Cofactor-Independent RNA Editing by a Synthetic S-Type PPR Protein

ABSTRACT Pentatricopeptide repeat (PPR) proteins are RNA-binding proteins that are attractive tools for RNA processing in synthetic biology applications given their modular structure and ease of design. Several distinct types of motifs have been described from natural PPR proteins, but almost all work so far with synthetic PPR proteins has focused on the most widespread P-type motifs. We have investigated synthetic PPR proteins based on tandem repeats of the more compact S-type PPR motif found in plant organellar RNA editing factors, and particularly prevalent in the lycophyte Selaginella. With the aid of a novel plate-based screening method we show that synthetic S-type PPR proteins are easy to design, bind with high affinity and specificity, and are functional in a wide range of pH, salt and temperature conditions. We find that they outperform a synthetic P-type PPR scaffold in many situations. We designed an S-type editing factor to edit an RNA target in E. coli and demonstrate that it edits effectively without requiring any additional cofactors to be added to the system. These qualities make S-type PPR scaffolds ideal for developing new RNA processing tools.

Generation and Application of a Versatile CRISPR Toolkit for Mammalian Cell Engineering

CRISPR/Cas9 has revolutionized the field of genome engineering. Yet, as the CRISPR toolbox has rapidly expanded, there remains a need for a comprehensive library of CRISPR/Cas9 reagents that allow users to perform complex cellular and genetic manipulations without requiring labor-intensive generation of reagents to meet each user’s unique experimental circumstances. Here we described the creation and validation of a pNAX CRISPR library consisting of 72 different Cas9 and gRNA expression plasmids to allow for efficient multiplex gene editing, activation, and repression in mammalian cells. The toolkit plasmids, which are piggyBac or lentiviral based, provide the means for reliable and rapid delivery of Cas9/gRNA through either transient transfection or stable integration. Using the toolkit, we demonstrate the ease with which users can perform single or multiplex gene editing and modulate the expression of both coding and non-coding genes. We also highlight the use of the comprehensive toolkit to perform combinatorial gene knockout to identify factors that regulate homologous recombination, along with investigating the regulatory role of a 68-kb intronic region associated with human disease.

GoldBricks: An Improved Cloning Strategy that Combines Features of Golden Gate and Biobricks for Better Efficiency and Usability

ABSTRACT With increasing complexity of expression studies and the repertoire of characterized sequences, combinatorial cloning has become a common necessity. Techniques like Biobricks and Golden Gate aim to standardize and speed up the process of cloning large constructs while enabling sharing of resources. The Biobricks format provides a simplified and flexible approach to endless assembly with a compact library and useful intermediates but is a slow process, joining only two parts in a cycle. Golden Gate improves upon the speed with use of TypeIIS enzymes and joins several parts in a cycle but requires a larger library of parts and logistical inefficiencies scale up significantly in the multigene format. We present here a method that provides improvement over these techniques by combining their features. By using Type IIS enzymes in a format like Biobricks, we have enabled a faster and efficient assembly with reduced scarring, which performs at a similarly fast pace as Golden Gate, but significantly reduces library size and user input. Additionally, this method enables faster assembly of operon-style constructs, a feature requiring extensive workaround in Golden Gate. Our format allows such inclusions resulting in faster and more efficient assembly.

A CRISPR/Cas9 Method Facilitates Efficient Oligo-Mediated Gene Editing in Debaryomyces Hansenii

The halophilic and osmotolerant yeast Debaryomyces hansenii has a high potential for cell factory applications due to its resistance to harsh environmental factors and compatibility with a wide substrate range. However, currently available genetic techniques does not allow the full potential of D. hansenii as a cell factory to be harnessed. Moreover, most of the currently available tools rely on the use of auxotrophic markers that are not suitable in wild-type prototrophic strains. In addition, the preferred non-homologous end-joining (NHEJ) DNA damage repair mechanism pose further challenges when precise gene targeting is required. In this study, we present a novel plasmid based CRISPRCUG/Cas9 method for easy and efficient gene editing of the prototrophic strains of D. hansenii. Our toolset design is based on a dominant marker and facilitates quick assembly of the vectors expressing Cas9 and single or multiple sgRNAs that provides possibility for multiplex gene engineering even in prototrophic strains. Moreover, we have constructed an NHEJ deficient D. hansenii that enable our CRISPRCUG/Cas9 tools to support highly efficient introduction of point mutations and single/double gene deletions. Importantly, we also demonstrate that 90-nt single stranded DNA oligonucleotides are sufficient to direct repair of DNA breaks induced by sgRNA-Cas9 resulting in precise edits reaching 100% efficiencies. In conclusion, tools developed in this study will greatly advance basic and applied research in D. hansenii. In addition, we envision that our tools can be rapidly adapted for gene editing of other non-conventional yeast species including the ones belonging to the CUG clade.

Design and Assembly of DNA Molecules Using Multi-Objective Optimisation

Rapid engineering of biological systems is currently hindered by limited integration of manufacturing constraints into the design process, ultimately reducing the yield of many synthetic biology workflows. Here we tackle DNA engineering as a multi-objective optimization problem aiming at finding the best tradeoff between design requirements and manufacturing constraints. We developed a new open-source algorithm for DNA engineering, called Multi-Objective Optimisation algorithm for DNA Design and Assembly (MOODA), available as a Python and Anaconda package, as well as a Docker image. Experimental results show that our method provides near optimal constructs and scales linearly with design complexity, effectively paving the way to rational engineering of DNA molecules from genes to genomes.

Standardization of Inducer-Activated Broad Host Range Expression Modules: Debugging and Refactoring an Alkane-Responsive AlkS/PalkB Device

Although inducible heterologous expression systems have been available since the birth of recombinant DNA technology, the diversity of genetic devices and their coming together in the corresponding vectors often result in a lack of reproducibility and interoperability. In an effort to increase predictability of expression of genes of interest in a variety of possible bacterial hosts we propose a composition standard for debugging and reassembling all regulatory parts that participate in the performance of such devices. As a case study we addressed the n-octane and dicyclopropyl ketone (DCPK)-inducible PalkB promoter of the alkane biodegradation pOCT plasmid of Pseudomonas putida. The standardized expression module included an edited alkS transcription factor divergently expressed and separated from PalkB by a synthetic buffer sgement. The DNA sequence of the alkS gene was modified to alleviate the catabolite repression exerted by several carbon and nitrogen sources through the Crc/Hfq complex of some hosts. The PalkB promoter and the alkS variants were then formatted as SEVA (Standard European Vector Architecture) cargoes and their activity in P. putida quantified with GFP and luminiscent reporters. Despite considerable editing of the DNA sequences involved, the thereby refactored module basically kept the functioning parameters of the original configuration. The same qualities were inspected when the system was passed to Escherichia coli and P. aeruginosa. We argue that application of the compositional standard thereby implemented in the AlkS/PalkB module to other promoter/regulator pairs will enable more complex genetic programming in non-model bacteria.

Biofoundry-Assisted Expression and Characterisation of Plant Proteins

Many goals in synthetic biology, including the elucidation and refactoring of biosynthetic pathways and the engineering of regulatory circuits and networks, require knowledge of protein function. In plants, the prevalence of large gene families means it can be particularly challenging to link specific functions to individual proteins. However, protein characterisation has remained a technical bottleneck, often requiring significant effort to optimise expression and purification protocols. To leverage the ability of biofoundries to accelerate design-built-test-learn cycles, we present a workflow for automated DNA assembly and cell-free expression of plant proteins that accelerates optimisation and enables rapid screening of enzyme activity. First, we developed a phytobrick-compatible Golden Gate DNA assembly toolbox containing plasmid acceptors for cell-free expression using E. coli or wheat germ lysates as well as a set of N- and C-terminal tag parts for detection, purification, and improved expression/folding. We next optimised automated assembly of miniaturised cell-free reactions using an acoustic liquid handling platform and then compared tag configurations to identify those that increase expression. We additionally developed a luciferase-based system for rapid quantification that requires a minimal 11 aa tag and demonstrate facile removal of tags following synthesis. Finally, we show that several functional assays can be performed with cell-free protein synthesis reactions without the need for protein purification. Together, the combination of automated assembly of DNA parts and cell-free expression reactions should significantly increase the throughput of experiments to test and understand plant protein function and enable the direct reuse of DNA parts in downstream plant engineering workflows.

Data Sharing Policies: Share Well and You Shall be Rewarded

Sharing research data is an integral part of the scientific publishing process. By sharing data authors enable their readers to use their results in a way that the textual description of the results does not allow by itself. In order to achieve this objective, data should be shared in a way that makes it as easy as possible for readers to import them in computer software where they can be viewed, manipulated, and analyzed. Many authors and reviewers seem to misunderstand the purpose of the data sharing policies developed by journals. Rather than being an administrative burden that authors should comply with to get published, the objective of these policies is to help authors maximize the impact of their work by allowing other members of the scientific community to build upon it. Authors and reviewers need to understand the purpose of data sharing policies to assist editors and publishers in their efforts to ensure that every article published complies with them.

Contemporary Biomedical Engineering Perspective on Volitional Evolution for Human Radiotolerance Enhancement Beyond Low-Earth Orbit

A primary objective of the National Aeronautics and Space Administration (NASA) is expansion of humankind’s presence outside low-Earth orbit, culminating in permanent interplanetary travel and habitation. Having no inherent means of physiological detection or protection against ionizing radiation, humans incur capricious risk when journeying beyond low-Earth orbit for long periods. NASA has made large investments to analyze pathologies from space radiation exposure, emphasizing the importance of characterizing radiation’s physiological effects. Because natural evolution would require many generations to confer resistance against space radiation, immediately pragmatic approaches should be considered. Volitional evolution, defined as humans steering their own heredity, may inevitably retrofit the genome to mitigate resultant pathologies from space radiation exposure. Recently, uniquely radioprotective genes have been identified, conferring local or systemic radiotolerance when overexpressed in vitro and in vivo. Aiding in this process, the CRISPR/Cas9 technique is an inexpensive and reproducible instrument capable of making limited additions and deletions to the genome. Although cohorts can be identified and engineered to protect against radiation, alternative and supplemental strategies should be seriously considered. Advanced propulsion and mild synthetic torpor are perhaps the most likely to be integrated. Interfacing artificial intelligence with genetic engineering using predefined boundary conditions may enable the computational modeling of otherwise overly complex biological networks. The ethical context and boundaries of introducing genetically pioneered humans are considered.

Evaluation of inducible promoter–riboswitch constructs for heterologous protein expression in the cyanobacterial species Anabaena sp. PCC 7120

Cyanobacteria are promising chassis for synthetic biology applications due to the fact that they are photosynthetic organisms capable of growing in simple, inexpensive media. Given their slower growth rate than other model organisms such as Escherichia coli and Saccharomyces cerevisiae, there are fewer synthetic biology tools and promoters available for use in model cyanobacteria. Here, we compared a small library of promoter–riboswitch constructs for synthetic biology applications in Anabaena sp. PCC 7120, a model filamentous cyanobacterium. These constructs were designed from six cyanobacterial promoters of various strengths, each paired with one of two theophylline-responsive riboswitches. The promoter–riboswitch pairs were cloned upstream of a chloramphenicol acetyltransferase (cat) gene, and CAT activity was quantified using an in vitro assay. Addition of theophylline to cultures increased the CAT activity in almost all cases, allowing inducible protein production with natively constitutive promoters. We found that riboswitch F tended to have a lower induced and uninduced production compared to riboswitch E for the weak and medium promoters, although the difference was larger for the uninduced production, in accord with previous research. The strong promoters yielded a higher baseline CAT activity than medium strength and weak promoters. In addition, we observed no appreciable difference between CAT activity measured from strong promoters cultured in uninduced and induced conditions. The results of this study add to the genetic toolbox for cyanobacteria and allow future natural product and synthetic biology researchers to choose a construct that fits their needs.