Unit FOOD BIOCHEMISTRY
- Course
- Food science and technology
- Study-unit Code
- 80053506
- Curriculum
- Tecnologie agro-alimentari
- Teacher
- Daniele Del Buono
- Teachers
-
- Daniele Del Buono
- Hours
- 54 ore - Daniele Del Buono
- CFU
- 6
- Course Regulation
- Coorte 2022
- Offered
- 2023/24
- Learning activities
- Caratterizzante
- Area
- Discipline della tecnologia alimentare
- Academic discipline
- AGR/13
- Type of study-unit
- Obbligatorio (Required)
- Type of learning activities
- Attività formativa monodisciplinare
- Language of instruction
- Italian
- Contents
- The course topics will regard living matter, from the simplest chemical events in the cells to the more recent technology. The course will address the role that the major classes of molecules exert in metabolism and the kinetic aspects of enzymology, thermodynamics and bioenergetics. In addition, the main metabolic processes, photosynthesis, metabolism of carbohydrates, lipids and amino acids, protein metabolism and genetic information will be addressed.
- Reference texts
- D. DEL BUONO, Dispense dalle lezioni.
PINTON R., COCUCCI M., NANNIPIERI P., TREVISAN M., Fondamenti di Biochimica Agraria. Pàtron Editore, Bologna
DAVID L. NELSON, MICHAEL M. COX, I Principi di Biochimica di Lehninger, Zanichelli - Educational objectives
- The main aim of the course is to provide students with a basic understanding of Biochemistry.
Course Goals
Knowledge
1. Energetic flows of the metabolism.
2. Evaluation of the energetic balances associated with the metabolic processes.
3. Enzyme catalysis and the effect of inhibitors and regulators.
4. Photosynthetic process.
5. Carbohydrates' metabolism in plant and animal cells.
6. Processes of fermentation and respiration.
7. Biosynthesis and catabolism of lipids.
8. Metabolism of amino acids and proteins.
9. The formation, structural characteristics and properties of DNA and RNA and their involvement in protein synthesis.
Skills
1. Assessment of the spontaneity of biochemical reactions.
2. Identification of the enzymes involved in the different metabolic pathways.
3. Calculation of the energy obtainable in the catabolism of carbohydrates.
4. Calculation of metabolic energy required for the biosynthesis of fatty acids and triglycerides and then that obtainable from their catabolism.
5. Evaluation of the protein content of food and agricultural products.
6. Links among the various metabolic pathways. - Prerequisites
- To understand the main aspects of this course, the students must have successfully passed the Chemistry course (first year). In particular, the students should be able to apply the basic concepts of inorganic chemistry and recognize the principal functional groups of organic molecules and their reactivity.
- Teaching methods
- The course will be organized in:
- classroom teaching aimed at developing theoretical skills;
- classroom exercises in order to determine the amounts of energy changes associated with reactions in the cells and the evaluations of energy balances related to carbohydrates and lipids metabolism;
- Laboratory experiments aimed to estimate the content of plant pigments and proteins and determine the activity of some enzymes. - Other information
- Student reception will be held every afternoon Monday through Friday from 2:30 to 4 p.m. at the RU of Agricultural Chemistry.
- Learning verification modality
- The examination will consist of a final test (about 40 minutes) to verify the students' level of knowledge and understanding of the theoretical and methodological contents of the program. The discussion will cover some topics of the course, including bioenergetics, protein structure and catalysis, photosynthesis, primary metabolism, the nitrogen cycle in plants, DNA and RNA, and protein biosynthesis.
Student evaluation
18-21: sufficient knowledge of the basic topics of the course; sufficient understanding of the concepts.
22-24: good knowledge of the course topics;
good understanding of the concepts.
25-27: very good knowledge of the course topics;
very good understanding of the concepts.
28-30: excellent knowledge of the course topics;
excellent understanding of the concepts.
The examination will also test the student's ability to communicate and explain the topics covered by the course. Lastly, the test will assess the student's ability to apply the knowledge acquired to the solution of practical cases, working out solutions independently.
For information on support services for students with disabilities visit http://www.unipg.it/disabilita-e-dsa - Extended program
- Bioenergetics and enzyme catalysis. Elements of thermodynamics and biochemical reactions. Concepts of enthalpy, entropy and free energy, exergonic and endergonic reactions and their coupling. Concept of metabolism and energy flows in catabolic and anabolic phases. Mechanism of enzyme catalysis, structure and characteristics of the enzymes, the Michaelis-Menten theory and definition of the kinetic parameters of an enzyme. Inhibition and regulation of enzyme activity. Isoenzymes, allosteric enzymes and zymogens. Mechanism of action and biochemical role of hydrolases, oxidoreductases, transferases, lyases, isomerases and ligases.
Photosynthesis and carbohydrate synthesis: Photosynthetic pigments. Role of the light and the reaction of Hill. The photosystems and photosynthetic electron transport. Cyclic and non-cyclic photophosphorylation. CO2 fixation and the Calvin cycle. Photorespiration. Formation of monosaccharides, oligosaccharides and polysaccharides.
Respiration and carbohydrate metabolism: glycolysis and fermentation processes. The way of the phosphogluconate. Gluconeogenesis. Citric acid cycle and glyoxylate way. Respiratory chain and oxidative phosphorylation. The energy yield of fermentation processes and respiratory systems.
The metabolism of fatty substances: Nature and chemical structure of fatty substances. Biogenesis of fatty acids, glycerides and the related energy requirements. Catabolism of fatty acids and triglycerides. Energy and nutrient budgets in the catabolism of fatty acids and glycerides. Biochemical role and metabolism of phospholipids, sphingolipids and sterols.
Metabolism of nitrogen compounds: Notes on the nitrogen cycle in nature. Biochemical aspects of nitrogen fixation, nitrate reduction, and insert on carbon structures of ammonia. Formation of amino acids and proteins. Protein catabolism: proteolysis, oxidative degradation of amino acids and nitrogen mineralization.
Nucleic acids: DNA structure. DNA replication: the role of DNA polymerase, helicase, topoisomerase, primase and DNA ligase. DNA repair. Structure and synthesis of RNA, the role of RNA polymerase, transcription and post-transcriptional modifications. Genetic code and its translation into protein synthesis.