Spider silk serves as a new material with superior properties that can be applied in medication, cloth, and aerospace fields. However, spider breeding is not applicable due to spider's fierce behavior. The current approach is to produce recombinant spidroins (silk ) from other chassis and spin them into silk. NT-2Rep-CT is the common architecture in two main types of proteins: major ambulate spidroins(MaSps) and minor ampullate spidorins (MiSps). NT is a non-repetitive N-terminal domain, as well as CT, the C- terminal domain, In between them is an extensive repetitive region. In the storage of spider silk . This year, Greatbay_SZ constructed recombinant spider silk protein NT- 2Rep-CT (spidroin) that can spin into artificial spider silk fiber. This part is in the part collection where we provide improved recombinant chromoproteins and spidroins based on the functions of different regions of naturally occurring spidroin. By carrying out different mixing of the proteins of different combinations, we can produce artificially spun silk of different colors and properties. Our part collection can help and inspire future teams to further design recombinant spider silks of more variety and give silks diversified color and property to fulfill the collection.

Design Considerations NT can form stable dimers when pH decreases in the spinning duct. On the other side during the decrease of pH, the CT gets disrupted and unfold to turn in the beta- sheet -like fibrils. It is hypothesized that structural change of CT precipitate the change of the repetitive region to beta-sheet conformation.

We found the sequence of NT domain, CT domain and extensive region Rep. Codon optimization was carried out by us to code the nucleotide sequence of NT-2Rep-CT according to the E.coli codon bias. The construct was cloned into a pT7 plasmid and transformed into BL21 (DE3) E. coli. The construction includes: 1. a 6× His tag (MGHHHHHHM) is added to enable us carrying out Ni-NTA protein purification 2. an N-terminal domain based on the E. australis MaSp1 sequence (SHTTPWTNPGLAENFMNSFMQGLSSMPGFTASQLDDM STIAQSMVQSIQSLAAQGRTSPNKLQALNMAFASSMAEIAASEEGGG SLSTKTSSIASAMSNAFLQTTGVVNQPFINEITQLVSMFAQAGMNDVSA; EMBL accession number AM259067) 3. a repetitive part consisting of two polyalanine and -rich repeat regions from MaSp1 of E. australis (GNSGRGQGGYGQGSGGNAAAAAAAAAAAAAAAGQGGQGGYGR QSQGAGSAAAAAAAAAAAAAAGSGQGGYGGQGQGGYGQSGNS; EMBL accession number AJ973155) 4. a C-terminal domain based on the A. ventricosus MiSp sequence (VTSGGYGYGTSAAAGAGVAAGSYAGAVN RLSSAEAASRVSSNIAAIASGGASALPSVISNIYSGVVA SGVSSNEALI QALL ELLSALVHVLSSASIGNVSSVGVDSTLNVVQ DSVGQYVG; GenBank accession number JX513956). Also, the linker between the NT/CT and the 2Rep(repetitive region) is GNS

Characterization

We aimed to use a synthetic biology approach to combine standardized DNA part NT-2Rep-CT, and transform constructs to metabolically engineered E. coli for bioproduction. Purification and SDS PAGE

In order to detect whether protein expression was induced by adding isopropylthiogalactoside (final concentration 0.3mM), we used SDS-page(12%) to determine the presence of target protein. The induced protein was initially 34kDa, which it consistent with the previous research (Andersson, Marlene, et al. 2017).

Spidroin Production measure BCA protein essay kit give us the specified data of the average amount of protein we extracted in parallel sets of Ni-NTA purification (Fig.2). Result shows the amount of spidroin in shaking-flask E.coli cultures and yielded average around 336±49 mg protein/L, and 46±10mg/g, which is more than double of the yield in previous research (125mg protein/L) (Andersson, Marlene, et al. 2017) and most yielded protein among all spidroins we produced this year. Fiber spinning

NT2RepCT has the feature of pH-dependent assembly, because lowered pH and shearing induce adjusts conformational changes that result in conversion from soluble protein to beta-sheet fibers. At pH>7, NT is in highly soluble state, which lead the spidroin to have high solubility. Due to the lock and trigger mechanism, when pH is lowered in the end of the silk duct, NT forms stable dimers and therefore interconnects the spidroins by applying pulling force alone the fiber via protein chains; CT, at the same time, unfolds to form amyloid-like fibrils that serves as the nucleation seeds of the conversion of the repetitive region (2Rep) into beta- sheet structures. (Andersson, Marlene, et al. 2017) To further substantiate the role of pH in fiber spinning, we carried out artificial fiber spinning in different aqueous buffers that valued from (pH2.0 to pH7.0) with same extruding speed. (Fig.4.A) sketches these relationships. When pH of the buffer bath is from 2.0 to 4.0 gelatinous substance forms and attach to the syringe until disappearing shortly in the solution. Continuous fibers formed when buffer pH is in between 5.0 to 6.0. Fiber is visually continuously formed in pH=7.0 buffer, but disrupted easily when we try to reach the fiber and lift. Besides the pH change, in our biomimetic spinning, we also used 100% isopropanol (Fig.3.A) in the fibre spinning solution and gained a continuous and uniformly-distributed fibre that would not be interrupted by lifting to collect.

Scanning electron microscopy of fibers

Aiming to verify the distribution uniformity of NT2RepCT after spinning into fiber, we looked at our artificial spun silks by NT-2Rep-CT spidroin and concocting NT-2Rep- CT spidroin with sfGFP chromoprotein under electron microscope (Fig.5), the role of sfGFP chromoprotein here is for us to clearly observe our silk under electron microscope. We randomly selected the cross section in our continuous silk, it is clearly shown that the fiber circularity is qualified as a uniformly distributed silk. Without sfGFP mixed, the spider silk spun by NT-2Rep-CT spidroin only can not be observed from the positive electron microscope image due to its lack of fluorescence. ———————————————————————————————————— Reference [1] Andersson, Marlene, et al. “Biomimetic Spinning of Artificial Spider Silk from a Chimeric Minispidroin.” /Nature Chemical Biology/, vol. 13, no. 3, Sept. 2017, pp. 262–264., doi:10.1038/nchembio.2269.