Learning outcomes of the course unit
Biochemistry is the science dealing with the molecular basis of life. Biochemistry deals with composition, structure and function of molecules typical of living organisms and with the chemical reactions that occur in these organisms. The course aims to make students able to understand fundamental concepts regarding: the relationship between structure and function in biological macromolecules, including globular and fibrous proteins, antibodies, enzymes and nucleic acids; metabolic transformations of nutrients; bioenergetics; properties of biological membranes; primary mechanisms of preservation, transmission and translation into protein of the information contained in genes.The aim is also to provide the tools for students to be able to analyze and solve autonomously simple biochemistry issues.
To deal with the topics of the “Biochemistry” course, students should possess a basic knowledge of Chemistry and Organic Chemistry.
Course contents summary
Amino acids and proteins. Peptide bond. Primary, secondary, tertiary and quaternary structure of proteins. `Folding’ and 'unfolding' of proteins. Antibodies: structure and function. Structural proteins: collagen.
Actin, myosin and muscle contraction.
Mioglobin and hemoglobin.
Enzymes: overview of the mechanism of action of enzymes and enzyme kinetics.
Lipids. classification and properties. Lipids as structural components of membranes: glycerophospholipids, sphingolipids and cholesterol. Lipids with energy reserve function.
Overview of Bioenergetics. “High energy” compounds. ∆G of individual exoergonic and endoergonic metabolism reactions. Exoergonic and endoergonic metabolic sequences.
Carbohydrate metabolism. Glycolysis.. Alcoholic and lactic acid fermentation. Glycogenolysis and glycogenosynthesis. Pyruvate dehydrogenase complex. Tricarboxylic acid (Krebs) cycle. Anaplerotic reactions: pyruvate carboxylase. Gluconeogenesis. Pentose cycle.
Overview of lipid metabolism. Fatty acid beta-oxydation. Ketonic bodies and ketogenesis. Citrate transport system. Synthesis of saturated fatty acids.
Overview of amino acid metabolism. Role and mechanism of transaminase action. Degradation of amino acids. Correlation of amino acid metabolism with carbohydrate and lipid metabolism.
o Respiratory chain and oxidative phosphorylation.
Overview of the preservation, expression and transmission of genic information. DNA as repository of gene information. DNA replication and transcription. Diversification of the function and role of ribosomal, transport and messenger RNA (r-RNA, t-RNA, m-RNA). The genetic code. Protein synthesis: translation.
BiochemistryMathews Van Holde Haren
Lehninger principles of biochemistry
Oral lessons, with the use of multimedia means.
Assessment methods and criteria
Written and oral exams