Difference between revisions of "Team:TU Delft/Notebook"

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 +
<h2>15/06/2015</h2>
 +
<p class="lead">We started preparing the materials for the lab. All the devices are set up, and the disposables ready to sterilize. At the end of the day, both plastic ware and liquids were autoclaved (121ºC, 15-30 min). Here the materials prepared are summarized: </p>
 +
<p class="lead" style="margin-bottom:5px;">LB medium, 6 bottles of 200 ml*</p>
 +
<p class="lead" style="margin-bottom:5px;">LB-agar mixture, 6 bottles of 400 ml*</p>
 +
<p class="lead" style="margin-bottom:5px;">CaCl2 100mM, 1 bottle of 200 ml*</p>
 +
<p class="lead" style="margin-bottom:5px;">Ethanol 70%, 1 bottle of 400 ml*</p>
 +
<p class="lead">CaCl2 100mM + 40% Glycerol, 1 bottle of 200 ml*</p>
 +
<p class="lead">*All the materials were prepared using standard methods</p>
 +
<h2>16/06/2015</h2>
 +
<p class="lead">The first stock of competent cells was made, so the first cloning experiments were conducted. could. The Top10 strain was chosen due to its availability and reliability in the results. 100 tubes of working solution containing 50 µL of Top10 competent cells (1) were made, and stored at -80ºC afterwards. </p>
 +
<p class="lead">(1) Protocol for Top10 competent cells</p>
 +
<h2>19/06/2015</h2>
 +
<p class="lead">The cloning experiments started today. The experiments for InterLab study were performed initially (see Interlab labjournal).  First, LB-Agar plates were made so they were solid and available for growing the cells later:</p><img class="featurette-image img-responsive center-block" src="https://static.igem.org/mediawiki/2015/8/86/TU_Delft_DSDSFASFAS.png" style="width:100%; background-size: cover;" alt="Generic placeholder image">
 +
<p class="lead">*The antibiotics were taken from a stock solution containing:</p>
 +
<p class="lead" style="margin-bottom:5px;">1:1000 ampicillin</p>
 +
<p class="lead" style="margin-bottom:5px;">1:1000 chloramphenicol</p>
 +
<p class="lead">1:1000 kanamycin</p>
 +
 +
<h2>23/06/2015</h2>
 +
<p class="lead">The following cell cultures were made in 9 mL LB  ∆csgA strain, K1316015 and I13504 in and grown overnight at 30°C. I13522 (TETP-GFP) has been taken from the iGEM distribution kit (2015, plate 3, location I6). </p>
 +
<p class="lead">Primers were dissolved in sterile Milli-Q water according to the amount specified in the shipping information (3) and shaken at 400 rpm for 20 minutes at room temperature to procedure stock solution for iGEM15 1 and iGEM15 2.</p>
 +
<p class="lead">(3): Shipping information for primers.</p>
 +
<h2>24/06/2015</h2>
 +
<p class="lead">Plasmids were isolated for K1316015 using the Promega miniprep unit and the related protocol you can find online (4). Plasmids were stored at minus 20°C (30 µl);</p>
 +
<p class="lead">AM35α has been made competent (1) and grown overnight. In order to see whether the density was good enough, the OD was measured. </p>
 +
<p class="lead">To check the PCR reaction, an agarose gel (6) was made. The PCR product should be at the level of 2.7 KB.</p>
 +
<p class="lead">The construct K1316015∆CsgB was isolated from the gel by using the Promega DNA purification protocol (7). </p>
 +
<p class="lead">Finally, the ligation was performed with K1316015∆Csg (0.3 µl, based on a concentration of 153.94 ng/µl).</p>
 +
<p class="lead">(4): Protocol related to Promega miniprep unit for plasmid isolation.</p>
 +
<p class="lead">(5): Protocol for doing a PCR reaction.</p>
 +
<p class="lead">(6): Protocol for running an agarose gel.</p>
 +
<p class="lead">(7): Protocol for Promega DNA purification.</p>
 +
<h2>25/06/2015</h2>
 +
<p class="lead">Transformation (2) of ligation product  K1316015∆CsgB (top10 cells, 46 ng). After transformation, the cells were plated on LB + CAM.</p>
 +
<p class="lead">Plated the transformation products K1316015∆CsgB on LB - Cam plates;</p>
 +
<p class="lead">Preparation of competent cells for ∆csgA AM35α. 1 mL of the overnight culture was inoculated in 100 mL of LB medium.</p>
 +
<p class="lead">Isolation of genomic csgC & csgEFG with primers
 +
Primers selected: iGEM15 15;16;17;18. The primers were dissolved in Milli-Q water (sterile) according to the amount specified in the delivery note (8) and shaken for 20 minutes at 400 rpm at room temperature.
 +
Produced primer stock solutions from which the working solutions were prepared (100 µM). By a 1:10 dilution to give a working solution of 10 µM or 10 pmol/µl. Working solutions were produced for a volume of 100 µL. </p>
 +
<p class="lead">The competent cells (AM35α) had an OD600 of 0.561 in a volume of 100 mL. Cells were harvested in 2 50mL tubes at 4°C for 5 minutes at 4000 rpm. 10 ml of ice cold 0.1 M CaCl2 was added to each tube to resuspend the cells and incubate them on ice for 20 minutes. They were centrifuged and resuspended in 5 mL ice cold CaCl2 each. Incubation for 1h on ice.
 +
The cells were pelleted and resuspended in 5 mL 50mM CaCl2 + 40% glycerol each. They were divided in portions of 50 µL and frozen in liquid N2.</p>
 +
<p class="lead">(8): Delivery note of primers.</p>
 +
<h2>29/06/2015</h2>
 +
<p class="lead">Isolation of E.coli U12 DH5α genomic DNA. Cells were grown overnight in 6mL LB and stored in the fridge over the weekend. The genomic DNA was isolated using Promega Wizard genomic DNA purification kit following the producer’s protocol (9). The DNA pellet was rehydrated at 4°C overnight. </p>
 +
<p class="lead">Cell cultures were created for the 100 µL plates from 25/06/2015 in 8mL LB+ 80µL 100x AMP (actually, 100 mg/mL). No growth was observed indicating problems with the transformation. </p>
 +
<p class="lead">(9): Promega Wizard genomic DNA purification kit.</p>
 +
<h2>30/06/2015</h2>
 +
<p class="lead">Measurements of dsDNA indicates failure of isolation of genomic DNA. The concentration is within the machine’s fluctuation 1-2 ng/µl with fluctuations of 1 ng/µl in measurement. </p>
 +
 
                   </div>
 
                   </div>
 
                 </div>
 
                 </div>

Revision as of 18:07, 18 September 2015

Notebook

Subtitle

Overview

Subtitle or summary goes here. Should be short - two or three sentences.

Lorem ipsum dolor sit amet, consectetur adipiscing elit. Praesent ultrices tincidunt ipsum, vitae tempor nibh porta ac. Fusce consectetur neque et dolor vestibulum iaculis. Nunc pretium turpis at arcu tempus vehicula. Nam nec accumsan metus, ac tempus tortor. Aenean euismod elit vitae ex ultrices pulvinar. Etiam rhoncus non urna vel volutpat. Donec ut erat ornare, faucibus quam a, posuere urna. Phasellus at nisl sed erat ultricies commodo vel ut mauris. Morbi ac mauris dui. Cras sit amet ornare nisl. Suspendisse lectus mi, ullamcorper et dolor a, vulputate condimentum velit. Morbi dolor eros, cursus euismod magna sit amet, tempus volutpat quam. Morbi at est sed erat efficitur lobortis nec non elit. Integer urna nisi, dapibus nec magna non, pharetra sodales felis. Fusce dignissim elit sit amet purus aliquet, quis luctus tortor commodo. Donec viverra enim vel ultrices iaculis.

Work Space

Our lab and office. Our new home for the summer.

About our lab

The iGEM lab, inside the Applied Sciences building of the TU Delft, has been the place where our science took place. It has the certification for ML-1 experiments, which was enough for our experiments. Here we learned and improved our skills in cloning and manipulating biological materials. We also tried to apply our ideas from paper to the real world. All in all, we discovered the world of synthetic biology from the inside.

Generic placeholder image

About our office

Our office has been our meeting point and our dry-lab zone during the project. Here, amazing talks about biology, engineering and philosophy took place. And here we debated about science and lab topics. To sum up, the office that you can see in the picture in the left has been our home this summer: the place where we built the project, but also where we built our team spirit.

Safety

Lab and Project Safety

Safety in our Lab

Our lab is classified as Level 1 of biosafety. This is the lowest safety level, meaning that our experiments involve low or no risk. The biological materials used for our experiments are handled in an open bench All the members of the team have received safety training, including:

Introduction to sterile working

RNA handling

Laser safety

Microscopy training

ML-1 safety test completion

Chemical safety training

General safety information, regarding contact persons and locations

Computer infrastructure

The safety of our experiments was supervised by Susanne Hage (Safety Manager of the TNW faculty) and Marinka Almering (Safety officer of the TU Delft). The research has been conducted with respect to the regulations of biosafety for The Netherlands, that can be found here

Safety in our Project

Our harmless bacteria produces curli subunits in order to make an inducible biofilm. The curli is natively produced by several safe strains, like the TOP10 used for transformations. Our strain contains a CsgA deletion and can only produce the curli when transformed with the designed plasmid and induced. This part of the project is based on sufficient scientific publications and previous iGEM information and parts. Also, one assay is designed to test the efficiency of the biofilm created carrying a specific affinity tag. For the assay teeth pieces were used, taking care of all the existing regulations and safety recommendations.

The chassis organism used for our project is a modified strain of the lab organism Escherichia coli K-12. It is called E. coli K-12 MG1655 PRO ΔcsgA ompR234.

In addition to our chassis organism, Escherichia coli Top 10 cells were used for cloning procedures

A pig tooth is used for testing our affinity application to hydroxyapatite. This will be arranged following the lab regulations, and the tooth will be provided following all the existing regulations. We will handle the part in the ML1 lab, and using gloves while working with the part. Furthermore, the teeth are cleaned properly before the use. The use of that samples is regulated by the Ministry of Economic affairs, Agriculture and Innovation of the Government of The Netherlands. The waste of all animal byproduct is designated as Specific Animal Waste (following Euralcode 180102). Later on, it is transported to the ZAVIN in Dordrecht for its destruction. For further information, you could contact the Residual Management Department of TU Delft (ReststoffenBeheer@tudelft.nl)

One of the problems to be faced with this project is the production of csgA as biofilm-maker unit. It has been reported previously as a virulence factor from harmful strains of E.coli, because the amyloid make the attachment to surfaces easier. However, we implemented two safety points for minimizing the risk of plasmid transmission to pathogen strains. First of all, the gene which codifies for csgA is preceded by a Rhamnose promoter. That prevents curli (csgA+csgB polymer) to be produces when no inductor is applied to the system. Furthermore, as rhamnose is a metabolizable inductor the gene expression could be avoided just by stopping the rhamnose supply. On the other hand, we aim our project for product testing or industrial production. So, the good laboratory practices and good manufacturing practices in these two fields should avoid any safety issue.

If our project could be fully developed into a real product, it would aim the following fields:

Factories

Lab applications

Consumer products

Test products to be used in the human body

Test products on food

We would like to encourage every interested iGEM team or researcher in general to contact us for further details about the safety in our lab and project!

Day Notes

Subtitle or summary goes here. Should be short - two or three sentences.

Curli

15/06/2015

We started preparing the materials for the lab. All the devices are set up, and the disposables ready to sterilize. At the end of the day, both plastic ware and liquids were autoclaved (121ºC, 15-30 min). Here the materials prepared are summarized:

LB medium, 6 bottles of 200 ml*

LB-agar mixture, 6 bottles of 400 ml*

CaCl2 100mM, 1 bottle of 200 ml*

Ethanol 70%, 1 bottle of 400 ml*

CaCl2 100mM + 40% Glycerol, 1 bottle of 200 ml*

*All the materials were prepared using standard methods

16/06/2015

The first stock of competent cells was made, so the first cloning experiments were conducted. could. The Top10 strain was chosen due to its availability and reliability in the results. 100 tubes of working solution containing 50 µL of Top10 competent cells (1) were made, and stored at -80ºC afterwards.

(1) Protocol for Top10 competent cells

19/06/2015

The cloning experiments started today. The experiments for InterLab study were performed initially (see Interlab labjournal). First, LB-Agar plates were made so they were solid and available for growing the cells later:

Generic placeholder image

*The antibiotics were taken from a stock solution containing:

1:1000 ampicillin

1:1000 chloramphenicol

1:1000 kanamycin

23/06/2015

The following cell cultures were made in 9 mL LB ∆csgA strain, K1316015 and I13504 in and grown overnight at 30°C. I13522 (TETP-GFP) has been taken from the iGEM distribution kit (2015, plate 3, location I6).

Primers were dissolved in sterile Milli-Q water according to the amount specified in the shipping information (3) and shaken at 400 rpm for 20 minutes at room temperature to procedure stock solution for iGEM15 1 and iGEM15 2.

(3): Shipping information for primers.

24/06/2015

Plasmids were isolated for K1316015 using the Promega miniprep unit and the related protocol you can find online (4). Plasmids were stored at minus 20°C (30 µl);

AM35α has been made competent (1) and grown overnight. In order to see whether the density was good enough, the OD was measured.

To check the PCR reaction, an agarose gel (6) was made. The PCR product should be at the level of 2.7 KB.

The construct K1316015∆CsgB was isolated from the gel by using the Promega DNA purification protocol (7).

Finally, the ligation was performed with K1316015∆Csg (0.3 µl, based on a concentration of 153.94 ng/µl).

(4): Protocol related to Promega miniprep unit for plasmid isolation.

(5): Protocol for doing a PCR reaction.

(6): Protocol for running an agarose gel.

(7): Protocol for Promega DNA purification.

25/06/2015

Transformation (2) of ligation product K1316015∆CsgB (top10 cells, 46 ng). After transformation, the cells were plated on LB + CAM.

Plated the transformation products K1316015∆CsgB on LB - Cam plates;

Preparation of competent cells for ∆csgA AM35α. 1 mL of the overnight culture was inoculated in 100 mL of LB medium.

Isolation of genomic csgC & csgEFG with primers Primers selected: iGEM15 15;16;17;18. The primers were dissolved in Milli-Q water (sterile) according to the amount specified in the delivery note (8) and shaken for 20 minutes at 400 rpm at room temperature. Produced primer stock solutions from which the working solutions were prepared (100 µM). By a 1:10 dilution to give a working solution of 10 µM or 10 pmol/µl. Working solutions were produced for a volume of 100 µL.

The competent cells (AM35α) had an OD600 of 0.561 in a volume of 100 mL. Cells were harvested in 2 50mL tubes at 4°C for 5 minutes at 4000 rpm. 10 ml of ice cold 0.1 M CaCl2 was added to each tube to resuspend the cells and incubate them on ice for 20 minutes. They were centrifuged and resuspended in 5 mL ice cold CaCl2 each. Incubation for 1h on ice. The cells were pelleted and resuspended in 5 mL 50mM CaCl2 + 40% glycerol each. They were divided in portions of 50 µL and frozen in liquid N2.

(8): Delivery note of primers.

29/06/2015

Isolation of E.coli U12 DH5α genomic DNA. Cells were grown overnight in 6mL LB and stored in the fridge over the weekend. The genomic DNA was isolated using Promega Wizard genomic DNA purification kit following the producer’s protocol (9). The DNA pellet was rehydrated at 4°C overnight.

Cell cultures were created for the 100 µL plates from 25/06/2015 in 8mL LB+ 80µL 100x AMP (actually, 100 mg/mL). No growth was observed indicating problems with the transformation.

(9): Promega Wizard genomic DNA purification kit.

30/06/2015

Measurements of dsDNA indicates failure of isolation of genomic DNA. The concentration is within the machine’s fluctuation 1-2 ng/µl with fluctuations of 1 ng/µl in measurement.

Back to Top

Protocols

During our lab work we used the following protocols. You can also download them here. Protocols

  1. Plate Top10 cells and incubate at 37ºC overnight

  2. Pick one colony, inoculate in LB media and incubate overnight while shaking at 37ºC

  3. Dilute the culture in fresh medium, and continue the incubation until the OD600= 0.4-0.6

  4. Centrifugation 5 min. at 4000 rpm.

  5. Pellet cells and resuspend in 100mM of CaCl2 solution

  6. Incubate on ice for 20 min

  7. Centrifugation 5 min at 3000 rpm

  8. Pellet cells and suspend again in 100mM CaCl2 solution

  9. Incubate on ice for 60 min

  10. Centrifugation 5 min at 3000 rpm

  11. Add a solution of 100mM CaCl2 + 40% glycerol

  12. Store immediately at -80ºC

  1. Grow single Escherichia coli colony in LB overnight, at 37ºC and 200 rpm

  2. Dilute the overnight culture 1:100 in fresh LB medium and grow at 37ºC and 200 rpm, until OD600 is between 0.4 and 0.6

  3. Place the culture on ice for 15 minutes

  4. Harvest the cells by centrifugation (5 minutes at 4000 rpm at 4ºC) and resuspend in ice cold Mili-Q water, to the volume of the original culture

  5. Repeat the last washing step with Mili-Q water 2 times

  6. Resuspend cells in equal volume as cell pellet ice cold 10% glycerol

  7. Make aliquots of 40 µL and store at -80ºC

  1. Take the competent cells from the storage at -80ºC and leave them on ice for 10-15 min

  2. Add 1-2 µL of plasmid solution to the 50 µL cell tube

  3. Incubate on ice for 30 min

  4. Heat-shock the cells at 42ºC for 45s

  5. Incubate on ice for 2 min

  6. Add 500 µL of LB media and incubate 60 min at 37ºC

  7. Plate the cultures on agar plate

  1. Use 40 µL electrocompetent cells for electroporation

  2. Add 1-10 ng of plasmid DNA or 1 µL of ligation product to the cells

  3. Transfer cells + DNA to 2mm electroporation cuvette

  4. Electroporate at 2500 V, with a pulse of 5-6 ms

  1. Pick a single colony from a plate or cryostock

  2. Put the colony in a 50 mL sterile tube and add 5-10 mL of LB fresh medium

  3. Put the tube to incubate for at least 16 h, at 37ºC and 200 rpm

Gel making

  1. Prepare 200 mL of TAE buffer

  2. Mix the TAE solution with 2g of agarose (for 1%)

  3. Heat the solution to boiling, and then cool it to 50ºC aprox.

  4. Add 5 µL of Ethidium bromide to the solution

  5. Pour the solution in the electrophoresis vessel. Apply the combs.

  6. Let it polymerize, and then cover it with TAE

Gel running

  1. Add 1/6 of total volume of Loading buffer to every DNA sample.

  2. Remove the combs from the gel, and pipette DNA samples and DNA ladder

  3. Run at 100-130V for 30-60 min (depends on the fragments)

  1. Add 20-100 ng of vector DNA (can be calculated from the DNA concentration in the sample)

  2. Add X ng of insert DNA. X is calculated using the length of both vector and insert and the molar ratio desired.

  3. Add 2µL of ligation buffer

  4. Add MQ water to set the final volume to 15-20

  5. Add 1 µL of T4 ligase (always at the end to keep the enzyme in optimal conditions)

  6. Incubate for at least 3 hours at 16ºC

  1. Take 1.5 mL from a freshly grown culture and put it in a 1.5 mL tube

  2. Spin the tube for 10 min at 2000 rpm

  3. Decant the supernatant without disturbing the pellet

  4. Add 0.5 mL of LB media and 0.5 mL of glycerol 80% solution

  5. Mix by vortexing

  6. Save in the -80ºC freezer

  1. Add 1 µg of DNA (can be calculated from concentration in the sample)

  2. Add 5 µL of NEB buffer

  3. Add 1 µL of restriction enzyme 1

  4. Add 1 µL of restriction enzyme 2

  5. Add MQ water to set the final volume at 50 µL

  6. Mix the solution by flicking the tube

  7. Spin-down in a microcentrifuge for 15 s

  8. Incubate at 37ºC for 1-2 hours

  1. Add 1.5 mL of bacterial culture in LB medium to a 1.5 mL micro-centrifuge tube. Centrifuge that tube at max speed for 3 min

  2. Remove the supernatant, and add 600 µL of MQ water to the pellet

  3. Add 100 µL of Cell Lysis Buffer, and mix by inverting 6 times. The color change to blue indicates complete lysis

  4. Add 350 µL of cold (4-8ºC) Neutralization Buffer, and mix by inverting the tube. The color change to yellow indicates total neutralization

  5. Centrifugate at maximum speed for 3 minutes, and transfer the supernatant to a PureYield Minicolumn

  6. Place the minicolumn into a PureYield Collection Tube and centrifuge at maximum speed for 15 seconds

  7. Discard the flowthrough and place the minicolumn again into the same PureYield Collection tube

  8. Add 200 µL of Endotoxin Removal Wash to the minicolumn. Centrifuge at maximum speed for 15 seconds. Do not empty the Collection Tube now

  9. Add 400 µL of Column Wash Solution to the minicolumn, and centrifuge at maximum speed for 30 seconds

  10. Transfer the minicolumn to a clean 1.5 mL tube, and 30 µL of hot (50ºC, pre-warmed) MQ water directly to the minicolumn matrix. Let stand for 5 minutes at room temperature

  11. Centrifuge at maximum speed in a microcentrifuge for 15 seconds to elute plasmidic DNA. Cap the tube, and store the DNA solution at -20 ºC (or use it directly for cloning experiments)

  1. Weigh a 1.5 mL microcentrifuge tube for each DNA fragment to be isolated, and record the weight

  2. Visualize the DNA in the agarose gel using a long-wavelength UV lamp and an intercalating dye (Ethidium bromide). Irradiate the gel the minimum possible time to reduce nicking

  3. Excise the DNA fragment of interest in a minimal volume of agarose using a clean scalpel or razor blade. Transfer the gel slice to a weighted 1.5 mL tube and record the weight, again. Subtract the previously measured tube weight to obtain the weight of the gel slice containing the DNA fragment

  4. Add Membrane Binding Solution at a ratio of 10 µL of solution per 10 mg of agarose gel slice

  5. Vortex the mixture and incubate at 50-65ºC for 10 minutes, or until the gel slice is completely dissolve in the liquid. You can vortex the tube every few minutes to increase the rate of agarose melting

  6. Centrifuge the tube briefly at room temperature to ensure the contents are at the bottom of the tube. Once the agarose gel is melted, the gel will not re-solidify at room temperature

  7. Place one SV Minicolumn in a Collection Tube for each dissolved gel slice

  8. Transfer the dissolved gel mixture to the SV minicolumn assembly and incubate for 1 minute at room temperature

  9. Centrifuge the SV Minicolumn assembly in a microcentrifuge at max speed for 1 minute. Remove the SV Minicolumn from the Spin Column assembly and discard the liquid in the Collection Tube. Return the SV Minicolumn to the Collection Tube afterwards

  10. Wash the column by adding 700 µL of Membrane Wash Solution, previously diluted with 95% ethanol to the SV Minicolumn. Centrifuge the SV Minicolumn assembly for 1 minute at maximum speed

  11. Empty the Collection Tube as before, and place the SV Minicolumn back in the Collection Tube. Repeat the wash with 500 µL of Membrane Wash Solution, and centrifuge the SV Minicolumn assembly for 5 minutes at maximum speed

  12. Remove the SV Minicolumn assembly from the centrifuge (not wetting the bottom of the column with the supernatant). Empty the Collection Tube and centrifuge the assembly for 1 minute with the microcentrifuge lid open (or off) to allow ethanol evaporation

  13. Carefully transfer the SV Minicolumn to a clean 1.5 mL tube. Apply 50 µL of Nuclease-Free Water (at 50ºC) directly to the center of the column, without touching the membrane with the pipette. Incubate at room temperature for 5 minutes

  14. Centrifuge for 1 minute at 14000 rpm. Discard the SV Minicolumn, and store the tube containing the eluted DNA at 4ºC or -20ºC

  1. Add an equal volume of Membrane Binding Solution to the restriction product tube

  2. Place one SV Minicolumn in a Collection Tube for each restriction product solution

  3. Transfer the mixture to the SV Minicolumn assembly and incubate for 1 minute at room temperature

  4. Centrifuge the SV Minicolumn assembly in a microcentrifuge at max speed for 1 minute. Remove the SV Minicolumn from the Spin Column assembly and discard the liquid in the Collection Tube. Return the SV Minicolumn to the Collection Tube afterwards

  5. Wash the column by adding 700 µL of Membrane Wash Solution, previously diluted with 95% ethanol to the SV Minicolumn. Centrifuge the SV Minicolumn assembly for 1 minute at maximum speed

  6. Empty the Collection Tube as before, and place the SV Minicolumn back in the Collection Tube. Repeat the wash with 500 µL of Membrane Wash Solution, and centrifuge the SV Minicolumn assembly for 5 minutes at maximum speed

  7. Remove the SV Minicolumn assembly from the centrifuge (not wetting the bottom of the column with the supernatant). Empty the Collection Tube and centrifuge the assembly for 1 minute with the microcentrifuge lid open (or off) to allow ethanol evaporation

  8. Carefully transfer the SV Minicolumn to a clean 1.5 mL tube. Apply 50 µL of Nuclease-Free Water (at 50ºC) directly to the center of the column, without touching the membrane with the pipette. Incubate at room temperature for 5 minutes

  9. Centrifuge for 1 minute at 14000 rpm. Discard the SV Minicolumn, and store the tube containing the eluted DNA at 4ºC or -20ºC

  1. Linearize 1 µg vector by restriction digest

  2. Remove the 5’ phosphates from the vector with alkaline phosphatase

  3. Purify the linearized vector using an agarose gel

  4. Resuspend the GBlocks gene fragments to a final concentration of 10 ng/µL of water or TE buffer. The amount of DNA in each tube can be checked in the delivery document

  5. Prepare ends of GBlocks fragments by restriction of 10 µL

  6. Heat inactivate the enzyme, or column purify the restriction product (depending on the restriction protocol) keeping the digested insert as concentrated as possible

  7. Ligate 50 ng of vector with a 3 times molar excess of GBlocks in fresh T4 DNA ligase buffer and 400 u of T4 DNA ligase, setting the final volume to 20 µL. Incubate the solution for 2 hours at 16º

  8. Transform the ligation protocol into competent cells using the Transformation protocol

  1. Make the MasterMix using the materials specified below

  2. Pick a colony and dip in this mixture and then in 50 µL LB, so the colonies that contain the correct insert can be grown

  3. Run the PCR using the program specified below

Materials

  1. Salt solution, containing 1.2 M NaCl and 0.06 M MgCl2

  2. Taq polymerase

  3. dATP solution

  4. 10x buffer, containing 100 mM Tris-HCl, pH 8.3 (at 42°C), 500 mM KCl, 25 mM MgCl2 and 0.01% gelatin

  5. DNA for transform into the cells

  6. Competent CaCl2 cells

  7. SOC medium, containing 2% Tryptone, 0.5% Yeast Extract, 10 mM NaCl, 2.5 mM KCl, 10 mM MgCl2, 10 mM MgSO4, 20 mM glucose

  8. LB-Agar petri dishes

Methodology

  1. Get adenine nucleotide at 3’, by adding

  2. 6 uL of DNA; 1 uL of Taq Polymerase; 1 uL of dATP; 1 uL of 10x buffer

  3. Use 3 uL of this solution and put them in a different tube.

  4. Add 1 uL of Salt Solution, 2 uL of miliQ water

  5. Incubate for 10 minutes at room temperature

  6. 2 uL are added into thawed competent cells, and the mixture is incubated for 15 minutes at room temperature

  7. Heat shock the cells at 42ºC for 30 seconds

  8. Place the tubes on ice, and add 250 uL of SOC medium to the mixture

  9. Grow the cells at 37ºC for 1 hour

  10. Plate the cultures on agar plate, using the necessary antibiotic

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  1. LB medium

  2. Lb+rhamnose medium, at different concentrations for induction

  3. Autoclaved, flat bottomed, transparent 96-well microtiter plates with lids

  4. Crystal violet solution at 0.1% (w/v) in water

  5. 95% (v/v) ethanol

  6. Platform shaker

  7. Plate reader

Methodology

Make an overnight culture of the bacteria of interest in LB+antibiotic at 37°C

Dilute each overnight culture by 1:100 into 200 μL of LB-rhamnose in wells of a cell culture treated, flat bottom, transparent 96-well microtiter plates with lids. Cover the plate

Incubate the plate for ~3 days, leaving enough time for the induction to occur

Remove the planktonic bacteria from each well by pipetting or shaking out the liquid

Wash the wells with water to remove the remaining planktonic cells. Submerge the plate in a tray of water and shake out the liquid. One can also add in water and remove the liquid with a multichannel pipet. Repeat this step twice

Add 210 μL of crystal violet solution into each well and stain for 10 min at RT

Discard the crystal violet solution, washing the wells three times in a tray or by pipetting (for removing non-specific interactions of the dye)

Invert the microtiter plate and vigorously tap the plate on a paper tower to remove the remaining water in the well. Air-dry the plate

Add 200 μL of 95% ethanol into each stained well. Cover the plate and incubate it on a platform shaker at RT for 15 min

Transfer the 100 μL of liquid onto a non-sterile, flat bottom, transparent 96-well microtiter plate. Measure the OD at 600 nm on a plate reader

Zhou, Y., Smith, D. R., Hufnagel, D. A., & Chapman, M. R. (2013). Experimental manipulation of the microbial functional amyloid called curli. In Bacterial cell surfaces (pp. 53-75). Humana Press.

  1. Wash buffer NPI-20

  2. Elution Buffer NPI-500

  3. Lysis buffer NPI-10

Methodology

Inoculate 10 mL of LB medium containing the appropriate antibiotics with a fresh bacterial colony harboring the expression plasmid. Grow at 37ºC overnight

Dilute the non-induced overnight culture 1:60 with fresh LB medium containing the appropriate antibiotics. Grow at 37ºC while shaking until the OD600 reaches 0.6

Add Rhamnose (induction) to the desired final concentration for induction, and grow at 37ºC for the appropriate induction time

Harvest the cells by centrifugation at 4000 g for 15 min

Transfer the supernatant to another tube and discard the pellet. Keep a part of the supernatant for SDS-PAGE analysis, if needed

Equilibrate the Ni-NTA spin column with 600 µL Buffer NPI-10. Centrifuge for 2 min at 2900 rpm (890 g)

Make the supernatant solution, by setting the final solution to contain 200mM NaCl, 1mM PMSF, and 20mM imidazole. The pH is adjusted to 7.8, using 1M K2HPO4 solution

Load up to 600 µL of the supernatant solution containing the 6xHis-tagged protein onto the pre-equilibrated Ni-NTA spin column. Centrifuge for 5 min at 1600 rpm (270 g) and collect the flow-through

Wash the Ni-NTA spin column twice with 600 µL Buffer NPI-20. Centrifuge for 2 min at 2900 rpm (890 g)

Elute the protein twice with 300 µL of Buffer NPI-500. Centrifuge for 2 min at 2900 rpm (890 g) and collect the eluate

  1. Wash buffer NPI-20

  2. Elution Buffer NPI-500

  3. Lysis buffer NPI-10

  4. Lysozyme stock solution 10 mg/mL in water

  5. Benzonase ® Endonuclease 25 U/µL

Methodology

Inoculate 10 mL of LB medium containing the appropriate antibiotics with a fresh bacterial colony harboring the expression plasmid. Grow at 37ºC overnight

Dilute the non-induced overnight culture 1:60 with fresh LB medium containing the appropriate antibiotics. Grow at 37ºC while shaking until the OD600 reaches 0.6

Add Rhamnose (induction) to the desired final concentration for induction, and grow at 37ºC for the appropriate induction time

Harvest the cells by centrifugation at 4000 g for 15 min

Discard the supernatant and keep the pellet. Then resuspend the pellet in 630 µL of Lysis buffer (NPI10). Add 70 µL of Lysozyme stock solution (10 mg/mL) and add 3 units/mL of Benzonase®

Incubate on ice for 15-30 min

Centrifuge the lysate at 12000 g for 15-30 min at 4ªC. Collect the supernatant

Equilibrate the Ni-NTA spin column with 600 µL Buffer NPI-10. Centrifuge for 2 min at 2900 rpm (890 g)

Load up to 600 µL of the cleared lysate solution containing the 6xHis-tagged protein onto the pre-equilibrated Ni-NTA spin column. Centrifuge for 5 min at 1600 rpm (270 g) and collect the flow-through

Wash the Ni-NTA spin column twice with 600 µL Buffer NPI-20. Centrifuge for 2 min at 2900 rpm (890 g)

Elute the protein twice with 300 µL of Buffer NPI-500. Centrifuge for 2 min at 2900 rpm (890 g) and collect the eluate

  1. LB agar plates

  2. LB liquid medium

  3. Congo Red (CR) stock: Dissolve 1 g of Congo Red in 100 mL of water and sterilize by filtering. Store at 4ºC

  4. Chloramphenicol stock solution (35 mg/mL)

  5. Rhamnose (0.1-1% w/v)

  6. IPTG (4mM)

Methodology

Streak out the cells from a -80ºC cryostock onto LB+agar plate. Pick grown colonies and grow them overnight in liquid LB + antibiotic

Transfer 1 mL of the overnight culture in 30 mL LB+antibiotic, and keep it growing while shaking

Once the OD600 of the culture is around 0.4, induce the cultures with the desired amount of inductor (Rhamnose or IPTG). Wait 2 days after the induction

Take 1 mL of every sample and measure the OD600, using LB+CAM as blank

Add Congo Red to a final concentration of 20 µg/mL, mix and incubate for 5 min at room temperature

Centrifuge at 14000 rpm for 5 minutes

Take the supernatant and measure it at 480 nm (or the peak in the spectrophotometric absorption curve), using LB+CAM+Congo Red as a reference

Zhou, Y., Smith, D. R., Hufnagel, D. A., & Chapman, M. R. (2013). Experimental manipulation of the microbial functional amyloid called curli. In Bacterial cell surfaces (pp. 53-75). Humana Press.

  1. Grow a ∆csgA - csgA and ∆csgA – csgA-I13521 strain at 37°C overnight in LB medium.

  2. Measure the OD600. As the OD600 will probably be high (>2.5), make a ~50x dilution and grow the liquid cultures at 37°C for ~2h.

  3. Measure the OD600 again. If the OD600 is between 0.4 and 0.6 (exponential phase), continue to step 4.

  4. Write down the OD600 that was obtained. Make a dilution to an OD600 of 0.05.

  5. Fill the wells with different amounts of rhamnose (from 50 g / L stock) and sterile water.

  6. Fill the wells with 180 ul LB + cells, or solely 180 ul LB.

  7. When all the wells are filled, measure the fluorescence and OD600 in a plate reader in time (at a temperature of 30°C).

Characterization of the surface of the samples

  1. A tooth sample is cleaned and disinfected by ethanol bath overnight

  2. The tooth is then carefully broken down into smaller parts

  3. Three of these pieces are then selected based on the size and shape, taking the three cubical pieces with more resemblance

  4. Keep the samples in ethanol, so they stay sterile before their use

Biofilm formation on the surface

  1. Cells csgA+Hydroxyapatite+RFP affinity tag positive after induction are taken from a cryostock/plate and cultured overnight in LB media. It is important to also grow two cultures that can be used as a control, making the total number of samples 3

  2. The cultures are then dropped in a sterile, empty 12-wells plate. After that, the dental samples are placed in the middle of one well

  3. Next to the dental sample, Rhamnose solution is added to the dish to a final concentration of 0.5%. After this step, the plate is left for induction for 20-40 hours

Hydroxyapatite-tag strength test

  1. The fluorescence of the samples is then measured Typhoon fluorescence reader, after two immersions in water

  2. The samples are then placed in a tube and rinsed with 1 ml of ethanol. The mixture is left 5 minutes so all the cells can detach from the tooth

  3. Then, the ethanol solutions are taken from the tube and placed in a 96-well plate, and the RFP intensity is measured using a fluorescence plate reader

Grow a ∆csgA - csgA and ∆csgA – csgA-His strain at 37°C overnight in LB medium.

Measure the OD600. Make a ~50x dilution and grow the liquid cultures at 37°C for 1.5h.

Measure the OD600 again. If the OD600 is between 0.35 and 0.6 (exponential phase) , the induction can be made.

Induce the cells with Rhamnose (from 50 g / L stock) and sterile water. You need to have a final concentration of 0.5 wt% Rhamnose. The induction has to be performed at 30°C.

After 5 hours of induction, measure the OD600 and disrupt the cells.

Run SDS-PAGE gel with protein marker and samples (use pre-stained protein marker)

Transfer protein from gel to membrane:

  1. Soak 2 x filter thick paper and the gel in transfer buffer.

  2. Soak 1 x PVDF membrane in 100% methanol, then water, then transfer buffer or use cellulose membranes soaked only in transfer buffer.

  3. Make sandwich: filter bottom paper, membrane, gel (upside down), filter top paper.

  4. Roll out bubbles with glass pipette.

  5. Attach top electrode plate.

  6. Transfer 40 min at 15V.

    7. Development blot with Supersignal West pico kit (Pierce):

    1. Block blot membrane in 5% milk or BSA in TBS-T, on orbital shaker 1 hour (RT) to overnight (cold room).

    2. Add anti-His-HRP antibody (dilution 1:5000) in blocking solution and incubate on orbital shaker for 1h at room temperature.

    3. Wash 4 x 10min with TBS-T on orbital shaker, RT.

      4. Detection (Supersignal West pico kit)

        Put blot membrane on Saran wrap

      1. Mix 1.5 ml detection reagent 1 and 1.5 ml detection reagent just before use

      2. Pipette 3 mL of mix detection reagent on blot (make sure there is even distribution on the membrane)

      3. Incubate 5 minutes at RT in dark

      4. detect chemiluminescence with CCD camera (Biorad Imager in Biobrick)

Materials

1 % w/v Sodium alginate

0.1M CaCl2

0.1M sodium citrate (monobasic)

5 % w/v L-Rhamnose

Preparation bio-ink

Grow cells overnight in ~ 5mL LB + CAM.

Spin down cells at 4000 rpm for 3 min

Discard supernatant

Resuspend pellet in 100 μL LB and transfer to 1.5 mL tube

Add 55.6 μL 5% w/v rhamnose to get a 0.5% rhamnose concentration

Add 400 μL alginate and vortex

Printing

Make line with pipet (~10-20 μL each) on plasma cleaned cover slip

Place cover slip onto a tissue

Add CaCl2 by dripping it on the alginate lines with pipet

Place the cover slip in vertical position on the tissue to remove most of the CaCl2

Retake above steps for the second line

Store

Put a tissue in a petri dish and make it wet

Put a piece of parafilm on top and place the sample on top of the parafilm

Store at room temperature

After induction with rhamnose wait at least 24h before dissolving the hydro gel

Dissolving gel

Place cover slip onto a tissue

Add sodium citrate by dripping it on the alginate lines with pipet

Place the cover slip in vertical position on the tissue to remove most of the sodium citrate

Store sample again in the petri dish

  1. Make an overnight culture of the cells containing the plasmid with csgA, using LB+CAM, at 37ºC and 220 RPM

  2. Dilute the cultures to a final OD600 of 0.05, by taking a small part of the overnight culture and adding LB+CAM

  3. Let the cultures grow at 37ºC and 220 RPM until the OD600 reaches a value between 0.4-0.6

  4. Induce the cultures with different concentrations of L-rhamnose, from 0% to 1%

  5. Add a small volume (1%) of the sample directly on the grid of the TEM

  6. Take pictures of the visualized bacteria

Gel making

  1. Grow BFP_SpyCatcher_His (TOP10) and empty TOP10 strain at 37°C overnight in LB medium.

  2. Measure the OD600. As the OD600 will probably be high (>2.5), make a ~50x dilution and grow the liquid cultures at 37°C for ~2h.

  3. Measure the OD600 again. If the OD600 is between 0.4 and 0.6 (exponential phase), continue to step 4.

  4. Fill the wells with different amounts of arabinose (from 100 g / L stock) and sterile water.

  5. Fill the wells with 180 ul LB + cells, or solely 180 ul LB.

  6. When all the wells are filled, measure the fluorescence and OD600 in a plate reader in time (at a temperature of 30°C).

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Resources

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Contact Details

Address:

Faculty of Applied Sciences

Room F109

TU Delft

Lorentzweg 1

2628 CJ Delft

The Netherlands

Phone:

+31 15 278 18 62

Email:

tudelft.igem@gmail.com