Line 169: | Line 169: | ||
</div> | </div> | ||
</div> | </div> | ||
− | <p> <font size="3">Python 3.7.0 (package downloaded from <a href="https://www.python.org/" | + | <p> <font size="3">Python 3.7.0 (package downloaded from<a href="https://www.python.org/" class="black">Python</a> was the programming language used for development of liquid handling protocols. Python script was written and edited using TextWrangler (Bare Bones Software, United States). TextWrangler.py files could then be read by the OT-2 App (http://opentrons.com/ot-app). Once protocols were developed and showed preliminary success, python scripts were uploaded to the GitHub development platform (GitHub, United States) for open-source sharing and further collaborative development (see <a href="https://github.com/jbird1223/Newcastle-iGEM" class="black">GitHub Newcastle iGEM</a> for file downloads and access).</font></p> |
<p> <font size="3">Custom made plastic ice box containers with customisable tube rack inserts were drawn up using EazyDraw 3.10.9 software (Dekorra Optics LLC, United States) and 3D printed. Cold boxes were 3D modelled in SketchUp (Trimble Inc.) and constructed out of PLA using an Ultimaker 3 Extended desktop printer (Ultimaker). Customisable tube rack inserts were redrawn accurately using Adobe illustrator and exported as a PDF. A FB700 laser cutter was then used to cut the inserts. Models were uploaded to GitHub to allow open access. A 200 uL TipOne rack adapter downloaded from open-source module page was also constructed using an Ultimaker.</font></p> | <p> <font size="3">Custom made plastic ice box containers with customisable tube rack inserts were drawn up using EazyDraw 3.10.9 software (Dekorra Optics LLC, United States) and 3D printed. Cold boxes were 3D modelled in SketchUp (Trimble Inc.) and constructed out of PLA using an Ultimaker 3 Extended desktop printer (Ultimaker). Customisable tube rack inserts were redrawn accurately using Adobe illustrator and exported as a PDF. A FB700 laser cutter was then used to cut the inserts. Models were uploaded to GitHub to allow open access. A 200 uL TipOne rack adapter downloaded from open-source module page was also constructed using an Ultimaker.</font></p> |
Revision as of 19:51, 17 October 2018
Alternative Roots
Materials and Methods
Implementing the New Devices
Bacterial Strains.
Transformations with, and expression of, iGEM test devices and controls were carried out using chemically competent Escherichia coli DH5α. Competency was conferred using the MgCl-CaCl2 method [1]. Briefly, a single colony of DH5α was incubated in Leuria Bertoni (LB) broth overnight at 37°C with shaking at 220rpm. Overnight culture was diluted 1:100, further incubated until an optical density (OD600nm) of 0.3 – 0.6 was reached and then placed on ice for 30 minutes. Cells were centrifuged at 4000g for 5 minutes at 4°C, resuspended in 0.1M MgCl2 and incubated on ice for 30 minutes. The suspension was centrifuged again as before, resuspended in 0.1M CaCl2 and placed on ice for 30 minutes. Cells were spun down again, resuspended in 0.1M CaCl2 with 15% glycerol and frozen at -80°C.
Plate Reader Set-up
Culture absorbance and fluorescence were measured in 96 well plates using a Thermofisher Varioskan Lux plate reader (Thermofisher scientific) unless stated otherwise. Absorbance was measured at 600nm. GFP Fluorescence was measured at 525nm with excitation at 485nm. RFP fluorescence was measured at 635nm with excitation at 588nm. All readings took place at 25°C after a 5 second 300rpm shake step to homogenise the culture. Readings used a 12nm bandpass width and pathlength correction was disabled, as per the iGEM Interlab study guidelines.
Internal Standard & mNeonGreen Design
An RFP construct was designed for use as an internal standard for each test device. The RFP construct was designed using Benchling. The parts used for building the RFP construct were Anderson promoter BBa_J23108, RBS BBa_0032, the RFP gene - gained from SnapGene - and double terminator BBa_B0015. Gibson ends were also designed for cloning into pSB1C3 using the NEBuilder DNA assembly tool and the gBlock was synthesised by IDT. The promoter has a measured strength of 0.51 relative to BBa_J23100.
The mNeonGreen construct was designed for use as an alternate fluorescent reporter for each test device - replacing GFP. The mNeonGreen sequence was codon optimised using Benchling and the Gibson ends were designed using NEBuilder for cloning into pSB1C3. The subsequent sequence was synthesised by IDT.
Cloning of New Devices into pSB1C3
Plasmid vectors were purified from E. coli via miniprep (Qiagen)and the concentration for each mini-prepped test device was determined using a Qubit fluorometer and diluted to 0.5 ng/µl. The diluted pSB1C3 vectors were linearised using a 2 step PCR system following a Q5 Polymerase protocol (NEB). This protocol utilised forward and reverse primers with Tm values of 72°C. The internal standard and mNeonGreen primers were designed by using the NEB Tm calculator and Benchling. The Internal Standard bind in a non-coding region of the pSB1C3 vector – a region between the chloramphenicol resistance gene and the ORI. The mNeonGreen primers consisted of 6 reverse primers, one complimentary to each test device promoter, and a single forward primer over the terminator. The amplified DNA was then digested with DpnI, heat treated to inactivate the enzyme and assembled via Gibson Assembly using the NEBuilder HiFi DNA Assembly Kit. Following their protocol, a 2-fragment reaction with 0.5 pmol of DNA in a 2:1 insert to vector ratio was done and transformants were plated onto agar plates with the appropriate antibiotic (LB+cam for each test device and LB+amp for the controls). Following growth of colonies, plasmid DNA was miniprepped from DH5α transformed with both the internal standard and the mNeonGreen vector and sequenced to verify presence of the genes.
Internal Standard & mNeonGreen Analysis
Analysis of the internal standards involved comparing the original InterLab test device plasmids against the new internal standard plasmids. Wells A-D represented the RFP containing E. coli and wells E-H represented the original test device containing E. coli. Column 9 wells A-H contained an LB+CAM blank. The microtiter plate was incubated for 24 hours in the plate reader with Abs600, fluorescence (GFP): Excitation 485, Emission 420 and fluorescence (RFP): Excitation 588, emission 635 measured every 15 minutes following a short shake at 420 rpm at a low shake diameter.
Three further Interlab studies were carried out for mNeonGreen expressing E. coli and those containing the original test devices, using the same conditions as the original study. The results fluorescence/OD, MEFL/particle and mean standard error of the mNeonGreen study was compared to the original Interlab.
Bio-Design Automation
Transformation Buffer Preparation
Primary transformation buffers (TB) before optimisation were CCMB80 protocol and a CaCl2-MgCl2 protocol. CCMB80 buffer was made from the following: 10 mM KOAc, 80 mM CaCl2, 20 mM MnCl2, 10 mM MgCl2, 10% glycerol and pH was adjusted to 6.4 with 0.1 N HCl. For the CaCl2-MgCl2 protocol, a 100 mM CaCl2 and a 100 mM MgCl2 solution were made. For preliminary DoE scoping experiments, concentrated stock solutions were made up of each individual reagent, buffer or compound. These stocks were used for the low, medium and high scoping (Table 1), buffer (Table 2), wash step (no wash, 1 wash or 2 wash) and cryoprotectant experiments (Medium TB with either DMSO 7.5% or glycerol 18%). All buffers were filter sterilised using Soft-Ject® syringes with Minisart 0.2 um filter (bar DMSO which was filtered with a DMSO-Safe Acrodisc® filter) and stored in 30 mL sterile universal tubes at 4 ℃. Fresh stocks were made when solutions ran out, however concentrations and storage remained the same.