GENETICS

GENETICS

_
iten
Code
80756
ACADEMIC YEAR
2018/2019
CREDITS
5 credits during the 1st year of 8756 Biotechnology (L-2) GENOVA
SCIENTIFIC DISCIPLINARY SECTOR
BIO/13
LANGUAGE
Italian
TEACHING LOCATION
GENOVA (Biotechnology)
semester
1° Semester
modules
This unit is a module of:
Teaching materials

AIMS AND CONTENT

LEARNING OUTCOMES

This module will provide a basic outline of the principles of classical genetics and of their main underlying molecular and cellular mechanisms. The course will cover both the function and the organization of genetic material, mainly in eukaryotes. Methods to determine the relative positions of genes in the genome will be explained, and different patterns of inheritance will be described. The main areas covered will be: transmission genetics, gene and genome structure, and stability and variability mechanisms. The course will also introduce students to simple genetics problems with specific interactive lessons.

AIMS AND LEARNING OUTCOMES

Upon completion of the course, students should be able to recognize and describe genetic phenomena and demonstrate knowledge of

 

-General mechanisms of inheritance, with  particular attention to human heredity

-Fundamentals of molecular genetics mechanisms that underlie Mendelian inheritance patterns.

-Mutations: basic features of the process, molecular mechanisms and relative  consequences on the potential pathogenicity

-Applications of modern analytical techniques of molecular genetics and genomics to biotechnology and biomedicine

 

Teaching methods

The course consists of 40 hours of classroom training including 32 hours of theoretical lessons on all topics of the program, 6 hours dedicated to solving genetic problems and 2 hours of seminar activity designed to offer  the opportunity to reflect critically on the potential biotechnological applications of the genetics and genomics topics dealt with in the course. 

SYLLABUS/CONTENT

1) Genes and genomes

Organization of gene structure and function

comparative description of Genomes (size and organization)

Structure and function of chromatin

The nucleosome as a fundamental unit of DNA packaging, and its role in gene expression regulation

 

2)Meiosis: Inheritance and variation 

-Comparative analysis of meiosis and mitosis kinetics

-Mechanisms contributing to genetic variation: (recombination,independent assortment, random fertilization)

 

3)Basic Principles of inheritance:

Mendel's study of heredity. Applications of Mendel's principles to General genetics (eukaryotes)

Testing Hypotheses  about Patterns of Inheritance (Punnett  Square, branch diagram, probability methods )

4) Extensions to Mendel’s Laws for single gene inheritance

 

-Allelic variation and gene function:

-Incomplete dominance. Codominance,

-Multiple alleles, lethal alleles

-Notions on allelic variation effects on viability: phenotypic, sterility-causing, lethal

-Pleiotropy : A single gene responsible for a variety of traits.

 

5) Extensions. to Mendel’s Laws for two or more  genes  determining one trait-

-Different models from 2-gene interaction :

novel phenotypes, complementary gene action, epistasis

-Gene-environment interaction,  environmental effects on phenotype

-Penetrance and expressivity

 

6) Problem solving in the following subjects :

-Applications of Mendel's Principles to eukaryotics .

-Extensions of Mendelism: incomplete dominance. Codominance, Multiple alleles, lethal alleles ,

-Different models of Gene-gene interaction

-Description of some examples of pleiotropic traits

 

7) Applications of Mendel's principles to Human genetics 

-Testing inheritance-hypothesis through  Mendelian pedigree pattern analysis

 

8)Problem solving in the following subjects

-Applications of Mendel's principles to Human genetics

-Pedigrees analysis.

-Transmission probability of monogenic traits

 

-9)Sex-linked traits:

 Sex-chromosomes and the chromosomal theory of inheritance.

-X-linked recessive and dominant inheritance and Y-linked inheritance.

-Molecular mechanisms of sex determination in humans,drosophila and other eukaryotes.

 

10) Dosage Compensation of X-Linked Genes:

-Molecular mechanisms of X-chromosome dosage compensation in mammals, Drosophila and other eukaryotes 

 

11)Linked Genes: Recombination and gene mapping in eukaryotes.

-Linked and unlinked genes, crossing-over and recombination.

-Frequency of recombination and genetic distance in genetic mapping.

-Correlations among genetic, cytogenetic and physical mapping.

-Notions of mechanisms of genetic exchange and mapping in humans and bacteria.

 

12) Problem solving in the following subjects :

-Sex-linked traits in drosophila and humans –

-Linked Genes: recombination and gene mapping in eukaryotes and notions of linkage analysis in human genetics Simple examples of pedigrees

 

13) Polygenic inheritance and environmental effects

A Mendelian explanation of continuous variation in polygenic trait inheritance

-Additive model of polygenic inheritance (continuous characters)

-Polygenic threshold model for non mendelian discontinuous characters.

-Simple examples of both models

 

14) -Mutation: Source of the Genetic Variability Required for Evolution

-Basic Features of the Process.

-Somatic and germline mutations.

-Spontaneous and induced mutations

-Physical,chemical agents as mutagens.

 

-Notions of DNA Repair mechanisms

 

15)Mutation: molecular basis and phenotypic effects

-Mutations with dangerous phenotypic effects

-Dominant and recessive lethal mutations

-Conditional mutations as  powerful tools for studying gene function

-Intra and intergenic suppressor mutations

-More in-depth studies on mutational mechanisms which result in the exchange of repeated sequences, unstable expansion of triplet repeats,transposable genetic elements

 

16) Transposable Genetic Elements(TGE)

-Transposable elements in bacteria

-Cut-and-paste transposons in Eukaryotes

-Retroviruses and Retrotransposons

-Transposable Elements in Humans

-The Genetic and Evolutionary Significance of Transposable Elements

 

17)

Mitochondrial Inheritance

-Molecular genetics mechanisms that contribute to uniparental (maternal)inheritance

-Mitochondrial DNA mutations and human health

Chromatin Structure and Epigenetic effects

-Genomic imprinting , DNA methylation ,chromatin remodeling

-Inheritance pattern of imprinted genes

 

18)The genetic basis of cancer

Cancer: a genetic disease

Role of Oncogenes, Tumor Suppressor Genes on failure of control over cell division and on cancer onset

Genetic Pathways to Cancer

Inherited cancer syndromes : defects in DNA replication, repair and recombination mechanisms.

 

19)Molecular Analysis of Genetic Information

-Use of Recombinant DNA Technology to Identify Human Genes and Diagnose Human Diseases

-Molecular Diagnosis of Human Diseases

-DNA Profiling

-Problem solving in applications of molecular genetics to biomedicine

 

20)Seminar lesson in cooperation with the students

More in-depth explanations on course-related topics requested by the students

RECOMMENDED READING/BIBLIOGRAPHY

EXTBOOKS 

Recommended  textbooks include

 Russell P.J. et. al.- Genetica. Un approccio molecolare. Pearson

 

Hartwell L.H. et al.- Genetica. Mc Graw-Hill Company

Pierce B.A et al.- Genetica -Zanichelli

 

 

 

 

TEACHERS AND EXAM BOARD

Ricevimento: make an appointment by e-mail paola.ghiorzo@unige.it, or telephone  0103538949-0105557255. Address: DiMI; Viale Benedetto XV, 6. Secondo floor , room  206

Exam Board

ALDO PAGANO (President)

PAOLO GIANNONI (President)

PAOLA GHIORZO (President)

LORENZA PASTORINO

LESSONS

Teaching methods

The course consists of 40 hours of classroom training including 32 hours of theoretical lessons on all topics of the program, 6 hours dedicated to solving genetic problems and 2 hours of seminar activity designed to offer  the opportunity to reflect critically on the potential biotechnological applications of the genetics and genomics topics dealt with in the course. 

EXAMS

Exam description

Students are assessed ­by a final exam  (written and oral) which aims to ensure that they have actually reached the required level of knowledge.

Assessment methods

 

Written test solving 3 or 4 genetic problems and 4 open questions,  all to be answered in 75  minutes) for the Genetics section.
The examination for the main course  consists of a single written exam for the 2 sub-sections.  The total amount of time allowed for the examination is 135  minutes.
The chance to carry out a supplementary oral examination  is available both to students whose final average mark is 17/30 and  to those who wish to increase the mark (at least 27/30) they obtained in the written examination. 

 

In order to pass the examination and to reach a mark of at least 18/30,  the students must prove their knowledge on :
 

-general mechanisms of inheritance, with  particular attention to human heredity

- fundamentals of molecular genetics mechanisms that underlie inheritance models .

- basic features of the process and the Molecular Basis of the Mutation

medical applications of modern analytical techniques of molecular egentics and genomics to biomedicine and biotechnology