Studying at the University of Verona

Here you can find information on the organisational aspects of the Programme, lecture timetables, learning activities and useful contact details for your time at the University, from enrolment to graduation.

Academic calendar

The academic calendar shows the deadlines and scheduled events that are relevant to students, teaching and technical-administrative staff of the University. Public holidays and University closures are also indicated. The academic year normally begins on 1 October each year and ends on 30 September of the following year.

Academic calendar

Course calendar

The Academic Calendar sets out the degree programme lecture and exam timetables, as well as the relevant university closure dates..

Definition of lesson periods
Period From To
I sem. Oct 2, 2017 Jan 31, 2018
II sem. Mar 1, 2018 Jun 15, 2018
Exam sessions
Session From To
Sessione invernale d'esame Feb 1, 2018 Feb 28, 2018
Sessione estiva d'esame Jun 18, 2018 Jul 31, 2018
Sessione autunnale d'esame Sep 3, 2018 Sep 28, 2018
Degree sessions
Session From To
Sessione di laurea estiva Jul 18, 2018 Jul 18, 2018
Sessione di laurea autunnale Nov 22, 2018 Nov 22, 2018
Sessione di laurea invernale Mar 20, 2019 Mar 20, 2019
Holidays
Period From To
Christmas break Dec 22, 2017 Jan 7, 2018
Easter break Mar 30, 2018 Apr 3, 2018
Patron Saint Day May 21, 2018 May 21, 2018
Vacanze estive Aug 6, 2018 Aug 19, 2018

Exam calendar

Exam dates and rounds are managed by the relevant Science and Engineering Teaching and Student Services Unit.
To view all the exam sessions available, please use the Exam dashboard on ESSE3.
If you forgot your login details or have problems logging in, please contact the relevant IT HelpDesk, or check the login details recovery web page.

Exam calendar

Should you have any doubts or questions, please check the Enrollment FAQs

Academic staff

B C D F G M O P Q S T U V Z

Bicego Manuele

symbol email manuele.bicego@univr.it symbol phone-number +39 045 802 7072
Foto,  February 9, 2017

Bloisi Domenico Daniele

symbol email domenico.bloisi@univr.it

Boscaini Maurizio

symbol email maurizio.boscaini@univr.it

Buffelli Mario Rosario

symbol email mario.buffelli@univr.it symbol phone-number +39 0458027268

Busato Federico

symbol email federico.busato@univr.it

Calanca Andrea

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Capaldi Stefano

symbol email stefano.capaldi@univr.it symbol phone-number +39 045 802 7907

Castellini Alberto

symbol email alberto.castellini@univr.it symbol phone-number +39 045 802 7908

Cicalese Ferdinando

symbol email ferdinando.cicalese@univr.it symbol phone-number +39 045 802 7969

Combi Carlo

symbol email carlo.combi@univr.it symbol phone-number +390458027985

Daducci Alessandro

symbol email alessandro.daducci@univr.it symbol phone-number +39 045 8027025

Delledonne Massimo

symbol email massimo.delledonne@univr.it symbol phone-number 045 802 7962; Lab: 045 802 7058

Dell'Orco Daniele

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Dominici Paola

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D'Onofrio Mariapina

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Drago Nicola

symbol email nicola.drago@univr.it symbol phone-number 045 802 7081

Farinelli Alessandro

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Giachetti Andrea

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Giorgetti Alejandro

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Gobbi Bruno

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Gregorio Enrico

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Manca Vincenzo

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Maris Bogdan Mihai

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Menegaz Gloria

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Migliorini Sara

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Oliboni Barbara

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Piccinelli Fabio

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Posenato Roberto

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Quaglia Davide

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Spoto Nicola Fausto

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Trabetti Elisabetta

symbol email elisabetta.trabetti@univr.it symbol phone-number 045/8027209
UgoliniSimone

Ugolini Simone

symbol email simone.ugolini@univr.it

Valenti Maria Teresa

symbol email mariateresa.valenti@univr.it symbol phone-number +39 045 812 8450

Villa Tiziano

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Zanatta Marco

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Study Plan

The Study Plan includes all modules, teaching and learning activities that each student will need to undertake during their time at the University.
Please select your Study Plan based on your enrollment year.

2° Year  activated in the A.Y. 2018/2019

ModulesCreditsTAFSSD
12
B
INF/01
6
C
BIO/18

3° Year  activated in the A.Y. 2019/2020

ModulesCreditsTAFSSD
One course to be chosen among the following
Other activitites
3
F
-
Final exam
3
E
-
activated in the A.Y. 2019/2020
ModulesCreditsTAFSSD
One course to be chosen among the following
Other activitites
3
F
-
Final exam
3
E
-

Legend | Type of training activity (TTA)

TAF (Type of Educational Activity) All courses and activities are classified into different types of educational activities, indicated by a letter.




S Placements in companies, public or private institutions and professional associations

Teaching code

4S00997

Credits

6

Language

Italian

Scientific Disciplinary Sector (SSD)

BIO/13 - EXPERIMENTAL BIOLOGY

Period

II sem. dal Mar 1, 2018 al Jun 15, 2018.

Learning outcomes

The course purposes are:
• to give basic knowledge about living organism characteristic: procariots, eucariots, viruses, through the acquisition of the fundamental concepts of biology and of the structural, functional and molecular principles of cellular processes.
• to describe the fundamental concepts of genetics and the transmission of hereditary characters in different organisms, with specific examples of pathological traits in humans
• to provide basic knowledge on the mechanisms governing the flow of genetic information and the development of organisms
• to provide basic knowledge of animal behavior
• to educate to the critical evaluation of experimental data, describing and discussing past and contemporary important experiments.
• to provide the up-to-date methodologies used in the biological molecules studies

At the end of the course, students should demonstrate to have acquired notions to become fruitful for a critical analysis of the mechanisms which regulate intra/intercellular activities, cellular interactions and reproduction, organism-to –organism interactions and organisms-to-environment interactions and cause mutations. Students are expected to be autonomous in the evaluation of the mentioned processes. They should also demonstrate to have acquired knowledge of the flow of genetic information, growth and development of living organisms, Mendelian genetics and of animal behavior. Students should also demonstrate to have acquired basic knowledge of methodologies used in the biological molecules studies and their capability to expose reasoning in a critical and precise manner using appropriate scientific terms.

Knowledge and understanding: students will acquire knowledge of the fundamental structures of biological systems, interpreted in a molecular and cellular key, in an evolutionary view of life; students will also acquire knowledge of the main biomolecular models and technologies and the basic foundations of genetics.

Ability to apply knowledge and understanding: students will be able to use the specific notions of biology and genetic bases of life to propose appropriate and original solutions in computer applications; students will also acquire the ability to read and understand advanced biological topics and will therefore be able to face a training course (including a master's degree) both in the biotechnology and bioinformatics field.

Program

• OVERVIEW ON BIOLOGY. Characteristics of the living beings: prokaryotic and eukaryotic cell, growth and development, regulation of metabolism, ability to respond to stimuli, reproduction, evolution and adaptation. Levels of biological organization. Transmission of information between organisms and across generations. Evolution and hierarchical classification of living organisms. Energy flow through ecosystems.
• CHEMICAL ELEMENTS OF LIFE. Chemical elements in living organisms. Covalent, ionic, polar, nonpolar, hydrogen bonds; intermolecular interactions, the van der Waals forces. Redox reactions, pH, salts, acids, bases, buffers. Functional groups. Geometrical and structural isomers. Organic molecules and macromolecules. Carbohydrates, proteins, lipids, nucleic acids. Enantiomers. Importance of water in biology.
• PRINCIPAL INSTRUMENTS AND METHODS OF CELL INVESTIGATIONS: light microscopy, electron microscopy, cell fractionation
• PROKARYOTIC AND EUKARYOTIC CELL. Cell theory. Organization of the cell. Internal membranes and compartmentalization. Organelles, characteristics and functions: Nucleus, ribosomes, RER, REL, Golgi, lysosomes, peroxisomes, cytoskeleton (microtubules, microfilaments, intermediate filaments, centrioles), cilia, flagella, cell wall, extracellular matrix. Animal and plant cells. Mitochondria and plastids (chloroplasts, amyloplasts, chromoplasts) and endosymbiont theory.
• BIOLOGICAL MEMBRANES. Structure and proposed models. Kinds of membrane lipids and proteins. Function of membrane constituents. Passage of materials across cell membranes: passive transport (facilitated diffusion and simple), osmosis, directly and indirectly active transport, co-transport. Exocytosis and endocytosis. Anchoring, tight and gap cell junctions in animal and plant cells.
• CELL COMMUNICATION. Types of cellular communication: endocrine, paracrine, autocrine and iuxtacrine. Sending and receiving the signal. Surface and intracellular receptors. Receptors coupled to ion channels, G protein, enzymes. Signal transduction and second messengers. The response to signals. Negative signal transduction.
• ENERGY FLOW THROUGH LIVING ORGANISMS.
Energy and metabolism: energy and biological work; exo-and endo-ergonic reactions, metabolism, anabolism and catabolism, reduction-oxidation reactions, energy coupling; ATP; energy transfer systems: transport of phosphate groups, electrons and other active groups.
Enzymes. Activation energy, active site, features, functioning, control systems, activation and inhibition of enzyme activity, metabolic pathways, cofactors, coenzymes, prosthetic groups.
• ATP SYNTHESIS AND METABOLIC PATHWAYS THAT RELEASE ENERGY. Redox reactions. Glycolysis, aerobic respiraton, Krebs cycle, electron transport chain: oxidative phosphorylation and chemiosmosis. Anaerobic respiraton. Fermentation.
Photosynthesis. Chlorophyll and other pigments. Antenna pigments. Light-dependent reactions. Photosystems I and II. Cyclical and not-cyclical transport of electrons. Chemiosmosis and photophosphorylation. Light-independent reactions and C fixation. Calvin Benson cycle. C4 cycle. Crassulacean acid metabolism (CAM). Photorespiration.
Heterotrophic, autotrophic, phototrophic, chemotrophic organisms.
• ORGANIZATION OF DNA IN CHROMOSOMES, MITOSIS AND MEIOSIS. DNA and proteins, nucleosomes, heterochromatin, euchromatin, chromosome condensation. The cell cycle and its regulation. Mitosis, meiosis and sexual reproduction.
• PRINCIPLES OF MENDEL’S HEREDITY. Definition of phenotype, genotype, locus, gene, dominant and recessive allele, homozygosity and heterozygosity. Segregation and independent assortment. Independence and association. Crossing-over and recombination. Genetic determination of sex. Gene interactions. Incomplete dominance, condominance, multiple alleles, epistasis and polygeny.
• DNA AND GENETIC MATERIAL. Transforming principle in bacteria. Bacterial Transformation and Griffith experiments. Hershey and Chase experiment. DNA structure. Replication. Meselson and Stahl experiment and semiconservative replication. DNA synthesis and error repair.
• GENE EXPRESSION IN DIFFERENT ORGANISMS. Gene/protein relationship. Gene/enzyme hypothesis, Beadle and Tatum experiment. Genetic information pathway. Transcription, mRNA synthesis and maturation. Genetic code, tRNA and translation. Post-transcriptional and post-translational modifications. Coding and noncoding sequences. Prokaryotic and eukaryotic genes. Several types of RNA and gene expression control. DNA mutations and mutagenesis.
• GENERAL ASPECTS OF GENE REGULATION IN PROKARYOTES AND EUKARYOTES. Operons, promoters, inducible and repressible genes, repressors and activators. Positive and negative control of gene transcription. Post-transcriptional and post-translational controls. Epigenetic inheritance. Imprinting. Gene amplification. Promoters, TATA box and UPE. Transcription factors, enhancers. RNA maturation and alternative splicing. RNA stability. Maturation of proteins.
• RECOMBINANT DNA TECHNOLOGY AND GENOMICS. DNA cloning, restriction enzymes, vectors and genomic libraries. Genetic probes. DNA amplification in vitro by polymerase chain reaction (PCR). DNA analysis by means of electrophoresis: Southern, Northern and Western blot. Polymorphisms and DNA sequencing. Definition of structural, functional and comparative genomics. DNA microarray. Human Genome Project, Bioinformatics, Pharmacogenomics and Proteomics.
• HUMAN GENOME. Karyotype analysis and pedigrees. Mouse models for studying genetic diseases in humans. Chromosomal abnormalities and genetic mutations. Autosomal recessive, autosomal dominant, X-linked diseases.
• DEVELOPMENT BIOLOGY. Cell differentiation and morphogenesis. Differential gene expression. Somatic and germ cells. Stem cells. Cloning. Transgenic organisms. Genetic control of development. Model organisms: Drosophila, Caenorbiditis elegans, Mouse, Arabidospsis. Maternal effect genes, the segmentation genes, homeotic genes. Mosaic development, apoptosis. Transgenic mice. Aging process. Plant development. Cancer and cell growth. Growth factors.
• DARWIN AND EVOLUTION. Natural selection. Micro and macro-evolution. Synthetic theory of evolution (neo-Darwinism). Effect of chance. Evidence for evolution. Sedimentary rocks. Fossils. Comparative anatomy. Biogeography, geology (plate tectonics and continents drift) and correlations with evolution. Developmental biology and evolutionary patterns. Molecular comparison among organisms. Universality of the genetic code, evolutionary changes in proteins and DNA. Phylogenetic trees, speciation and divergence between species. Evolutionary hypothesis.
• GENERAL BIOLOGY OF VIRUES AND PROKARIOTES. DNA viruses, RNA viruses (retroviruses) and phages. Origin of the virus. Lytic cycle and virulence. Lysogenic cycle and temperate viruses. Lysogenic conversion. Viruses of vertebrates and viral infections. Elements of plant viruses. Viroids and prions.
Prokaryotes. Archea and Bacteria domains. Gram+ and Gram-. Cilia, flagella, chemotaxis. Binary fission and reproduction of bacteria. Transfer of genetic information. Processing, translation, conjugation. Evolution of bacterial populations. Sporulation. Biofilm. Metabolism: dependence on oxygen and other energy sources. Colonization of extreme environments. Prokaryotes and environment: parasites, saprophytes, symbionts. Prokaryotes and diseases. Antibiotics and resistance. Prokaryotes and commercial processes
• ANIMAL BEHAVIOUR. The influence of sensory stimuli, learning, genetic heritage. The selection for the survival and reproductive success, the concept of total fitness.
Teaching methods consist of frontal lessons. In addition to the suggested texts, supplemental material is offered on the e-learning platform of the course.
Students may request personal reception to the teacher every time they need it throughout the academic year, by email.

Reference texts
Author Title Publishing house Year ISBN Notes
Solomon, Martin, Martin, Berg Elementi di Biologia (Edizione 7) EdiSES 2017 978-88-7959-938-2
CAMPBELL - REECE PRINCIPI DI BIOLOGIA (Edizione 1) PEARSON / BENJAMIN CUMMINGS 2010 9788871926155

Examination Methods

The task of the exam consists in verifying the comprehension of course contents and the ability to accurately expose their arguments with appropriate scientific language.

The exam consists of a written test based on all the course contents featuring multiple-choice questions and open-ended questions. The exams are scheduled in 4 sessions, with intermediate evaluation, as follows: an intermediate written test during the course, 2 exams in the Summer Session at the end of the course, 1 exam in the Fall Session and 1 exam in the Extraordinary Session.
The exam is passed if the evaluation is greater or equal to 18/30.
Students who pass the intermediate test have to pass the final test on the same day of the first exam in the Summer Session; the whole evaluation is obtained as the average of the two evaluations.

Students reaching an evaluation greater or equal to 25/30 in the written test and who aspire to a better vote can take an oral exam (for those who have passed the intermediate test, there is only one oral exam after the final exam).

Students with disabilities or specific learning disorders (SLD), who intend to request the adaptation of the exam, must follow the instructions given HERE

Type D and Type F activities

Modules not yet included

Career prospects


Module/Programme news

News for students

There you will find information, resources and services useful during your time at the University (Student’s exam record, your study plan on ESSE3, Distance Learning courses, university email account, office forms, administrative procedures, etc.). You can log into MyUnivr with your GIA login details: only in this way will you be able to receive notification of all the notices from your teachers and your secretariat via email and soon also via the Univr app.

Graduation

For schedules, administrative requirements and notices on graduation sessions, please refer to the Graduation Sessions - Science and Engineering service.

List of theses and work experience proposals

Stage Research area
Correlated mutations Various topics

Attendance

As stated in the Teaching Regulations for the A.Y. 2022/2023, attendance at the course of study is not mandatory.
 


Career management


Student login and resources


Erasmus+ and other experiences abroad