Difference between revisions of "Lecture 03"
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;Links summary: | ;Links summary: | ||
− | *... | + | *[http://www.nature.com/news/ ''Nature'' news] |
+ | *[http://sciencenow.sciencemag.org/ ''Science'' news] | ||
+ | *[http://rebase.neb.com/ ReBase] | ||
+ | *[http://wishart.biology.ualberta.ca/PlasMapper/index.html PlasMapper] | ||
+ | *[http://www.expasy.org/prosite prosite] | ||
+ | *[http://www.expasy.org/tools the ExPASy tools collection] | ||
+ | | ||
;Exercises | ;Exercises | ||
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======Slide 007====== | ======Slide 007====== | ||
[[Image:L03_s007.jpg|frame|none|Lecture 03, Slide 007<br> | [[Image:L03_s007.jpg|frame|none|Lecture 03, Slide 007<br> | ||
− | A protein's isoelectric point depends on the pK values of the amino acids; the pK values characterize the propensity fo an amino acid sidechain to dissociate, which in turn depends on how energetically favourable dissociation is. For example: since a negatively charged amino acid will be stabilized in a positive electrostatic field, such a field will shift a pK value '''down'''. This means the pH value at which the side chain will be 50% ionized is lower, or in other words, in a positive electrostatic field the concentration of protons must be higher to keep a proton associated to the sidechain.<br> | + | (#: Number of ...) A protein's isoelectric point depends on the pK values of the amino acids; the pK values characterize the propensity fo an amino acid sidechain to dissociate, which in turn depends on how energetically favourable dissociation is. For example: since a negatively charged amino acid will be stabilized in a positive electrostatic field, such a field will shift a pK value '''down'''. This means the pH value at which the side chain will be 50% ionized is lower, or in other words, in a positive electrostatic field the concentration of protons must be higher to keep a proton associated to the sidechain.<br> |
<br> | <br> | ||
Compositional properties of nucleic acids include hybridization temperature and helix structure. | Compositional properties of nucleic acids include hybridization temperature and helix structure. | ||
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======Slide 030====== | ======Slide 030====== | ||
[[Image:L03_s030.jpg|frame|none|Lecture 03, Slide 030<br> | [[Image:L03_s030.jpg|frame|none|Lecture 03, Slide 030<br> | ||
− | Here is an example of regular expression searching: the leucine zipper, a protein dimerization element found frequently in transcription factors is defined by PROSITE as | + | Here is an example of regular expression searching: the leucine zipper, a protein dimerization element found frequently in transcription factors is defined by PROSITE as <tt>'''L-x(6)-L-x(6)-L-x(6)-L'''</tt>. |
]] | ]] | ||
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======Slide 031====== | ======Slide 031====== | ||
[[Image:L03_s031.jpg|frame|none|Lecture 03, Slide 031<br> | [[Image:L03_s031.jpg|frame|none|Lecture 03, Slide 031<br> | ||
− | A crude Perl program to find the Leucine Zipper pattern uses a regular expression at its core. | + | A crude Perl program to find the Leucine Zipper pattern uses a regular expression at its core. <tt>'''L.{6}){3,}L'''</tt> means: a string matching an "L", followed by 6 occurrences of any character ("."), repeated three or more times, and terminated by a final "L". (The arcane-looking <tt>print</tt> statement is just there to capture the sequence number of the pattern.) |
]] | ]] | ||
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======Slide 032====== | ======Slide 032====== | ||
[[Image:L03_s032.jpg|frame|none|Lecture 03, Slide 032<br> | [[Image:L03_s032.jpg|frame|none|Lecture 03, Slide 032<br> |
Latest revision as of 16:21, 17 November 2007
(Previous lecture) ... (Next lecture)
Sequence Properties
- What you should take home from this part of the course
- Understand the ideas of analysis by composition and analysis by signal;
- Know what deterministic pattern matching is;
- Recognize and understand the term regular expression;
- Be familiar with common sequence signals in DNA,RNA and proteins;
- Be familiar with the Prosite database and the Prosite scan server;
- Kow where to find EMBOSS tools and how to use them;
- Know about the offerings on the ExPASy tools collection page;
- Work on an understanding how biological facts can be translated into hypotheses and how hypotheses can be translated into computational procedures for analysis.
- Links summary
- Exercises
- Retrieve and read the Prosite documentation entry for the Leucine Zipper.
- Download entry 1NWQ from the PDB, visualize the Leucine Zipper with VMD and study its architecture (stereo vision!).
Lecture Slides
Slide 001
Slide 002
Slide 003
Slide 004
Slide 005
Slide 006
Slide 007
Slide 008
Slide 009
Slide 010
Slide 011
Slide 012
Slide 013
Slide 014
Slide 015
Slide 016
Slide 017
Slide 018
Slide 019
Slide 020
Slide 021
Slide 022
Slide 023
Slide 024
Slide 025
Slide 026
Slide 027
Slide 028
Slide 029
Slide 030
Slide 031
Slide 032
Slide 033
Slide 034
Slide 035
Slide 036
Slide 037
Slide 038
Slide 039
Slide 040
Slide 041
Slide 042
Slide 043
Slide 044
Slide 045
Slide 046