BIOL200 2013: Difference between revisions

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#Holt. J. G. Editor-in-Chief (1984). Bergey’s Manual of Systematic Bacteriology, Volume 1-4. Williams & Wilkins: Baltimore. http://www.cme.msu.edu/bergeys/pubinfo.html
#Holt. J. G. Editor-in-Chief (1984). Bergey’s Manual of Systematic Bacteriology, Volume 1-4. Williams & Wilkins: Baltimore. http://www.cme.msu.edu/bergeys/pubinfo.html
|}
|}
===March 12===
*Chapter 3. Molecular Evolution [[Media:CH3.pdf|Lecture Slides Ch.3-Che]]
* '''Homework:''' (TBA)
===March 19===
*REVIEW Session for MID-TERM EXAMS
<!--*Assignment #7. '''(To be posted)'''
Questions & Problems (pg.54-55): 2.1, 2.2, 2.3, 2.4-->
===March 26===
*MID-TERM
<!--*Assignment #8. '''(To be posted)'''
Questions & Problems (pg.75-76): 3.1, 3.2, 3.3 (use first ten codons), 3.4, 3.5, 3.7-->
===April 2===
*'''Chapter 4.''' Phylogenetics I. Distance Methods  [[Media:CH4.pdf|Lecture Slides Ch.4-Che]]
*"Tree Thinking" Puzzles - ([http://diverge.hunter.cuny.edu/~weigang/lab-website/SummerWorkshop/Baum_etal05_sup_part1.pdf Download])
*'''Tutorial:''' PROTDIST and NEIGHBOR using [http://mobyle.pasteur.fr/cgi-bin/portal.py#welcome Mobyle Pasteur]
{| class="collapsible collapsed wikitable"
|- style="background-color:lightsteelblue;"
! Assignment #6
|-style="background-color:powderblue;"
| '''Chapter 4 ''' Questions & Problems (pg.95-96): 4.1, 4.3, 4.4, 4.7, 4.8
|}
===April 9===
*'''Chapter 5.''' Phylogenetics II. Character-Based Methods  [[Media:CH4.pdf|Lecture Slides Ch.5-Che]]
*'''Tutorial:''' DNAML and bootstrap analysis using [http://mobyle.pasteur.fr/cgi-bin/portal.py#welcome Mobyle Pasteur]
<!--*Assignment #10. '''(To be posted)'''
Questions & Problems (pg.115-116): 5.1, 5.2, 5.3, 5.4-->
===April 16===
*'''Topic:''' Relational Database and SQL
*'''Tutorial:''' the Borrelia Genome Database
*'''Homework:''' SQL-embedded PERL
{| class="collapsible collapsed wikitable"
|- style="background-color:lightsteelblue;"
! Assignment #7
|- style="background-color:powderblue;"
| '''SQL-embedded PERL'''<br />
Continue work on the assignment we began in class. It is reproduced below, with some added functionality.
Your script will:
# Retrieve TEN orfs from the orf table that belong to the strain Pko.
# Find and store the sequences described by those orfs and their lengths.
# Determine if the orf is on the reference or reverse complement strand, and use that information to print the correct sequence.
# Print the orf name, sequence, and the length for each orf.
# '''In addition to printing the above information to the screen,''' write out the sequence information '''(in FASTA format)''' to a file
called "Pko_orfs.fasta". The sequence ID should be of the form:
Pko_orfname
Note that the above will require the use of BioPerl.
For those looking for extra challenges, you can try adding the following:
* Ask the user for the strain and contig *names* that they want orfs from, and only retrieve those rows. This means you must find a way
of obtaining their respective IDs from just their names. Make sure the sequence IDs are informative. They should look like this:
strainname_contigname_orfname
* If asking users for input, fail if they gave a strain or contig name which does not exist in the database.
* Also if asking users for input, the output file's name should be changed to reflect the chosen strain.
* Ask the user the minimum length the orf is allowed to be, and only print orfs as long, or longer, than what the user specifies.
Sample scripts will go up slowly, over time, including example SQL statements.
|-style="background-color:powderblue;"
| '''Questions from Text''' <br /> (pg.115-116): 5.1, 5.3
|}
===April 23===
'''NO CLASSES''' (Spring recess)
===April 30===
*'''Topic:''' Statistics
*'''In-class exercise:''' [https://docs.google.com/document/d/1wq-s8WpqyURVeGiLUxhEyBvHRDrK__Cr7XjkuLicP-c/edit?hl=en&authkey=CJ2g4qsI R basics and short demonstration of a simple boxplot]
*'''Tutorial:''' Statistical Visualization using R  [[Media:R-implementations.pdf|Lecture Slides-Che]]
<!--*Assignment #12. '''(To be posted)'''
R Exercises-->
===May 7===
*'''Chapter 6''' (Gene Expression) & '''Chapter 8''' (Proteomics)
*'''Tutorial:''' Array Data Visualization and Analysis ([[Media:Array_Data_Visualization_and_Analysis.pdf| Micro-Array Analysis Slides]])
*'''Homework:'''Data Analysis using R
{| class="collapsible collapsed wikitable"
|- style="background-color:lightsteelblue;"
! Assignment #8
|-style="background-color:powderblue;"
| '''Part 1 Data Analysis:'''
For this assignment, you will use sample data to answer the question: '''Do men and women have different body temperatures?'''
The file '''temps.txt''' located in ../bio425_2011/data on eniac, contains body temperature data for a sample of adults.
Use a hypotheses test with α = .05 to answer the above question of interest.
NOTE: For this part of the assignment you will need to turn in your answer to the question with p-values in addition to the R syntax used. '''Indicate your null hypothesis'''.
'''Part 2 Gene Expression Data Analysis:'''
Using the files '''GSM129276_cy3.txt''' & '''GSM129276_cy5.txt''' located in ./bio425_2011/data on eniac, conduct an analysis to produce a histogram of fold changes.
In addition to the histogram, you will need to turn in the R syntax used in every step of the analysis in R, along with an explanation as to why the step was necessary.
|-style="background-color:powderblue;"
| '''Read'''
'''For next class, read CH 7'''
|}
===May 14===
*'''Chapter 7.''' Protein Structure Prediction
<!--*Assignment #14 (Final Comprehensive Project). '''(To be posted)'''-->
===May 21===
*Final Project Due (TBA)
==Useful Links==
===Unix Tutorials===
*A very nice [http://www.ee.surrey.ac.uk/Teaching/Unix/ UNIX tutorial] (you will only need up to, and including, tutorial 4).
*FOSSWire's [http://files.fosswire.com/2007/08/fwunixref.pdf Unix/Linux command reference] (PDF). Of use to you: "File commands", "SSH", "Searching" and "Shortcuts".
===Perl Help===
* Professor Stewart Weiss has taught CSCI132, a UNIX and Perl class. His slides go into much greater detail and are an invaluable resource. They can be found on his course page [http://compsci.hunter.cuny.edu/~sweiss/course_materials/csci132/csci132_f10.php here].
* Perl documentation at [http://perldoc.perl.org perldoc.perl.org]. Besides that, running the perldoc command before either a function (with the -f option ie, perldoc -f substr) or a perl module (ie, perldoc Bio::Seq) can get you similar results without having to leave the terminal.
===Bioperl===
* BioPerl's [http://www.bioperl.org/wiki/HOWTOs HOWTOs page].
* BioPerl-live [http://doc.bioperl.org/bioperl-live developer documentation]. (We use bioperl-live in class.)
* Yozen's tutorial on [http://diverge.hunter.cuny.edu/wiki/HOWTO:Bioperl-live_on_Mac_OS_X installing bioperl-live on your own Mac OS X machine]. (Let me know if there are any issues!).
* [https://spreadsheets.google.com/pub?key=0AjfPzjrqY7BndHpyRHlDZUlGcktINm1IbXVzX1QzMXc&single=true&gid=0&output=html A small table] showing some methods for BioPerl modules with usage and return values.
===SQL===
* [https://docs.google.com/document/d/1zYLPeenwsqPYchkpXnndzphBbTKqX2GjjLHDxlBnt78/edit?hl=en&authkey=CLnh_88K SQL Primer], written by Yozen.
===R Project===
* Install location and instructions for [http://lib.stat.cmu.edu/R/CRAN/bin/windows/base/ Windows]
* Install location and instructions for [http://lib.stat.cmu.edu/R/CRAN/ Mac OS X]
* For users of Ubuntu/Debian:
sudo apt-get install r-base-core
* For users of Fedora/Red Hat:
su -
yum install R
===Utilities===
*An [https://chrome.google.com/webstore/detail/nlbjncdgjeocebhnmkbbbdekmmmcbfjd RSS button extension] for chrome. Can add feeds to Google Reader and others.
*A [https://chrome.google.com/webstore/detail/hcamnijgggppihioleoenjmlnakejdph similar extension] which adds a "Live bookmarks"-like feature to Chrome (like Firefox's RSS bookmarks).
===Other Resources===
* [http://www.ccrnp.ncifcrf.gov/~toms/papers/primer/primer.pdf Information Theory Primer] by Thomas D. Schneider. Useful in understanding sequence logo maps.


© Weigang Qiu, Hunter College, Last Update Jan 2013
© Weigang Qiu, Hunter College, Last Update Jan 2013

Revision as of 19:01, 4 March 2013

EXPERIMENT # 4

BIOL 200 Cell Biology II LAB, Spring 2013

Hunter College of the City University of New York

Course information

Instructors: TBD

Class Hours: Room TBD HN; TBD

Office Hours: Room 830 HN; Thursdays 2-4pm or by appointment

Contact information:

  • Dr. Weigang Qiu: weigang@genectr.hunter.cuny.edu, 1-212-772-5296


Experiment #4

The Tree of Life and Molecular Identification of Microorganisms

Objective

To classify microorganisms and determine their relatedness using molecular sequences.

LAB REPORT GRADING GUIDE

CELL BIO II Experiment #4:

  • Introduction 1 point :
 Statement of objectives or aims of the experiment in the student’s own words.
 (not to be copied from the Lab Manual)
  • MATERIALS AND METHODS 0 points :
 This should be a brief synopsis and must include any changes or deviations 
 from the procedures outlined in the Lab Manual. Specify which organisms were 
 used to create the phylogram.
  • RESULTS 4 points :
 A print out of the phylogram will suffice.
  • DISCUSSION 4 points :
 Responses to discussion questions.
  • SUMMARY |CONCLUSION 1 point :
 Two sentence summary of your findings.
  • REFERENCES 1 point :
 Credit is given for pertinent references obtained from sources other than the Lab Manual.
 This point is in addition to the 10 for the lab report..

INTRODUCTION

MATERIALS

  • Required hardware: Computer

Table 1

Volume 1A (Gram-negative bacteria)

Escherichia coli

ACCESSION #174375

Helicobacter pylori

ACCESSION #402670

Salmonella typhi

ACCESSION #2826789

Serratia marcescens

ACCESSION #4582213

Treponema pallidum

ACCESSION #176249

Additional species: Agrobacterium tumefaciens, Boredetella pertussis, Thermus aquaticus, Yersinia pestis, Borrelia burgdorferi. (Note: To search for unlisted 16S sequences, type key words such as “yersinia AND 16S [gene]” in the NCBI GenBank search box.)

Volume 1B (Rikettsias and endosymbionts)

Baronella bacilliformis

ACCESSION #173825

Chlamydia trachomatis

ACCESSION #2576240

Rickettsia rickettsii

ACCESSION #538436

Additional species: Coxiella burnetii, Thermoplasma acidophilum

Volume 2A (Gram-positive bacteria)

Bacillus subtilis

ACCESSION #8980302

Dinococcus radiodurans

ACCESSION #145033

Staphylococcus aureus

ACCESSION #576603

Additional species: Bacillus anthracis, Clostridium botulinum, Lactobacillus acidophilus, Streptococcus pyogenes

Volume 2B (Mycobacteria and nocardia)

Mycobacterium haemophilum

ACCESSION #406086

Mycobacterium tuberculosis

ACCESSION #3929878

Additional species: Mycobacterium bovis, Nocardia orientalis

Volume 3A (Phototrophs, chemolithotrophs, sheathed bacteria, gliding bacteria)

Anabaena sp.

ACCESSION #39010

Cytophaga latercula

ACCESSION #37222646

Nitrobacter wiogradskyi

ACCESSION #402722

Additional species: Heliothrix oregonensis, Myxococcus fulvus, Thiobacillus ferrooxidans

Volume 3B (Archeobaceria)

''Methanococcus jannaschii

ACCESSION #175446

Thermotoga subterranean

ACCESSION #915213

Additional species: Desulfurococcus mucosus, Halobacterium salinarium, Pyrococcus woesei

Volume 4 (Actinomycetes)

Actinomyces bowdenii

ACCESSION #6456800

Actinomyces neuii

ACCESSION #433527

Actinomyces turicensis

ACCESSION #642970

Eukaryotic representative (used as outgroup for rooting the phylogenetic tree)

Saccharomyces cerevisiae

ACCESSION #172403

ANALYSIS

DISCUSSION

References

© Weigang Qiu, Hunter College, Last Update Jan 2013