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Revision as of 20:06, 29 May 2013 (view source) Keltziee (Talk | contribs) (→4/8/13) ← Older edit		Revision as of 20:10, 29 May 2013 (view source) Keltziee (Talk | contribs) (→3/15/13) Newer edit →
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	==March==		==March==
	===3/15/13===		===3/15/13===
		+	3/15/13 - Friday - Bryan Merrill (BDM)
		+	Spreadsheet
		+	for plasmids, primers, and bacterial strains (and phage)
		+	Notes
		+	on what we found:
		+	Largest:
		+	Phage G, lytic, capsid, BSL1, generation time = 40 mins.
		+	Smallest:
		+	RH1 infects Rhodococcus, capsid size of 43 nm, 50kb?
		+	Smallest
		+	for E. coli: Spreadsheet (Jade) MS2, capsid protein size 137 aa, 27 nm.
		+	Well
		+	charaterized, Qbeta as well
		+
		+	Dissertation
		+	on capsid design – do longer protein sequences correspond to bigger
		+	capsids?  Are bigger capsids built from
		+	bigger monomers or more monomers?
		+	T7 – list of all genes, Gp10a and Gp10b (major and minor capsid proteins)
		+	Read the thesis/dissertation –
		+	3 Groups:
		+	Large phage
		+	Small phage
		+	How to build the capsids (heat shock or self-assembly)
		+
		+	Find phage which are well-characterized
		+
		+	Find:
		+	How
		+	phage are used for drug delivery (applications)
		+	Find out how capsid sizes change and mutate (targeted mutagenesis)
		+	Start by selecting, move towards targeted mutagenesis
		+	What are the applications for phage already
		+
		+	Cloning, sequence, and expression of the temperature-dependent phage T4 capsid assembly gene 31
		+	Modulation of bacteriophage T4 capsid size.
		+
		+
		+
		+	Goal:
		+	Build a library of multiple sizes of phage capsids and
		+	provide tools to assemble these phage capsids so they can be used for drug
		+	delivery and nanotechnology
		+
		+
		+	Look
		+	into:
		+	Metabolic
		+	load on bacteria based on capsid size?
		+
		+	Screening
		+	methods:
		+	Increasingly
		+	harsh environments, less nutrients, smaller phage?
		+	Using
		+	ozone for selection
		+
		+	3/15/13-Keltzie Smith
		+	Today we narrowed in on the phage we are going to use as a starting point for expansion. We found that it wasn’t as easy as we thought to simply look up what would be best for us since there are bits information here and there, but not all in the same location- I suppose this is why we are doing the research that we are- filling a gap! In deciding which to use we took into account genome size as well as how characterized it is. We decided that T4 is the simplest and most effective route to take even though it is technically not the largest phage that infects E. coli.
		+
		+	Large phage procedures:
		+
		+	Paper about UV light and backup genes?
		+
		+	Decreasing agar concentration – select for
		+	small plaque sizes
		+
		+	Find T4 phage and host
		+
		+	Start growing them (archive sample of the
		+	phage)
		+
		+	Determine sequence of the relevant capsid
		+	proteins
		+
		+	Mutate them
		+
		+	Determine the sequence again
		+
		+	Find a way to create just capsids of the larger
		+	size
	===3/18/13===		===3/18/13===

---

Revision as of 20:10, 29 May 2013

• Home
• Team
  • Overview
  • Official Team Profile
  • Team Video
  • Undergraduates
  • Mentors
• Project
  • Overview
  • Background
  • Experimental Design
• Notebook
  • Overview
  • Phage Team
  • Cholera Team
• Results
  • Overview
  • Judging Criteria
  • Experimental
  • Modeling
  • Parts Submitted to the Registry
  • A Taste of Toronto
• Human Practices
  • Overview
  • Orem Public Library Visit
  • The Adventure of Baxter Bacteria
• Safety
• Attributions & Collaborations
  • Attributions & Acknowledgements
  • Collaborations
• iGEM 2013

Contents 1 March 1.1 3/15/13 1.2 3/18/13 1.3 3/20/13 1.4 3/22/13 1.5 3/25/13 1.6 3/27/13 1.7 3/29/13 2 April 2.1 4/1/13 2.2 4/4/13 2.3 4/5/13 2.4 4/8/13 2.5 4/10/13 2.6 4/12/13 2.7 4/15/13 3 May 3.1 5/1/13 3.2 5/3/13 3.3 5/6/13 3.4 5/8/13 3.5 5/10/13 3.6 5/13/13 3.7 5/15/13 3.8 5/17/13 3.9 5/20/13 3.10 5/22/13 3.11 5/24/13 3.12 5/27/13 3.13 5/29/13 3.14 5/31/13 4 June 4.1 6/3/13 4.2 6/5/13 4.3 6/7/13 4.4 6/10/13 4.5 6/12/13 4.6 6/14/13 4.7 6/17/13 4.8 6/19/13 4.9 6/21/13 4.10 6/24/13 4.11 6/26/13 4.12 6/28/13 5 July 5.1 7/1/13 5.2 7/3/13 5.3 7/5/13 5.4 7/8/13 5.5 7/10/13 5.6 7/12/13 5.7 7/15/13 5.8 7/17/13 5.9 7/19/13 5.10 7/22/13 5.11 7/24/13 5.12 7/26/13 5.13 7/29/13 5.14 7/31/13 6 August 6.1 8/2/13 6.2 8/5/13 6.3 8/7/13 6.4 8/9/13 6.5 8/12/13 6.6 8/14/13 6.7 8/16/13 6.8 8/19/13 6.9 8/21/13 6.10 8/23/13 6.11 8/26/13 6.12 8/28/13 6.13 8/30/13 7 September 7.1 9/2/13 7.2 9/4/13 7.3 9/6/13 7.4 9/9/13 7.5 9/11/13 7.6 9/13/13 7.7 9/16/13 7.8 9/18/13 7.9 9/20/13 7.10 9/23/13 7.11 9/25/13 7.12 9/27/13 7.13 9/30/13

March

3/15/13

3/15/13 - Friday - Bryan Merrill (BDM) Spreadsheet for plasmids, primers, and bacterial strains (and phage) Notes on what we found: Largest: Phage G, lytic, capsid, BSL1, generation time = 40 mins. Smallest: RH1 infects Rhodococcus, capsid size of 43 nm, 50kb? Smallest for E. coli: Spreadsheet (Jade) MS2, capsid protein size 137 aa, 27 nm. Well charaterized, Qbeta as well

Dissertation on capsid design – do longer protein sequences correspond to bigger capsids? Are bigger capsids built from bigger monomers or more monomers? T7 – list of all genes, Gp10a and Gp10b (major and minor capsid proteins) Read the thesis/dissertation – 3 Groups: Large phage Small phage How to build the capsids (heat shock or self-assembly)

Find phage which are well-characterized

Find: How phage are used for drug delivery (applications) Find out how capsid sizes change and mutate (targeted mutagenesis) Start by selecting, move towards targeted mutagenesis What are the applications for phage already

Cloning, sequence, and expression of the temperature-dependent phage T4 capsid assembly gene 31 Modulation of bacteriophage T4 capsid size.

Goal: Build a library of multiple sizes of phage capsids and provide tools to assemble these phage capsids so they can be used for drug delivery and nanotechnology

Look into: Metabolic load on bacteria based on capsid size?

Screening methods: Increasingly harsh environments, less nutrients, smaller phage? Using ozone for selection

3/15/13-Keltzie Smith Today we narrowed in on the phage we are going to use as a starting point for expansion. We found that it wasn’t as easy as we thought to simply look up what would be best for us since there are bits information here and there, but not all in the same location- I suppose this is why we are doing the research that we are- filling a gap! In deciding which to use we took into account genome size as well as how characterized it is. We decided that T4 is the simplest and most effective route to take even though it is technically not the largest phage that infects E. coli.

Large phage procedures:

Paper about UV light and backup genes?

Decreasing agar concentration – select for small plaque sizes

Find T4 phage and host

Start growing them (archive sample of the phage)

Determine sequence of the relevant capsid proteins

Mutate them

Determine the sequence again

Find a way to create just capsids of the larger size

3/18/13

3/20/13

3/22/13

3/25/13

3/27/13

3/29/13

April

4/1/13

4/4/13

4/5/13

4/8/13

4/10/13

4/12/13

4/15/13

May

5/1/13

5/3/13

5/6/13

5/8/13

5/10/13

5/13/13

5/15/13

5/17/13

5/20/13

Today we need to run a dilution series to test the titer of our mutated phage stock. We also need to start selecting for small plaques and learning how to pick them and titer them out. We also should run a UV test on the mutated phage stock compared to the normal stock.

We picked one plaque off of the 180 sec UV plate sample. We suspended it in 1 mL of broth, and then UV-ed 20 uL samples at 45 second intervals. The number of plaques decreased the longer the samples sat under UV light. The samples were irradiated from 0 sec to 4 min 30 sec.

As a control, we diluted the T4Do stock to 10^-6 and tested 20 uL at 45 sec intervals (up to 6 min) under UV light.

Also, we diluted the T4 mutagenized stock to 10^-6 and tested 20 uL at 45 sec intervals (up to 4 min 30 sec) under UV light.

UV tests were done by placing 20 uL spots on parafilm and placed in a BSL-2 hood with the UV light turned on.

5/22/13

Results from 5/20/13 - We left the plates in the incubator for 48 hours, which caused contamination on many plates to grow.

When checked at 24 hours, the T4 mutagenized stock had a web plate at 10^-3 and less than 5 plaques at 10^-6. This experiment will need to be redone from 10^0 down through 10^-6. The whole mutagenesis may need to be redone if this only represents a dilution of our titer when we were trying to grow it in liquid culture. (We infected with ___ mL of phage at ___ titer in ____ vol of resuspended bacteria.)

Under UV light, the T4Do stock (diluted to 10^-6) has 19 plaques after being irradiated for six minutes (down from almost cleared at 0 min). Under UV light, the 180 sec UV plate spot (diluted in 1 mL) has a few hundred plaques on it, but the amount dropped significantly at 4 min 30 sec from when it was UV-ed for 0 min.

We will re-titer the T4-Mut stock so we can learn whether it was diluted or whether an infection worked. We will also re-run the UV test comparing the T4-Mut (10^-3) with the T4-Do stock (at 10^-6) for survivability. The mutagenized phage should survive better.

Since the loss of plaques seemed to level off for the T4Do stock at 5:15 (23 plaques) and 6 min (19 plaques), we will test a 7 min and 8 min timepoint to see if it stays level, suggesting these phage have multiple genomes and are severely mutated.

5/24/13

5/27/13

5/29/13

5/31/13

June

6/3/13

6/5/13

6/7/13

6/10/13

6/12/13

6/14/13

6/17/13

6/19/13

6/21/13

6/24/13

6/26/13

6/28/13

July

7/1/13

7/3/13

7/5/13

7/8/13

7/10/13

7/12/13

7/15/13

7/17/13

7/19/13

7/22/13

7/24/13

7/26/13

7/29/13

7/31/13

August

8/2/13

8/5/13

8/7/13

8/9/13

8/12/13

8/14/13

8/16/13

8/19/13

8/21/13

8/23/13

8/26/13

8/28/13

8/30/13

September

9/2/13

9/4/13

9/6/13

9/9/13

9/11/13

9/13/13

9/16/13

9/18/13

9/20/13

9/23/13

9/25/13

9/27/13

9/30/13