Microbiology
A.Y. 2025/2026
Learning objectives
The aim of the course is to provide a solid foundational knowledge of the microbial world, essential for competently tackling advanced microbiological subjects and related disciplines. Special emphasis will be placed on bacteria of agro-food interest and microorganisms involved in the biogeochemical cycles of carbon and nitrogen in the soil. Through a balanced combination of lectures and laboratory activities, the course will ensure an in-depth understanding of microbiology, along with fundamental technical skills.
The course is closely related to the biochemistry course, which will provide the basis for deepening the understanding of microbial metabolism, and to enological microbiology, offering essential references for understanding the structure and function of microorganisms in applied contexts. This interdisciplinary approach will enable students to develop an integrated view of microbiology, preparing them to understand both theoretical and practical aspects of the field.
The course is closely related to the biochemistry course, which will provide the basis for deepening the understanding of microbial metabolism, and to enological microbiology, offering essential references for understanding the structure and function of microorganisms in applied contexts. This interdisciplinary approach will enable students to develop an integrated view of microbiology, preparing them to understand both theoretical and practical aspects of the field.
Expected learning outcomes
At the end of the course, the student will be able to:
· Describe in detail the morphology and biochemical structure of bacteria, yeasts, and viruses.
· Apply practical methodologies for the isolation and identification of specific bacteria, using both classical and molecular techniques.
· List and explain the main energy metabolic pathways of chemo-organoheterotrophic bacteria, with particular focus on lactic and acetic bacteria.
· Understand and describe the principles of bacterial adaptation, selection, and genetic variability.
Additionally, the student will develop transversal skills, such as:
· The ability to critically analyze and assess the application of microorganisms in various contexts, such as agro-food, environmental, or biotechnological fields.
· The ability to communicate concepts learned during the course with precision and using appropriate scientific terminology.
· A solid foundation for independently exploring topics in applied microbiology, fostering an independent and informed approach to study.
· Describe in detail the morphology and biochemical structure of bacteria, yeasts, and viruses.
· Apply practical methodologies for the isolation and identification of specific bacteria, using both classical and molecular techniques.
· List and explain the main energy metabolic pathways of chemo-organoheterotrophic bacteria, with particular focus on lactic and acetic bacteria.
· Understand and describe the principles of bacterial adaptation, selection, and genetic variability.
Additionally, the student will develop transversal skills, such as:
· The ability to critically analyze and assess the application of microorganisms in various contexts, such as agro-food, environmental, or biotechnological fields.
· The ability to communicate concepts learned during the course with precision and using appropriate scientific terminology.
· A solid foundation for independently exploring topics in applied microbiology, fostering an independent and informed approach to study.
Lesson period: First semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course cannot be attended as a single course. Please check our list of single courses to find the ones available for enrolment.
Course syllabus and organization
Single session
Responsible
Lesson period
First semester
Course syllabus
Introduction to microbiology; the classification of living beings; the optical microscope. The Gram stain. The bacterial wall. The cell wall of Saccharomyces cerevisiae. The capsule; flagella, cilia and pili; bacterial endospore. Examples of spore-forming bacteria: Bacillus thuringiensis, Bacillus licheniformis and Clostridium botulinum. The cell membrane and membrane transport. The nutritional and energy needs of microorganisms. The chemical / physical environmental needs of microorganisms: microorganisms and oxygen. The chemical / physical environmental needs of microorganisms: microorganisms and osmotic pressure (water activity). Bacterial reproduction: the bacterial growth curve; the asexual reproduction of Saccharomyces cerevisiae. Cultivation media: classification based on physical state, chemical composition and function. The concept of sterility and the tools used for work in sterility; the types of sowing. The determination of the microbial load with direct and indirect measurements: the total microbial count with counting chambers; description and calculation examples for the vital count with the method of sowing serial decimal dilutions (the concept of CFU, the weighted average for the calculation of CFU). The eumycetes: filamentous fungi, the classification of eumycetes on the basis of asexual and sexual reproduction. Soil bacteria. Soil-plant-microorganism interactions: rhizosphere, root nodules of legumes, nitrogen fixation, Agrobacterium, mycorrhizae. Introduction to cellular metabolism: ATP and its formation. Free electron carriers (NAD and NADP). The production routes of pyruvate: Embden-Meyerhof route, pentose phosphate and Entner-Doudoroff. The definition of the catabolic processes of respiration and fermentation. The different types of fermentation in bacteria (alcoholic, lactic, mixed acid, butylene glycol, propionic, butyric and homoacetic fermentations). The fructose-6-phosphate phosphoketolase pathway. Lactic bacteria and their metabolism; acetic bacteria and their metabolism. Hints of anabolism. Principles of microbial genetics; the central dogma of biology; the regulation of transcription (lac operon, operon, tryptophan operon, regulon maltose); protein synthesis in prokaryotes. The concept of life in biology and viruses; bacteriophages; the plasmids. How microbial biodiversity is generated: horizontal gene transfer. The mechanisms of natural genetic recombination in bacteria: transformation, conjugation and transduction. The polymerase chain reaction. Taxonomy and bacterial identification. The 16S rRNA gene; the 16S rRNA gene in bacterial identification and in the study of bacterial phylogeny. Ongoing assessment of students' preparation
Laboratory activities program
During the exercises in the educational laboratories, the importance and ways of working in sterility in microbiology are illustrated (explanation of the Bunsen burner, oxidizing flame, sterility cone); the instruments used in classical microbiology are shown and used (loops, spatulas, pipettes, test tubes, slants, flasks, Petri dishes, liquid and agarized culture media); taught how to prepare decimal serial dilutions starting from samples of different origin of unknown concentration and then continue with sowing techniques by spatulation and incorporation on selective soils, following which it is explained how to perform the calculation of vital count from the colony forming units grown in the plate ; from suspensions of yeasts or bacteria of unknown concentration it is shown how to perform a calculation of the total count through the counting chamber under the optical microscope and also the viable count by means of methylene blue; the smear seeding technique is shown to obtain isolated colonies and pure cultures with the use of selective media; examples of biochemical assays to be carried out in plates are shown to highlight some microbial enzymatic activities (catalase, amylase, protease); tests of fermentative metabolism of lactobacilli are carried out with assays of use of different sources of sugars, and how the growth of anaerobic microorganisms is promoted; Gram staining is explained and performed; the principles of phase contrast optical microscopy are illustrated, with examples of observation of fresh preparations of different bacteria and yeasts, and of staining of bacteria from complex food matrices.
Laboratory activities program
During the exercises in the educational laboratories, the importance and ways of working in sterility in microbiology are illustrated (explanation of the Bunsen burner, oxidizing flame, sterility cone); the instruments used in classical microbiology are shown and used (loops, spatulas, pipettes, test tubes, slants, flasks, Petri dishes, liquid and agarized culture media); taught how to prepare decimal serial dilutions starting from samples of different origin of unknown concentration and then continue with sowing techniques by spatulation and incorporation on selective soils, following which it is explained how to perform the calculation of vital count from the colony forming units grown in the plate ; from suspensions of yeasts or bacteria of unknown concentration it is shown how to perform a calculation of the total count through the counting chamber under the optical microscope and also the viable count by means of methylene blue; the smear seeding technique is shown to obtain isolated colonies and pure cultures with the use of selective media; examples of biochemical assays to be carried out in plates are shown to highlight some microbial enzymatic activities (catalase, amylase, protease); tests of fermentative metabolism of lactobacilli are carried out with assays of use of different sources of sugars, and how the growth of anaerobic microorganisms is promoted; Gram staining is explained and performed; the principles of phase contrast optical microscopy are illustrated, with examples of observation of fresh preparations of different bacteria and yeasts, and of staining of bacteria from complex food matrices.
Prerequisites for admission
This course includes the compulsory prerequisites of Plant Biology. In addition, it is strongly recommended that you have acquired the basic concepts of teaching Organic Chemistry.
Teaching methods
The course will be delivered through two-hour lectures, complemented by practical laboratory sessions in microbiology. While attendance at these laboratory sessions is not mandatory, it is strongly recommended to maximize learning outcomes. Dates for the laboratory sessions and registration procedures will be communicated during the initial lectures, with registration taking place directly in the classroom.
The teaching methods are designed to ensure comprehensive learning and the achievement of the course's educational objectives. The lectures provide a solid theoretical foundation, systematically addressing key concepts in microbiology and equipping students with the tools necessary to understand the microbial world, with particular emphasis on microorganisms of agro-food and environmental interest.
Practical laboratory exercises play a crucial role in the course, allowing students to apply the theoretical knowledge acquired. Through these activities, students will develop essential technical skills for manipulating microorganisms, using specific equipment, and adopting advanced experimental methodologies. Practical experience enhances the development of analytical and critical skills, which are vital for addressing real-world problems in microbiology, preparing students to tackle scientific and professional challenges effectively.
In summary, the combination of theoretical lectures and practical activities ensures a balanced and in-depth education, fostering both conceptual and operational skills necessary for approaching the field of microbiology with a comprehensive and interdisciplinary approach.
The teaching methods are designed to ensure comprehensive learning and the achievement of the course's educational objectives. The lectures provide a solid theoretical foundation, systematically addressing key concepts in microbiology and equipping students with the tools necessary to understand the microbial world, with particular emphasis on microorganisms of agro-food and environmental interest.
Practical laboratory exercises play a crucial role in the course, allowing students to apply the theoretical knowledge acquired. Through these activities, students will develop essential technical skills for manipulating microorganisms, using specific equipment, and adopting advanced experimental methodologies. Practical experience enhances the development of analytical and critical skills, which are vital for addressing real-world problems in microbiology, preparing students to tackle scientific and professional challenges effectively.
In summary, the combination of theoretical lectures and practical activities ensures a balanced and in-depth education, fostering both conceptual and operational skills necessary for approaching the field of microbiology with a comprehensive and interdisciplinary approach.
Teaching Resources
The material for exam preparation includes slides available on myAriel, which, along with the notes taken during lectures, will be sufficient for thorough exam preparation. For those who wish to delve deeper into topics that may not have been entirely clear during class, the following reference texts are recommended:
· "Microbiology of Microorganisms" by Martinko, Ben, and Madigan; published by Pearson.
· "Microbiology" by Schaechter, Moselio, Ingraham, John L., and Neidhardt, Frederick C.; published by Zanichelli.
These texts provide a comprehensive and detailed overview of the topics covered in the course and can be helpful for clarifying any doubts or for further exploring specific areas of interest.
· "Microbiology of Microorganisms" by Martinko, Ben, and Madigan; published by Pearson.
· "Microbiology" by Schaechter, Moselio, Ingraham, John L., and Neidhardt, Frederick C.; published by Zanichelli.
These texts provide a comprehensive and detailed overview of the topics covered in the course and can be helpful for clarifying any doubts or for further exploring specific areas of interest.
Assessment methods and Criteria
Exam format: A written test consisting of multiple-choice questions (10 questions) and open-ended questions (7 questions), with a total duration of 60 minutes. The open-ended questions will include 4 questions covering the topics addressed during the lectures and 3 questions related to the topics covered during the laboratory sessions. Therefore, knowledge and skills related to the laboratory exercises will also be assessed in the exam, even for students who did not attend the practical sessions. A calculator may be brought to the exam to solve potential calculation problems.
Students with specific learning disabilities (SLD) or disabilities are requested to contact the instructor via email at least 10 days before the exam date to agree on any necessary individualized measures. In the email addressed to the instructor, students must cc the relevant University Services: [email protected] (for students with SLD) and [email protected] (for students with disabilities).
Assessment: Each multiple-choice question will be worth 1 point, while the open-ended questions will be worth 3 points each, for a total of 31 points. The final grade will be expressed in thirtieths. Failure to correctly answer more than 4 multiple-choice questions will result in failing the exam.
No mid-term or early exams are scheduled.
Communication of results: Results will be communicated via UNIMIA services (formerly SIFA), with the option for students to reject the grade.
Students with learning disabilities (DSA) and disabilities are requested to contact the instructor via email at least 10 days before the scheduled exam date to arrange any individualized measures. In the email addressed to the instructor, it is necessary to CC the respective University Services: [email protected] (for students with learning disabilities) and [email protected] (for students with disabilities).
-Evaluation: Each multiple-choice question will be worth 1 point, while the open-ended questions will be worth 3 points each, totaling 31 points. The grade will be expressed on a scale of thirty. Failing to answer more than 4 multiple-choice questions correctly will result in exam failure. There are no midterm exams or pre-exam sessions.
-Communication of exam results: through the UNIMIA services (formerly SIFA) with the option for students to refuse the grade.
Students with specific learning disabilities (SLD) or disabilities are requested to contact the instructor via email at least 10 days before the exam date to agree on any necessary individualized measures. In the email addressed to the instructor, students must cc the relevant University Services: [email protected] (for students with SLD) and [email protected] (for students with disabilities).
Assessment: Each multiple-choice question will be worth 1 point, while the open-ended questions will be worth 3 points each, for a total of 31 points. The final grade will be expressed in thirtieths. Failure to correctly answer more than 4 multiple-choice questions will result in failing the exam.
No mid-term or early exams are scheduled.
Communication of results: Results will be communicated via UNIMIA services (formerly SIFA), with the option for students to reject the grade.
Students with learning disabilities (DSA) and disabilities are requested to contact the instructor via email at least 10 days before the scheduled exam date to arrange any individualized measures. In the email addressed to the instructor, it is necessary to CC the respective University Services: [email protected] (for students with learning disabilities) and [email protected] (for students with disabilities).
-Evaluation: Each multiple-choice question will be worth 1 point, while the open-ended questions will be worth 3 points each, totaling 31 points. The grade will be expressed on a scale of thirty. Failing to answer more than 4 multiple-choice questions correctly will result in exam failure. There are no midterm exams or pre-exam sessions.
-Communication of exam results: through the UNIMIA services (formerly SIFA) with the option for students to refuse the grade.
AGR/16 - AGRICULTURAL MICROBIOLOGY - University credits: 6
Laboratories: 16 hours
Lessons: 40 hours
Lessons: 40 hours
Professors:
Gargari Giorgio, Mangieri Nicola
Shifts:
Professor(s)