E.coli strain construction

We assume expressing monomer streptavidin on the outer membrane of E.coli will help us using biotin-avidin system to link E.coli and S.cerevisiae. In part registry, we find BBa_K523013 constructed by team Edinburg encoding INP-eYFP. We acquire INP using PCR from this part. Then we choose promoter J23106 from part registry because it can express protein continuously so that we can have a relative steady co-culture system. The mSA part is from team Peking that give us much help. Monomer streptavidin is much smaller than wild type and is easier to use in circuit. Based on above reasons, we designed J23106-INP-mSA-pSB1C3 plasmid and trans-form into DH5α strain.

Fig 2.1 Electrophoresis result of expression vector. Lane 3&4 is pSB1C3-J23106-INP-mSA.

After the sequencing results confirmed that we successfully cloned the J23106-INP-mSA-PSB1C3 expression vectors, we transformed the target plasmids to DH5α for amplification.

Protein expression verification

If the protein is successfully expressed, they will be displayed on the extracellular mem-brane of the E.coli. Therefore, we can verify protein expression by detecting whether INP-mSA is displayed in the outer membrane protein.

We used the Fractionation Separation to extract three components of the outer mem-brane protein, the intimal protein and the cytoplasmic protein of engineered E.coli. Further Western Blot aim to confirm the previous result specifically and We choose to use horseradish peroxidase-biotin because it have the specific ability to bind INP-mSA.

Fig 2.2 Western blot analysis using HRP-biotin to evaluate JIM expression. lane1, the outer mem-brane of JIM; lane2, the intimal protein of JIM; the cytoplasmic protein of lane3; lane4, the outer membrane DH5α; lane5, the intimal protein of DH5α; lane6, the cytoplasmic protein of DH5α.

Western Blot result shows that there is a clear protein band at corresponding position with a correct size and the result specifically. It makes sure that we do express INP-mSA on the E.coli surface successfully .

Protein function verification

After verifying the protein expression, we want to prove that the protein can function as normal. We used Rhodamine-biotin to immunofluorescence stain the engineerd E.coli and negative strains DH5α to observe whether the bacteria had fluorescence under fluorescence microscope.

The result proves that the function of protein was normal.

Fig 2.3 Rhodamine-biotin immunofluorescence staining of engineerd E.coli(left) and negative strains(right).

Meanwhile, we would like to quantify the expression of INP-mSA compared with DH5α with plate reader. When we carried out the experiment, we met the problem that there are different incubating conditions in different paper. So we had to explore the best incubating condition of the INP-mSA protein expression. We did two sets of experiments to compare the fluorescence values of 2h incubation under two conditions (0 ℃ and 30 ℃).

Fig 2.4 Expression level of INP-mSA fusion protein under different conditions.( I ) the fluores-cence values of E.coli DH5α cell expressing JIM fusion and DH5α under 0 ℃ incu-bation for 2h. ( II ) the fluorescence values of E.coli DH5α cell expressing JIM fusion and DH5α under 30 ℃.

The image showed that E. coli containing Jim Plasmid successfully expressed INP-MSA fusion protein. The fluorescence value was higher after incubation of dye 2h under 30 ℃ conditions. We speculate that there may be an ice dye incubation that causes ice nucleation proteins to form crystals that inhibit the combination of fluorescent dyes and the MSA of fusion proteins.

Moreover, we want to confirm the connection between E.coli and S.cerevisiae by FACS analysis, because this analysis method can observe in single-cell level. We can use Rhoda-mine-polyethylene glycol-biotin to dye the E.coli containing JIM Plasmid for char-acterizing the expression of the protein by fluorescence detection.

Unfortunately, however, we found the Beckman flow cytometry (FCM) in our university couldn’t excite our fluorescent dye rhodamine-biotin so we was not able to use it to catch dyed E.coli. In spite of this, luckily we found that we can use FCM to confirm the ex-pression of biotin and its expressing percent. We use FITC-streptavidin to stain on S.cerevisiae and use 488nm exciting light to excite it while receive it at 525nm. As the result showed, the fluorescent peak shifted towards the direction of stronger fluorescent, which means positive sample express more BAP. Compared with the results of empty sam-ple, we can ensure that BAP is displayed on the surface of Saccharomyces cerevisiae. Above the threshold, there are 48% of Saccharomyces cerevisiae in the positive sample. While in the negative sample and empty sample, the percentage is only 28%.

Fig 2.5

Yeast strain construction

Here we need to construct the vector of BirA (biotin ligase) and BAP (biotin acceptor peptide) in yeast for displaying biotin on the surface.

We first cloned birA into the yeast-shuttle plasmid pYC230. After transformation, it ena-bles the yeast to transfer biotin to biotin-receiving peptide bap. pYD1 is another 5.0 KB ex-pression vector designed for expression, secretion, and display of proteins on the extracel-lular surface of S.cerevisiae. The vector contains AGA2 gene from S.cerevisiae encoding one subunit of the a-agglutinin receptor. Fusing our gene of interest to AGA2, so we can enable the yeast to display the biotin on the extracelluar surface.

Fig 2.6 Electrophoresis result of expression vector. Lane1&2 is pYD1-BAP, lane 3&4 is pSB1C3-J23106-INP-mSA, lane5&6 is pYC230-BirA.

After successful construction of plasmids, we introduced pYD1 containing BAP and pYC230 containing Bira into S.cerevisiae EBY100.

Protein expression verification

We want to test whether biotinylated bap is successfully integrated in the yeast cell wall. So we dye engineered yeast and negative control respectively with FITC-streptavidin. Using fluorescence microscopy we are able to observe the fluorescence of both.

Fig 2.7 The fluorescent staining of yeast with FITC-Streptomyces. (left) S.cerevisiae EBY100 without target gene; (middle) S.cerevisiae EBY100 with BAP+Bira though galactose induction for 12h; （right) S.cerevisiae EBY100 with BAP+Bira though galactose induction for 32h.

Meanwhile, we would like to quanty the expression of biotin compared with EBY100 with plate reader and wonder when biotin can reach the maximum expression.

Fig 2.8 Expression level of biotin in different time compared with negative controll.

And after Xh, the expression level of biotin achieved the highest amount.

Co-cultivation verification

We aimed to build an adhesion platform of E. coli and S.cerevisiae. Therefore, first we need to select a culture condition under which the heterogeneous cells can both grow happily. Taking into account the expression of the BAP in S.cerevisiae, galactose is required to induce protein expression. And to avoid diauxic growth of yeast when changing a new carbon source in the medium, we ultimaytely selected the YNB-CAA galactose medium. In order for the optimize expression of INP-MSA fusion protein, the in-ducing expression of BAP, and the growth rate of two heterogeneous cells, we took 28 ℃ as the culture temperature.

We characterized the growth curve of E. coli with JIM target gene and that of S.cerevisiae containing BirA & Bap under the mentioned culture condition. And the dry group wonder some parameters of the growth of E.coli and S.cerevisiae, as well as the consumption of galactose.

Fig 2.9 (left) The growth curve of E.coli with JIM; (right) the growth curve of S.cerevisiae containing BirA & Bap.

From the image we can tell, when the yeast and E.coli grows at 28 ℃, the culture time needs to be longer than 48h in order to make the yeast take a dominant proportion. We adjust the YNB-CAA galactose medium containing S.cerevisiae initial OD600 to 1.

Meanwhile, we used HLPC to measure the consumption of galactose.

Linkage validation

In order to illustrate that in practice, the co-culture of S.cerevisiae and E.coli can truly form the collaborating platform of heterologous cells, we will cultivate the two strains together by adding E.coli to the galactose-induced yeast. The co-cultured samples will then be dyed with rhodamine-biotin and FITC-streptavidin.

As is shown below, we can see that there are quite a few areas of overlapping red and green fluorescent in positive group where there are both S.cerevisiae and E.coli in the sample, indicating that they are very likely to have linked to each other. The negative control of S.cerevisiae and E.coli however, has either red or green fluorescent. And for the empty group, there is no fluorescent detected at all.

Fig 2.10 The co-cultured samples will then be dyed with rhodamine-biotin and FITC-streptavidin（tips: please maximize the intensity of your screen when looking at this picture）

Finally, we use the scanning tunneling microscope to shoot the microscopic structure of the connecting system and get a clearer picture of the connection structure. So far, we can say our adhesion platform is successfully established.

Fig 2.11 Observation of scanning tunneling microscope