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87995 - Physical Methods of Biology

Academic Year 2023/2024

                
                        Docente:
                        Emanuele Paci
                    
                        Credits:
                        6
                    
                        SSD:
                        FIS/07
                    
                        Language:
                        English
                    
                        Teaching Mode:
                        Traditional lectures
                        
                            Campus:
                            Bologna
                        
                            Corso:
                            Second cycle degree programme (LM) in
                            Physics (cod. 9245)

                            Teaching resources on Virtuale
                        
                                    Course Timetable
                                
from Sep 27, 2023 to Dec 21, 2023

Learning outcomes

The course will focus on the physical laws that underlie life. At the end of the course the student will acquire a broad understanding of the relation between physics, chemistry, and biology. They will be able to use theoretical and computational methods to predict properties of biomolecules and advanced experimental methods currently available to investigate the relation between genotype and phenotype.

Course contents

What is life? Can we understand life in terms of fundamental physical principles? The course focuses on the physical principle behind the emergent biological properties of biomolecules and computational and experimental methods to characterize them.

1) Biology, chemistry and physics; top-down and bottom-up approaches; fundamental physics laws and emergent biological properties; time and length scales.

2) Biological molecules: proteins, DNA, RNA, lipids and their environment.

3) Intramolecular and intermolecular interactions

4) Thermodynamics and statistical mechanics of chemical interactions and biopolymers; chemical and biomolecular kinetics;

5) Atomistic simulation as a computational microscope; molecular dynamics and Monte Carlo simulation; estimation of thermodynamic and kinetic properties; free energy methods.

6) Protein folding; physics-based and knowledge-based methods for protein structure prediction.

7) Experimental biophysics, with a focus on methods to investigate structure and dynamics of proteins (x-ray diffraction; NMR; cryo-EM; SMFS; FRET)

8) Stochastic processes (master equation, Markov processes)

9) Physics of brain

Readings/Bibliography

Schrödinger, What is Physics? Cambridge 1944
van Kampen, Stochastic Processes in Physics and Chemistry, Elsevier 2011
Frenkel & Smit, Understanding Molecular Simulation, Academic Press 2002
Nelson, Biological Physics. Energy, Information, Life., Freeman 2008
Zuckerman, Statistical Physics of Biomolecules: an Introduction, CRC Press, 2010
Finkelstein & Ptitsyn, Protein Physics, Academic Press, 2002
Bialek, Biophysics: Searching for Principles, Princeton University Press, 2012
Leach, Molecular Modelling: Principles and Applications, Pearson 2001
Zaccai, Serdyuk & Zaccai, Methods in Molecular Biophysics, Cambridge University Press, 2017

Teaching methods

Lectures, tutorials, seminars

Assessment methods

Oral exam.

Teaching tools

Access to computers and virtual reality suite for students choosing specific projects.

Office hours

See the website of Emanuele Paci