Assembly by cut&paste
As we had trouble with our USER-specific primers request and could not start with the USER method, we started an alternative way to polymerize the MaSp1 monomers. Based on the Nature protocol of Teulé et al(ref) we designed a cut and paste technique, to duplicate the MaSp1 sequence at each round.
Telué and collaborators use a cloning vector with a restriction site in its resistance gene and two complementary but non regenerable restriction sites, one at each side of the insert, which is the sequence that is going to be duplicated. The vector is cut in two parallel separated digestions, at one side of the insert and at the resistance gene, and on the other side of the insert and also at the resistance gene. In both digestions, two fragments will be generated: one that contains the insert and a part of the resistance gene, and one that does not contain the insert. Ligating the insert-containing fragments of the two different digestions together results in the duplication of the insert in a vector with a complete resistance gene.
In our case we used the same vector, that would be transformed into our production organism,
Positive results
We were able to purify a PfuX7 polymerase and standardize a working PCR protocol
We were able to design and clone in pSB1C3 a protein domain part (BBa_K2136002) and a working gene expression cassete for microalgae (BBa_K2136010) !
General sequences assembly
iGEM requests all teams submit their sequences using pSB1C3 as plasmid backbone. Then, we have tried to bind our project’s sequences to it.
Initially, all our sequences were designed taking into account the codon usage of C. reinhardtii. Afterwards, we submitted these to IDT offer of gene synthesis (Table 1).
Table 1. Synthetic constructs designed by our team
On registry |
Description |
Length |
Function |
LysK |
1550 |
Enzybiotic |
|
MV-L |
1508 |
Enzybiotic |
|
BBa_K2136002 |
Lysostaphin |
803 |
Enzybiotic |
b-galacto |
1547 |
Gene reporter |
|
Lip_Thela |
872 |
Lipase |
|
gLuc |
569 |
Gene reporter |
|
Ea MaSp1 |
252 |
Spider silk proteins |
|
Lh MaSp1 Type 2 |
267 |
||
Lh MaSp1 Silwa 1 |
231 |
||
Lh MaSp1 Silwa 2 |
444 |
||
USER cassette |
141 |
||
BBa_K2136010 |
5' cassete for Chlamydomonas transgenic expression |
1593 |
Upper part of our synthetic cassette |
3' cassete for Chlamydomonas transgenic expression |
1478 |
Lower part of our synthetic cassette |
Resource setbacks in life force people to such an extreme to come up with clever solutions. In this regard, a bacterial extract bearing a X7 Pfu polymerase was purified to make affordable further molecular biology operations., USER cloning (see below) take advantage of this polymerase too because of its ability on dealing with uracil residues.
Since the arrival of primers on early-July and for the following months, our team dedicated huge efforts on cloning, with tons of unsuccessful transformations, each part.
Last but not least, throughout the project, we defy the traditional electrophoresis running buffer, named TAE or TBE, against sodium borate buffer which demonstrate to heat less, and therefore, running on high-voltage conditions without melting the gel.
Gathering of expression vector units
As we got fascinated by the novelty and eye-catching properties of Chlamydomonas reinhardtii, we cogitated that sending each unit of our expression vector system to Registry parts will expand current systems for protein expression, specially, the complex ones. In this way, we felt glad that we can share this with iGEMers, and even, any of each unit could be combined with other parts of the bank to enhance, test, prank in clever ways..
Characterization of expression vector
In order to study if our construct works as we expect, a fluorescent protein mCherry was inserted in it and some analyses about its expression were done.
Screening of mCherry expressing colonies
Since expression of proteins from nuclear transformation in Chlamydomonas may vary due to insertion location, we decided to screen the colonies upfront in a 96 well layout (Schematic in Proof of concept page). Basically, we picked the colonies from selection plates (TAP media supplemented with 5-10 μg/mL of Zeocin) and incubated it in 200 μL TAP media in an individual well. We performed this screening in two different set ups, due to availability of equipments. The basic setup schematic can be found in Proof of concept page.
SETUP 1
Microplate Shaker model :Agitador de Micro Placas Analógico AM 2.4 AN - INBRAS, Jardinopolis, SP, Brazil
Agitation: 800 RPM
Temperature: ~25oC
Light Intensity: 60 μE/cm2
mCherry measurement: 1 every 12 hours
Absorbance 750nm: 1 every 12 hours
Chlorophyl: 1 every 12 hours
SETUP 2
Microplate Shaker model: VWR INCUBATOR SHAKER-508 - Radnor, Pennsylvania, US
Agitation: 800 RPM
Temperature: ~25oC
Light Intensity: 60 μE/cm2
mCherry measurement: 3 every 12 hours
Absorbance 750nm: 4 every 12 hours
Chlorophyl: 1 every 12 hours
We follow mCherry production measuring mCherry fluorescence, cell growth by optical density in 750 nm absorbance and chlorophyll content by its fluorescence every 12 hours in both screenings (See results in Proof of Concept). Data acquisition were different because we tried to have a reduced measurement time in the first screening (~aprox. 3 min per total measurement). Nevertheless, more reliable data were needed and more measurements per well per time was performed (~aprox. 3 min per total measuremnt).
Plate Reading SETUP
Fluorescence Measurement - mCherry
Mode: Fluorescence Top Reading
Excitation Wavelength: 575 nm
Emission Wavelength: 608 nm
Excitation Bandwidth: 9 nm
Emission Bandwidth: 20 nm
Gain: 200 Manual
Number of Flashes: 10
Integration Time: 20 µs
Lag Time: 0 µs
Settle Time: 0 ms
Z-Position (Manual): 18141 µm
Optical Density - Chlamydomonas reinhardtii
Mode: Absorbance
Multiple Reads per Well (Circle (filled)): 2 x 2
Multiple Reads per Well (Border): 750 µm
Wavelength: 750 nm
Bandwidth: 9 nm
Number of Flashes: 25
Settle Time: 0
Fluorescence Measurement - Chlorophyll
Mode: Fluorescence Top Reading
Excitation Wavelength: 440 nm
Emission Wavelength: 680 nm
Excitation Bandwidth: 9 nm
Emission Bandwidth: 20 nm
Gain: 100 nm
Number of Flashes: 10
Integration Time: 20 µs
Lag Time: 0 µs
Settle Time: 0 ms
Z-Position (Manual): 18141 µm
“Homemade” mCherry detection
In order to observe mCherry secretion we developed a method to observe its fluorescence in the supernatant (Our target). We had a laser pointer (532nm +- 10nm) lay around and some filters we bought to construct a transilluminator for gels with GelRed™. We set up a quick experiment with the supernatant of the Wild type Chlamydomonas (cc1690) and the supernatant of our mCherry producing strain. We basically centrifuged 50 mL of culture media with our cells at 2500 x g for 15 min, and fixed the tubes in a support with the red filter in front of part of it. A green laser and a cellphone camera (With fixed iso and exposure) was all we needed to get the awesome photos better described with schematic in the Proof of Concept page.
Improvement of mCherry
Codon optimization
In order to express mCherry in algae, we used a codon optimized mCherry. It`s comparison with the available sequence at the registtry (BBa_J06504), in regard to CAI (Codon Adaptation Index) is summarized below at Table 1.
Table1: CAI comparison of BBa_J06504 with optimized mCherry to Chlamydomonas reinhardtii.
Parameters |
Available mCherry in Registry BBa_J06504 |
Codon Optimize mCherry to Chlamydomonas reinhardtii |
G+C content (%) - %GC: |
62.2 |
63.9 |
%GC1s: |
59.2 |
61.0 |
%GC2s |
35.9 |
35.9 |
%GC3s |
96.9 |
99.6 |
Kolmogorov-Smirnov test for the expected CAI (alpha = 0.05): |
0.054 |
0.035 |
Chi-Square Goodness-of-Fit test for AA (alpha = 0.05) |
the 100.0% of sequences fit the AA distribution |
the 100.0% of sequences fit the AA distribution |
Chi-Square Goodness-of-Fit test for G+C (alpha = 0.05): |
the 100.0% of sequences fit the G+C distribution |
the 100.0% of sequences fit the G+C distribution |
Average CAI |
0.761 |
0.807 |
eCAI (p<0.05) |
0.850 |
0.885 |
Ref1: Puigbo P, Bravo IG and Garcia-Vallve S. (2008) E-CAI: a novel server to estimate an expected value of Codon Adaptation Index (eCAI). BMC Bioinformatics, 9:65.
Ref2: Codon usage table from Kazusa.
FPLC - Fast protein liquid chromatography of mCherry in Chlamydomonas supernatant
Ion exchange purification exploit the net electrostatic charges of proteins, in pH values diferrent of their pI (Isoelectric point). We developed a purification protocol to mCherry, using an anionic resin. First, we performed a gradient purification protocol to establish the best salt concentration to elute mCherry.
Gradient Set_UP:
Column: Resource Q (6 mL) - GE Healthcare
Buffer A: Sodium Phosphate 50 mM, pH7.5
Buffer B: Sodium Phosphate 50 mM, pH7.5 + 1M NaCl
Equilibration: 2 column volume (CV)
Injection: 0.5mL 40X Concentrate supernatant sample
Gradient length: 20 CV
Flow rate: 5mL/min
Fractionation: 5mL to unbound and 3 mL to the rest of the method
We obtained the following result (Figure 1).
Figure 1: Chromatogram of gradient mCherry purification. Green line (-) is the UV sensor reading. Red line (-) is buffer B percentage in the mixture. Black line (-) is the conductivity measurement. Blue line (-) is the fluorescence measurement of fractionated samples.
We were surprised, with the result. Most of Chlamydomonas natural proteins got bound to the resin, and got eluted with an increased salt concentration. This method was an efficient way to purify mCherry from the supernatant. UV absorbance curve integration allow us to estimate the amount of protein separated from mCherry and 99% of all protein detected by the sensor was separated from mCherry fractions.
To further develop our method and reduce processing time, we developed a step based purification method (Figure 2). We kept 0% of B after injection for 3 CV, increase it a little bit to 0.7% of B to try to remove mCherry in this step, followed by a 100% of B step. This strategy was performed in a slower flow rate (3mL/min), and allow us to separate mCherry from 2 peaks in the beginning of the method. mCherry still left in the 0% step, but this method proved to be efficient, 99,7% of detected proteins were separated from mCherry.
Step based purification Set_UP:
Column: Resource Q (6 mL) - GE Healthcare
Buffer A: Sodium Phosphate 50 mM, pH7.5
Buffer B: Sodium Phosphate 50 mM, pH7.5 + 1M NaCl
Equilibration: 2 column volume (CV)
Injection: 0.5mL 40X Concentrate supernatant sample
Step1: 3 CV
Step2: 2 CV
Step3: 5 CV
Flow rate: 3mL/min
Fractionation: 5mL to unbound and 1 mL to Step 1, 3 mL to Step 2 and 5 mL to step 3.
Figure 2: Chromatogram of step based mCherry purification. Green line (-) is the UV sensor reading. Red line (-) is buffer B percentage in the mixture. Black line (-) is the conductivity measurement. Blue line (-) is the fluorescence measurement of fractionated samples.
Fluorescence measurements in all fractions were obtained in a plate reader (TECAN Infinite® 200 PRO), following the fluorescence measurement method described above.
mCherry Fluorescence Spectrum (Ex/Em)
The samples purified by FPLC were used to further characterize our mCherry produced by Chlamydomonas reinhardtii. We used aliquots from fractions 5 and 6 (Step purification) to construct and further characterize codon optimized mCherry (BBa_K2136016). We set up a plate reader (TECAN Infinite® 200 PRO) to obtain fluorescence spectrum of our mCherry.
Experiment SETUP:
Mode: Fluorescence Top Reading
Excitation Wavelength Start: 300 nm
Excitation Wavelength End: 600 nm
Excitation Wavelength Step Size: 1nm
Excitation Scan Number: 301
Emission Wavelength: 640 nm
Bandwidth (Em): 280...850: 20 nm
Bandwidth (Ex) (Range 1): 230...315: 5 nm
Bandwidth (Ex) (Range 2): 316...850: 10 nm
Gain: 200 Manual
Number of Flashes: 10
Integration Time: 20 µs
Lag Time: 0 µs
Settle Time:0 ms
Z-Position (Manual): 18141 µm
We were happy to see that our Excitation/Emission spectrum obtained was similar to the ones available to mCherry. We extended the available spectrum from 300 nm to 850 nm, allowing us to observe a small excitable region in 360 nm to mCherry. This experiment allowed us, simultaneously, further characterize this important biobrick (BBa_J06504), by adding an extended fluorescence spectrum and demonstrate the presence of mCherry in the supernatant of our algae strain (See Proof of Concept page for mCherry Fluorescence spectrum).
Figure 3: Excitation/Emission spectrum of mCherry produced and purified from Chlamydomonas supernatant.
USER of Lh Masp 1 Type 2
The size of silk genes is one of the most important problems to be solved in a project about silk production. Chemical synthesis presented some limitations to this sequence due to their high CG content and their repetitives sequences. Many cloning approaches has been used to polymerase them. We decided to explore a new technique to achieve this.
USER is a seamless assembly method to recombinant molecules from multiples components. USER reaction performs a excision of a Uracil in a nucleotide sequence, and this is exploited to generate complementary overhangs between sequences. Primers are designed to contain a Uracil at nucleotide 8-10 of its sequence. In the reaction a complementary overhang of 8-10 is created and allowed to align. The reaction mixture containing linearized plasmid with a USER adaptor sequence, and desired sequences are transformed into E.coli where the plasmid and sequence are completely ligated. We designed 4 primers to this experiment.
Figura USER se der
Assembly by restriction enzyme of Lh Masp 1 Type 2
As we had trouble with our USER-specific primers request and could not start with the USER method, we started an alternative way to polymerize the MaSp1 monomers.
Based on the Nature protocol of Teulé et al(ref) we designed a cut and paste technique, to duplicate the MaSp1 sequence at each round. Telué and collaborators use a cloning vector with a restriction site in its resistance gene and two complementary but non regenerable restriction sites, one at each side of the insert, which is the sequence that is going to be duplicated. The vector is cut in two parallel separated digestions, at one side of the insert and at the resistance gene, and on the other side of the insert and also at the resistance gene. In both digestions, two fragments will be generated: one that contains the insert and a part of the resistance gene, and one that does not contain the insert. Ligating the insert-containing fragments of the two different digestions together results in the duplication of the insert in a vector with a complete resistance gene.
In our case we used the same vector, that would be transformed into our production organism, Chlamydomonas reinhardtii. The pJP22 has a ScaI restriction site in the ampicillin resistance gene and two compatible but non regenerable restriction sites at the MCS: BglII and BamHI, so we went on and cloned the spider silk monomer MaSp1 Type2(link to part). Then, following the scheme of Teulé and collaborators(ref figure), we cut in parallel digestions the pJP22-MaSp1t2 with ScaI and either BamHI or BglII(ref figure). The insert-containing fragments were then ligated together and transformed into E. coli DH5alfa cells
We obtained an 8-mer MaSp1 type2 insert.
Lysostaphin expression
To analyse the activity of an enzybiotic that could be applied on silk functionalization in future works, we tried to express Lysostaphin. The lysostaphin sequence that was synthesized by IDT was successfully cloned into pSB1C3 and from there, we tried to clone it into pETDuet to be expressed in BL21 DE3. Unfortunately we did not get positive clones so far.