Rhagium inquisitor ice-binding protein gene

RiAFP

The RiAFP gene encodes an antifreeze protein (AFP). AFPs can bind to ice crystals and thereby prevent further ice growth. They are produced by organisms to survive in extremely cold environments. Activities of AFPs can be characterized by their thermal hysteresis (TH) or by their ice recrystallization inhibition (IRI). TH activity corresponds to the lowering of the freezing point without changing the melting point of a solution. IRI activity inhibits the growth of large ice crystals at the expense of smaller ones. The combination of these activities, which vary depending on the protein structure, prevents the freezing of body fluids and cell damage in organisms that live in extremely cold environments.

Profile

Usage and Biology

The RiAFP protein coding region was used in the following composite parts (add links). It was expressed in E. coli BL21 (DE3) and purified. Various tests and assays were performed to characterize and verify the functionality of this ice-binding protein. RiAFP has high TH and low IRI activity, and it can bind to ice crystals and inhibit their growth. The aim of our project was to use it on its own or in a mixture of other antifreeze proteins to develop a solution which could be applied on sensitive plant tissues and thereby protect crops from frost damage.

RiAFP is naturally produced by the Siberian cerambycid beetle Rhagium inquisitor. Its TH activity is around 6 K^[1].

AFPs bind to ice crystals and inhibit their growth. Ice crystals don’t have the same molecular arrangement on each of their faces and certain AFPs tend to adsorb to the basal plane of the crystals whilst others tend to adsorb to the prism plane. Hyperactive AFPs can bind to every plane^[2]. The mechanism by which AFPs suppress the freezing point of a solution is still not completely understood. Nevertheless, AFPs are believed to attach irreversibly to the plane of a growing ice crystal. As the protein adsorbs to the growing ice plane, growth at the site is suppressed, producing bulges in between the adsorbed proteins^[3]. Due to the Gibbs-Thomson effect, the freezing point will be depressed^[4].

Characterization

To reduce frost damage during late spring freeze, we wanted to develop a solution containing AFPs, which bind to ice crystals and inhibit their growth. RiAFP was therefore chosen as one of three AFPs, cloned and expressed in E. coli BL21 (DE3), and finally purified using a His-tag affinity column and gel filtration.
Two different vectors were used for cloning: pET-17b and pColdI, containing a T7 promoter and a cold-shock protein A (cspA) promoter, respectively.

Cloning

Figure 1: (a) RiAFP in the RiAFP-pColdI construct was visualized by a 1% Agarose Gel. Left to right: L - 1 kb DNA Ladder, 1 – pCold-I-RiAFP (588). (b) RiAFP in the pET-17b construct was visualized by a 1% Agarose Gel. Left to right: L - 1 kb DNA Ladder, 2 – pET-17b-RiAFP (640 bp).

RiAFP was cloned into the pET-17b plasmid using restriction and ligation via HindIII and XhoI and subsequent Gibson Assembly. The vector includes an ampicillin resistance gene and a lac operator, which allows for IPTG-induced gene expression. The final construct was checked on a 1% Agarose gel (Fig. 1, A) and via sequencing.

RiAFP was cloned into the pColdI plasmid using restriction and ligation via NdeI and XhoI and subsequent Gibson Assembly. The vector includes an ampicillin resistance gene and a lac operator, which allows for IPTG-induced gene expression. The final construct was checked on a 1% Agarose gel (Fig. 1, B) and via sequencing.

Expression and Purification

Figure 2: SDS-PAGE electrophoresis before and after RiAFP purification. RiAFP was expressed in E. coli BL21 (DE3) using both pCold-I and pET-17b vectors. Left to right: L - 10 to 250 kDa Protein Ladder, Bacterial Lysate: 1 - pET-17b-RiAFP, 2 - pCold-I-RiAFP. Purified Protein: 3 - pET-17b-RiAFP, 4 - pCold-I-RiAFP.

After we successfully transformed E. coli BL21 (DE3) with our pET-17b-RiAFP and pColdI-RiAFP constructs, we inoculated our transformed cells in liquid cultures of LB supplemented with ampicillin. Before inducing expression of our genes in large volumes of liquid cultures, we first did small-scale test purifications to verify if the AFPs could be correctly purified. Next, we grew 1-liter liquid cultures at 37 °C until an OD₆₀₀ of 0.6 was reached. We then placed the culture in a cooling incubator at 15 °C for 30 minutes. We added 1mM IPTG and induced expression at 15 °C for 24 hours. Afterwards, we removed a small volume of culture to run a total cell SDS-PAGE (15%) of E. coli cultures stained with Coomassie blue and to verify that the AFP was correctly overexpressed. The remaining culture was centrifuged, and the cell pellet was resuspended in Cold Lysis Buffer. We sonicated the cells and centrifuged the cells once more to collect the supernatant, which we loaded into the His-tag affinity column. We eluted the antifreeze proteins which bound to the column and concentrated the solution to a smaller volume. We performed a gel filtration to further purify the protein and finally stored aliquots at -80 °C.

We induced expression of RiAFP with IPTG and ran a total cell SDS-PAGE (15%) of the E. coli BL21 (DE3) cultures stained with Coomassie blue. We used two different vectors, pET-17b and pColdI, to compare how the promoters influenced expression efficiency. The overexpression was successful for RiAFP. We observed thicker bands that matched the expected weight of the protein. The pColdI vector worked better than the pET-17b vector, because the band appeared to be stronger for this first plasmid on the gel (Fig. 2).

ISF Assay

Figure 3: Thermal hysteresis of RiAFP and FfIBP increase with their concentration. Connected scatter plot graph showing the mean of biological triplicate +/- standard deviation. Thermal hysteresis is measured with two different AFPs, RiAFP and FfIBP, at different concentrations (µM).

To quantify the effect of AFPs on ice formation, we created a specific assay called "I Said Freeze" (ISF). AFPs can be characterized in multiple ways, one of which is thermal hysteresis (TH). TH is the difference of the freezing and melting temperature of existing ice crystals in solution. Below the freezing point temperature, ice crystals grow, and above the melting point, ice crystals shrink. Between these two temperatures, ice crystals neither grow or shrink.

To measure the TH, we need to measure the melting and freezing temperatures. We defined the melting temperature as the temperature at which there is only one ice crystal left and the freezing temperature as the moment at which the single ice crystal is growing rapidly and constantly. To see these ice crystals, we needed precise control of the temperature under a microscope. We therefore created Frozone (add link to wiki), a precise cooling device.

To have more precision, we used a microscope with a camera linked to a computer and our software to record ice crystal formation in our solution and follow the temperature at the same time. This allowed us to replay the experiment frame by frame to determine the precise temperatures.

We measured TH changes due to RiAFP using the ISF assay and found a TH of around 0.84 K for a concentration of 25 µM by averaging our results for three measurements. The average TH for a concentration of 50 µM is 2.1 K. In comparison, the TH of our buffer, which contains no protein, is averaged at 0.5 K. The graph (Fig. 3) shows how the TH is concentration dependent.

From these results, we can conclude that our antifreeze protein is functional, as we have successfully measured its TH value at two distinct concentrations.

FDT Assay

Figure 4: Our AFP solutions protect plants from frost damage. The graph shows mean +/- standard deviation. Percentage of Damage on Arabidopsis thaliana leaves measured after overnight incubation in a climatic chamber at -5ºC. Plants were immersed in phosphate-buffered saline (PBS) liquid solution supplemented with two different AFPs: FfIBP [200 µM] (n=13) and RiAFP [50 µM] (n=17) and a mix of them (RiAFP + FfIBP) (n=15) at a concentration of 25 µM and 100 µM, respectively. These solutions were compared with the control in which the plants were immersed in the PBS buffer without any AFP (buffer) (n=17). The damage ratio is significantly different between the buffer and all AFPs. ANOVA, * significant at p<0.05.Damage ratio between the different AFPs are not significant.

To measure how RiAFP will affect damage on plants during frost conditions, we developed the Frost Damage Treatment (FDT) assay. We immersed Arabidopsis thaliana (Wild-type) in a buffer containing the AFPs and then placed the plants in a thermal chamber at -5 °C overnight. The following day we stained the plants with Trypan blue, which colors dead cells with a compromised membrane in blue. In our case, the stain highlighted the cells damaged by the ice crystals.
After the staining, we cut all the leaves of our plants and placed them on microscope slides to observe them under a microscope. We took pictures of all the leaves and analyzed them with our algorithm VISION (add link to wiki) to obtain the percentage of damaged area on every leaf.

We used the FDT assay to analyze if RiAFP can reduce frost damage on plants. We immersed Arabidopsis thaliana in different solutions:

• A buffer solution without RiAFP, which served as a control to observe the damage on our plants without the protection of AFPs.
• A buffer with RiAFP to observe how the protein reduces frost damage on our plants After immersion of Arabidopsis thaliana in the various solutions, we placed the plants in a thermal chamber overnight, stained them the next day and analyzed them as previously described with our VISION algorithm.

Our results show that plants incubated in the buffer alone are significantly more damaged than those incubated in the AFP solutions, therefore confirming the protective effect of our AFPs.

Sequence and Features

References

1. ↑ Hakim A, Thakral D, Zhu DF, Nguyen JB. Expression, purification, crystallization and preliminary crystallographic studies of Rhagium inquisitor antifreeze protein. Acta Crystallogr Sect F Struct Biol Cryst Commun [Internet]. 2012 May [cited 2021 Oct 8];68(Pt 5):547. Available from: /pmc/articles/PMC3374510/
2. ↑ Olijve LLC, Meister K, DeVries AL, Duman JG, Guo S, Bakker HJ, et al. Blocking rapid ice crystal growth through nonbasal plane adsorption of antifreeze proteins. Proc Natl Acad Sci [Internet]. 2016 Apr 5 [cited 2021 Oct 10];113(14):3740–5. Available from: https://www.pnas.org/content/113/14/3740
3. ↑ LM S, AV T. Kinetic pinning and biological antifreezes. Phys Rev Lett [Internet]. 2004 Sep 17 [cited 2021 Oct 10];93(12). Available from: https://pubmed.ncbi.nlm.nih.gov/15447309/
4. ↑ Pereyra RG, Szleifer I, Carignano MA. Temperature dependence of ice critical nucleus size. J Chem Phys [Internet]. 2011 Jul 21 [cited 2021 Oct 10];135(3):034508. Available from: https://aip.scitation.org/doi/abs/10.1063/1.3613672