general genetics textbooks (Griffiths et al - VII ed. - Zanichelli 2013, Russell - IV ed. - Pearson - 2014) for basic/advanced concepts in Mendelian inheritance and gene expression regulation.
For more specialized topics, references to original research papers/reviews for further reading will be highlighted during classes and uploaded via Ariel.
For more specialized topics, references to original research papers/reviews for further reading will be highlighted during classes and uploaded via Ariel.
Assessment methods and Criteria
Learning assessment will be through a written exam. Students attending the course can opt for a mid-term examination plus a second partial exam at the end of the course.
The exam includes open questions (30%), charts and graphs to complete (10%) and multiple choices tests (60%). These proportions broadly reflect their contribution to the composition of the final score. Multiple choice tests are designed to verify the global understanding of concepts and definitions taught during the course, whereas open questions/charts are designed to evaluate problem solving skills. Examples of multiple-choice questions and their evaluation will be provided during the course.
The exam includes open questions (30%), charts and graphs to complete (10%) and multiple choices tests (60%). These proportions broadly reflect their contribution to the composition of the final score. Multiple choice tests are designed to verify the global understanding of concepts and definitions taught during the course, whereas open questions/charts are designed to evaluate problem solving skills. Examples of multiple-choice questions and their evaluation will be provided during the course.
Professor(s)
Reception:
upon request of an appointment