BMB530: Basic Biochmestry (5 ECTS)

STADS: 01008601

Level
Bachelor course

Teaching period
The course is offered in the autumn semester.

Teacher responsible
Email: frankk@bmb.sdu.dk

Additional teachers
brewer@memphys.sdu.dk

Timetable
Group Type Day Time Classroom Weeks Comment
Common I Monday 12-14 U140 44-46,49
Common I Tuesday 14-16 U140 39-41
Common I Wednesday 10-12 U140 45
Common I Friday 10-12 U140 36-38,43
S1 TL Monday 14-18 BMB 49-50
S1 TE Wednesday 16-18 U142 37-41,43-47
S2 TE Monday 08-10 U145 37-38
S2 TE Monday 08-10 U24 39-41,44-47
S2 TE Tuesday 14-16 U142 43
S2 TL Tuesday 14-18 BMB 49-50
S3 TL Wednesday 14-18 BMB 49-50
S3 TE Thursday 16-18 U142 37-41,43-47
S4 TE Wednesday 08-10 U145 37-41,43-47
S4 TL Thursday 14-18 BMB 49-50
S5 TL Monday 12-16 BMB 51
S5 TL Friday 14-18 BMB 49
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Revison of timetable:
: På grund af mange studerende, er der oprettet et hold S5 i lab.De studerende er fordelt.

Prerequisites:
None

Academic preconditions:
BMB501 Biomolecular Chemistry or BMB531 must be passed

Course introduction
To give the students a basic introduction to the catalytic function and mechanisms of enzyme action, to the structure and function of biological membranes and a basic introduction to eukayotic cell metabolism on a molecular level. The students are introduced to the underlying theory of enzymes and membranes and in the methods used to study these. In addition some biochemical processes in animal and plant metabolism and their regulation are introduced with an emphasis on mammalian cells.        

Expected learning outcome
After completing the course the student should be able to:

  • use methods from chemical kinetics and enzyme kinetics to determine characteristic constants such as KM and turnover number for enzyme, both in theory and in practice
  • explain how the activity of enzymes are regulated, including allosteric regulation
  • explain the structure of biological membranes and how compounds are transported through these
  • use the thermodynamic and kinetic foundations of metabolism and explain the significance of  free energy and euqilibriun constants for coupled reactions and the universal role of ATP in this coupling
  • describe metabolites, enzymes amd coenzymes in glykolysis, glukoneogenesis, the citric acid cycle, glyoxylate cycle and the principles behind regulation and integration of these pathways
  • explain the pentose phosphate pathway and its regulation by metabolittes and coenzymes       
  • describe the transport of glucose in blood and how these compounds are taken up by cells
  • describe the light reactions of photosynthesis and CO2-fixation in plants (biology students)
Subject overview
The following topics will be covered:

  1. Chemical kinetics 
  2.  Simple Michaelis-Menten kinetics
  3. Regulation of enzyme activity
  4. Lipid structures in aqueous solution
  5. Models of biological membranes
  6. Active and passive membrane transport
  7. Ion channels
  8. Metabolism: basic terms and principles
  9. Glykolysis and gluconeogenesis
  10. TCA and oxidative phosphorylation
  11. Glycogen metabolism
  12. Integration of metabolism
Literature
  • Oplyses senere.
  • Laurence A. Moran (Author), Robert A Horton (Author), Gray Scrimgeour (Author), Marc Perry (Author): Principles of Biochemistry , 5th Edition.


Website
This course uses e-learn (blackboard).

Prerequisites for participating in the exam
None

Assessment and marking:
  1. Lab. work. Pass/fail, internal evaluation by teacher. 1 ECTS
  2. Written exam, Danish 7 mark scale, external examiner. 4 ECTS. The written exam is given as a digital exam on e-learn.

Reexam in the same exam period or immediately thereafter.



Expected working hours
The teaching method is based on three phase model.
Intro phase: 22 hours
Skills training phase: 28 hours, hereof:
 - Tutorials: 20 hours
 - Laboratory exercises: 8 hours

Educational activities

Language
This course is taught in Danish.

Course enrollment
See deadline of enrolment.

Tuition fees for single courses
See fees for single courses.