Type A
|
Code |
Competences Specific | | A8 |
Analyse appropriately data and experimental results from the fields of biotechnology with statistical techniques and be able to interpret it. |
| A9 |
Know in depth the microorganisms, both prokaryotes and eukaryotes, viruses, as well as the diversity of metabolisms present in prokaryotes, and their possibilities of biotechnological use. |
| A15 |
Know the diversity of existing biotechnological processes and products, as well as the recent biotechnological advances, and know how to explain them and communicate them to diverse audiences. |
Type B
|
Code |
Competences Transversal |
Type C
|
Code |
Competences Nuclear |
Type A
|
Code |
Learning outcomes |
| A8 |
Know the molecular biology of systems to its genomic, transcriptomic, proteomic and metabolomic aspects.
| | A9 |
Metabolically modify biotechnological microbian models in the food, medicine and agriculture sectors.
| | A15 |
Master the techniques of molecular biology used to obtain genetically modified animals and plants, and know the possibilities of applying molecular biotechnology to animals and plants.
|
Type B
|
Code |
Learning outcomes |
Type C
|
Code |
Learning outcomes |
Topic |
Sub-topic |
1. Microbial biotechnology: theoretical concepts, history and areas of incidence |
|
2. Availability and selection of microbial biotechnology models |
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3. Genetic engineering of microbial metabolism |
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4. Techniques for the creation and selection of microbial mutants with biotechnological interest |
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5. Biotechnological strategies in the development of bacteria for industrial and agricultural use |
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6. Microorganisms as producers of biomolecules |
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7. Biotechnologically developed microorganisms for the aromas and biofuels industry |
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8. Yeast as a model and tool in the knowledge of the cell higher eukaryotes and their application in medicine |
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Methodologies :: Tests |
|
Competences |
(*) Class hours
|
Hours outside the classroom
|
(**) Total hours |
Introductory activities |
|
2 |
0 |
2 |
Lecture |
|
25 |
37 |
62 |
Problem solving, exercises in the classroom |
|
4 |
0 |
4 |
Laboratory practicals |
|
20 |
10 |
30 |
Personal attention |
|
2 |
0 |
2 |
|
|
(*) On e-learning, hours of virtual attendance of the teacher. (**) The information in the planning table is for guidance only and does not take into account the heterogeneity of the students. |
Methodologies
|
Description |
Introductory activities |
In the theoretical classes will be exposed the scientific and practical foundations for the comprehension of the bibliography that the students must present in the second part of the following class. In this way, only the first theoretical class will not count on the active participation of the students. |
Lecture |
From the second class the students will be proposed the following dynamic: 40 min will be occupied by the teacher to teach the basic concepts of the bibliography to be presented by the students. In the second part of the next class: 25 min for the presentation of an article by the students, 15 min for the questions by the audience, 25 min for the presentation of a second article by the students and 15 min for questions by the audience. |
Problem solving, exercises in the classroom |
The responsible students for the exhibition must present on the website of the subject the possible answers using any of the existing supports on the internet. |
Laboratory practicals |
Design to develop genetic modifications of microorganisms and evaluate them at the molecular and physiological level. |
Personal attention |
The students will have a weekly consultation schedule to solve specific doubts of the subject. |
Description |
The students will have a weekly consultation schedule to solve specific doubts of the subject. |
Methodologies |
Competences
|
Description |
Weight |
|
|
|
|
Lecture |
|
Individual written questionnaire of a scientific article similar to those made in class |
30% |
Problem solving, exercises in the classroom |
|
The ability to discuss and answer questions about the topics taught during the lectures. |
20% |
Laboratory practicals |
|
Recognition of the critical points for the development of genetically modified microorganisms. |
50% |
Others |
|
|
|
|
Other comments and second exam session |
The second call will consist of an examination of all the contents of the subject. The demonstration of the fraudulent conduct of some evaluative activity of a subject in both material and virtual or electronic support leads to the student the failing grade of this evaluation activity. Regardless of this, in view of the seriousness of the facts, the centre may propose the initiation of a disciplinary file, which will be initiated by resolution of the rector. |
Basic |
, Recombinant Gene Expression, Methods in Molecular Biology Volume 824, 2012
, Recombinant Protein Production in Yeast: Methods and Protocols, Series: Methods in Molecular Biology, Volume: 866, 2012
Satyanarayana, T., Yeast Biotechnology: Diversity and Applications, Kunze, Gotthard (Eds.), 2009
Alexander N. Glazer and Hiroshi Nikaido, Microbial Biotechnology “Fundamentals of Applied Microbiology”, University of California, Berkeley, 2007
Lee Yuan Kun, Microbial Biotechnology “Principles and Applications”, World Scientific Publishing Co. Pte Ltd, 2006
Jose-luis Barredo, Methods in Biotechnology “Microbial Processes and Products”, Humana Press Inc, 2005
Walker, Graeme M, Yeast - Physiology and Biotechnology, John Wiley & Sons, 1998
|
Microbial biotechnology (2006)by
Association of Microbiologsits Annual Conference Dharwad, Karnataka), A. R.
Alagawadi Microbial Biotechnology: Technological Challenges and
Developmental Trends (2016) by Bhima. Bhukya, Anjana Devi. Tangutur Microbial biodegradation and bioremediation (2014)by Surajit Das Microbial biotechnology: fundamentals of applied
microbiology (2007)by Alexander N. Glazer, Hiroshi. Nikaido Microbial biotechnology : principles and applications (2013)by Yuan-Kun. Lee Microbial production of food ingredients, enzymes, and
nutraceuticals (2013)by B. McNeil, D. B. Archer, Ioannis Giavasis, L. M. Harvey Microbial biotechnology in agriculture and aquaculture (2005) by Ramesh C. Ray Molecular biotechnology : principles and applications of
recombinant DNA (2010) by Bernard R. Glick, Jack J.
Pasternak, Cheryl L. Patten Yeast physiology and biotechnology (1998) by Graeme M. Walker Yeast: molecular and cell biology (2012) by Horst Feldmann (Cytologist), Paola. Branduardi Yeast biotechnology: diversity and Applications (2009) by T. Satyanarayana, Gotthard.
Kunze Biotechnology and biology of trichoderma (2014)by Vijai Kumar. Gupta Food bioactives: extraction and biotechnology applications (2017)by Munish Puri Crop improvement through microbial biotechnology (2018)by Ram Prasad, Sarvajeet Singh Gill, Narendra Tuteja Recombinant protein production in yeast (2012) Bill, Roslyn M., Springer proteomics The metabolism and molecular physiology of Saccharomyces cerevisiae (2004) J. R. Dickinson & M. Schweizer |
Complementary |
|
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Subjects that continue the syllabus |
ANIMAL AND PLANT BIOTECHNOLOGY/19204122 | FROM MODEL ORGANISMS TO HUMAN BIOLOGY/19204218 |
|
Subjects that it is recommended to have taken before |
BIOCHEMISTRY/19204008 | CELL BIOLOGY/19204006 | METABOLISM OF MICROORGANISMS/19204110 |
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(*)The teaching guide is the document in which the URV publishes the information about all its courses. It is a public document and cannot be modified. Only in exceptional cases can it be revised by the competent agent or duly revised so that it is in line with current legislation. |
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