STRUCTURE AND EXPRESSION OF EUKARYOTIC GENOMES
cod. 1007199

Academic year 2019/20
1° year of course - Second semester
Professor
Roberto FERRARI
Academic discipline
Biologia molecolare (BIO/11)
Field
Discipline del settore biomolecolare
Type of training activity
Characterising
76 hours
of face-to-face activities
9 credits
hub: PARMA
course unit
in ITALIAN

Learning objectives


Acquiring knowledge and understanding.
The objective is for the students to gain solid and thorough knowledge of the organization of genomes and on the mechanisms and regulation of gene expression in eukaryotic organisms, with emphasis on the emerging roles of noncoding RNA (ncRNA) in gene regulation.

Applying knowledge and understanding.
Through guided analysis of key experiments for the molecular understanding of some aspects of eukaryotic gene regulation, the students are expected to strengthen their competence in addressing the experimental study of novel gene expression regulatory pathways and of the involved molecular mechanisms, and the identification and characterization of novel regulatory ncRNAs.

Prerequisites


Good knowledge of the structure of nucleic acids and the basic mechanisms of duplications, transcription, repair and recombination of DNA.

Course unit content


Genomes. Unique sequences, repeated sequences and informative content of eukaryotic genomes; fraction of genes expressed in a single cell type. Molecular anatomy of a eukaryotic gene: conservation of exons and their structural organization and high intronic variability; evolution of genomes and possible functional significance. Tandem repetition of rRNA genes. Highly repeated sequences and satellite DNA: evolution of satellite DNA mediated by unequal crossing-over events; minisatellites and genetic mapping. Retrovirus, retroposons and interspersed repeated sequences; structure, life cycle and mobilization of retroviruses; retrotransposons, SINE and LINE sequences and processed pseudogenes. Organellar genomes: circular DNA molecules of mitochondrial and chloroplast genomes. Mapping of genomes.

Chromatin. Chromatin, chromosomes and gene activation: the problem of genomic compaction; the nucleosome as the fundamental subunit of chromatin; organization and assembly of octameric histones; phasing nucleosomes, hypersensitive sites; histone covalent modifications; higher order structure of chromatin; centromeres, telomeres and structure of chromosomes. Eukaryotic transcription. Eukaryotic RNA polymerases; eukaryotic promoters; transcription mchineries of RNA polymerases I and III; RNA polymerase II transcription apparatus; eukaryotic transcription control mechanisms; regulatory "in cis" sequences; regulatory trans-acting factors; DNA binding and transcriptional activation; structural protein motifs involved in DNA binding and transcriptional activation. Transcription regulation mechanisms through "enhancers", "silencers" and "insulators"; chromatin structure and its effects on transcription; histone code; structural and functional organization of euchromatin and heterochromatin; covalent and non covalent modifiers of chromatin; genomic imprinting.
Regulatory RNAs. siRNA and RNAi, miRNA, ncRNA and gene regulation. Long noncoding RNAs. Maturation of RNA. Adjustment of RNA processing mechanisms. Alternative splicing; editing of primary transcripts. Coordination of RNA processing events. mRNA stability control systems. Eukaryotic translation: mechanism and regulation.

Full programme

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Bibliography


Reference textbooks
LODISH et al., MOLECULAR CELL BIOLOGY, 8th edition, W.H. Freeman & C. publishers, 2016;
also available in Italian translation (less updated edition):
LODISH et al., BIOLOGIA MOLECOLARE DELLA CELLULA, Zanichelli (2009), 3rd italian edition on the original edition.
Other textbooks
WATSON D. et al. - BIOLOGIA MOLECOLARE DEL GENE, settima edizione, Zanichelli 2015
AMALDI et al. – BIOLOGIA MOLECOLARE, seconda edizione, CEA 2014
CRAIG N. et al. – BIOLOGIA MOLECOLARE-Principi di funzionamento del genoma. Pearson 2013.

Teaching methods


The course consists of lectures on key topics in the program, and in-depth focus on topics of particular relevance and interest, with the use of original scientific articles and the assistance of specialist researchers.

Assessment methods and criteria


Evaluation of the expected achievements will be based on an oral interview/test. The test is devised to evaluate both the molecular-level knowledge of gene expression and regulation mechanisms illustrated during the course, and the ability to apply such a knowledge to addressing and solving experimental problems.

Other information

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2030 agenda goals for sustainable development

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Contacts

Toll-free number

800 904 084

Student registry office

E. segreteria.scienze@unipr.it
T. +39 0521 905116

Quality assurance office

T. +39 0521 905613
Office E.didattica.scvsa@unipr.it
 

President of the degree course

Prof. Claudio RIvetti
E. claudio.rivetti@unipr.it

Faculty advisor

Prof. Riccardo Percudani
E. riccardo.percudani@unipr.it

Career guidance delegate

Prof. Riccardo Percudani
E. riccardo.percudani@unipr.it

Erasmus delegates

Prof. Alessio Peracchi
E. alessio.peracchi@unipr.it

Quality assurance manager

Prof. Matteo Tegoni
E. matteo.tegoni@unipr.it

Tutor students

Dott.ssa Riva Elena
E. elena.riva2@studenti.unipr.it