Difference between revisions of "Team:Stanford-Brown-RISD/Experiments"

Our overall project can be broken down into four sub-projects. These are characterized as the following: Mycelium Material & Habitat Development, Mycelium Glue Project, Mycelium Filter Project, and finally the Mission Architecture that ties everything together. Below are the Experiments, Materials, and Methods corresponding to each subproject.

Mycelium Glue

In designing our mycelium specific bioadhesive candidates, we looked for protein-based adhesive molecules that could be easily produced in E. coli and B. subtilis. We excluded highly glycosylated adhesive proteins as well as proteins with other significant post translational modifications (PTMs) simply because coordinating large PTMs in B. subtilis in space would be exceptionally challenging and beyond our capabilities for the summer. The last component of our criteria for identifying mycelium specific bioadhesive candidates revolved around the composition of mycelium itself. All fungus, mycelium included, contains an outer cell wall composed of chitin, which makes up the surface that would interface with the adhesive [3].

In nature, various organisms have evolved chitin-binding-domains (CBDs) that allow them to bind tightly to the fungal cell wall [4]. One of these organisms is B. circulans from which we borrowed a CBD sequence [4]. Our first glue candidate uses this CBD in a fusion protein of four CBD’s with GSGGSG linkers in between each; our hope was that this could act as a mycelium specific “cross linker” in a sense. Our construct also included a six residue polyhistidine tag and a Lumio fluorescent sequence (CCPGCCGAGG) for detection with Thermo Fisher Scientific’s Lumio Detection Kit [5].

Another protein-based adhesive candidate we investigated was csgA, the major subunit of the bacterial curli system which is secreted in monomers and self-assembles into longer polymer fibers that contribute to the biofilm formation[6]. The csgA protein has been known to be highly adhesive and have amyloid-forming properties, so it was reasoned that it would be a good starting point for bioadhesive proteins [6]. Furthermore, the manner in which csgA fusion proteins express the functionality of the introduced polypeptides while retaining their self-assembly behavior has made them a molecule of extreme interest in engineering functional biomaterials [7].

Our third glue candidate was a combination of the first two: a csgA-CBD fusion protein. We hoped to take advantage of the self-assembling nature of the csgA as well as its known tendency to aggregate under isoelectric conditions [5, 8]. The rationale for this fusion protein was that csgA has a strong affinity for binding its own monomers and CBD of course has a strong affinity for binding chitin. We theorized that a fusion protein with both of these domains would bond tightly to itself and to the mycelium surface.

Lastly, we decided to test the mussel foot fusion protein fp151 developed by researchers at Pohang University of Science and Technology [9]. The fp151 fusion protein is comprised of repeats of the most adhesive segments of marine mussel adhesive proteins (MAPs) 1 and 5 [9]. MAPs are the proteins responsible for adhering marine mussels to the rocks and other hard surfaces they live on in marine ecosystems [9]. It is thought that much of MAPs adhesion properties’ can be attributed to the high number of 3,4-dihydroxyphenyl-alanine (L-DOPA) residues, which require the hydroxylation of tyrosine [9]. To facilitate this post translational modification, we ordered an additional DNA construct encoding the tyrosinase enzyme, which would be able to hydroxylate tyrosine residues in vivo. We also ordered mushroom tyrosinase which has been shown to be able to hydroxylate tyrosine in vitro post-purification [10].

Once all five constructs were ordered, we ligated the linear DNA constructs to the PSB1C3 iGEM backbone using Gibson Assembly Mastermix 2x, transformed NEB T7 competent E.coli with our new plasmids, and plated the colonies on chloramphenicol selective LB plates. The colonies were incubated at 37℃ overnight or until there were distinct, visible colonies and never longer than 72 hours. The existence of our DNA constructs in the colonies were confirmed using verification primers in a colony PCR. We then performed his-tag purification on crude cell extracts from our colonies using Thermo Scientific HisPur Ni-NTA spin columns. Following protein purification with the Thermo Scientific HisPur Ni-NTA spin columns, we confirmed the presence of our protein in the final elution using Thermo Fisher Scientific’s Lumio Tag Protein Detection Kit. We then performed a standard BCA Assay to determine our total protein concentration in each elution.

To quantitatively test the strength of each purified glue candidate we performed a lap-shear test using the Instron 5565 in the Stanford Soft & Hybrid Materials Facility. To do this, we grew Ganoderma Lucidum mycelium on sawdust into the specified dimensions of the ASTM D3163 rectangle, which is used as a standard for lap-shear adhesive tests [11]. We also cut cardboard into these dimensions to use as a rough control that would help us assess whether or not our glue candidates were truly specific to mycelium material. Before applying our various glue candidates to the mycelium and cardboard specimens, we incubated our purified protein solutions at their isoelectric points at 4℃ for 2 days, spun them down, and discarded the supernatant. This was done to allow aggregate forming proteins (csgA, csga-CBD) to form amyloid fibers and non-amyloid-forming proteins (CBD4x, fp151) to reach their optimal pH [8].

Mycelium Filter

2.1 Design of a Copper-binding Biofilter

When designing our biofilter, we had two guiding questions in mind: how can we best bind metals on a molecular level, and how can we use synthetic biology to create a platform for functionalizing mycelial material? We also considered the advantages of our platform in comparison to previous efforts, such as flagella-based or cellulose filtration tools [9, 10]. One of the largest benefits of using mycelium material is that it leverages the concept of economies of scale, and presents an entirely feasible option of scale-up of our technology to a level that could be successfully implemented on a space mission and on earth in developing countries with poor access to clean water. Fungi are capable of displaying growth on an enormous variety of biomass types, and grow at a rate that is unparalleled by other biological agents used in synthetic biology today [11].

2.2 Chitin Binding

We sought to find ways to utilize mycotecture and enhance its properties, and in the process realized that chitin is ubiquitous in nature in organisms ranging from fungi to insects - in fact, it’s the second most abundant biopolymer on earth [12]. Methods to take advantage of this fact using synthetic biology are limited - we established a part collection using chitin binding domains as a novel platform to functionalize chitin-containing surfaces, with almost unlimited potential for modifying regions of organisms. We demonstrated the utility through designing novel biological cross-linking glues, fluorescent dyes, but most directly, filtration tools. Our use of the CBD in fusion protein production forms an important pipeline for future teams and the global scientific community for numerous applications, and here we focused on its use for metal recovery from mixed aqueous solution.

2.3 Copper Binding

We then sought to optimize the actual binding interaction between our peptides and metals. We chose copper as our proof of concept as a metal that is both biologically and economically important. When looking at past iGEM teams working with metal binding domains, we found that very few, if any, focused on optimizing the manner in which the metals were bound, instead choosing to simply obtain a binding domain from nature and attempting to implement it. We thought we could do better. A researcher in our lab, Dr. Jesica Urbina, developed a 20 amino acid long peptide (referred to as HHTC-Re (HNLGMNHVLQGNRPLVTQGC), that is a modified peptide with substituted amino acids adapted from the peptide HHTC designed by Kozisek et al. [13]. We wondered whether we could apply this in tandem with repeats to bind multiple copper atoms to the same biomolecule, and if we could use chitin binding domains (CBD’s) to create fusion proteins that could bind copper atoms and then also bind to chitin on our mycelium material [15].

2.4 Construct Design and Modeling

To test whether we could bind multiple metal ions on the same protein and if this relationship would be monotonically increasing, we designed peptides with one, two, and three copper binding domains in tandem (1xHHTC-Re HNLGMNHVLQGNRPLVTQGC, 2xHHTC-Re HNLGMNHVLQGNRPLVTQGCHNLGMNHVLQGNRPLVTQGC, 3xHHTC-Re HNLGMNHVLQGNRPLVTQGCHNLGMNHVLQGNRPLVTQGCHNLGMNHVLQGNRPLVTQGC; see biobrick page for sequence information). These three peptides were synthesized by Elim Biopharmaceuticals (Hayward, CA), and provided as a lyophilized powder at >98% purity. They were also modified to possess N-terminal acetylation/C-terminal amidation to avoid having a charged peptide [16]. 10 mM MES pH 5.5 and the Pierce BCA assay were used for reconstitution and concentration determination, respectively [17].

To check whether the proteins would retain their respective conformations when added in tandem, we used a tool produced by the Zhang lab (University of Michigan) for de novo protein structure prediction (QUARK) [14]. Based on the structures, we were able to hypothesize that the HHTC-Re domains would each be able to bind copper atoms, even when restricted spatially by ordering them sequentially without spacing.

Figure 1: Depiction of the design of the HHTC-Re repeating peptides, along with predicted ab initio structures as per the QUARK database and algorithms. Individual HHTC-Re domains retain their conformation, even in the 3x peptide.

Mission Architecture

On another planet, mycelia will grow and expand to provide structural integrity for the house, inside which the astronauts will live. However, the mycelia requires a substrate (food) and oxygen to grow. Where will these supplies come from? Cyanobacteria.

Cyanobacteria are self-replicating, photosynthetic organisms that can convert the abundant carbon dioxide from the Martian atmosphere into oxygen. This oxygen can be used to grow the mycelia, as well as to keep astronauts healthy and alive inside the habitat. Moreover, it has been shown that mycelia can use cyanobacteria as a substrate (food) to grow (at normal Earth gas concentrations). Our goal in this experiment is to demonstrate and quantify the oxygen production capabilities of a specific strain of cyanobacteria, known as Anabaena variablis. Achieving Earth-like percentages of oxygen (~20%) solely from the Anabaena, in combination with existing knowledge, would demonstrate the feasibility of cyano-based mycelial growth and Astronaut sustenance.

All experimentation was conducted inside an airtight, Nasco Whirl-Pak bag (total volume: 1627 mL). Two BD Gaspak Anaerobe Sachets were used to help establish an anoxic environment (down to .8% O2); Dry ice was used to establish a 90% + CO2 atmosphere, mimicking the Martian atmosphere. Wireless CO2 and O2 sensors measured the gas compositions over time, for the respective gases.