Refactoring bacteriophage T7

Natural biological systems are selected by evolution to continue to exist and evolve. Evolution likely gives rise to complicated systems that are difficult to understand and manipulate. Here, we redesign the genome of a natural biological system, bacteriophage T7, in order to specify an engineered surrogate that, if viable, would be easier to study and extend. Our initial design goals were to physically separate and enable unique manipulation of primary genetic elements. Implicit in our design are the hypotheses that overlapping genetic elements are, in aggregate, nonessential for T7 viability and that our models for the functions encoded by elements are sufficient. To test our initial design, we replaced the left 11 515 base pairs (bp) of the 39 937 bp wild-type genome with 12 179 bp of engineered DNA. The resulting chimeric genome encodes a viable bacteriophage that appears to maintain key features of the original while being simpler to model and easier to manipulate. The viability of our initial design suggests that the genomes encoding natural biological systems can be systematically redesigned and built anew in service of scientific understanding or human intention

The impact of engineered design constraints upon bacteriophage T7 evolution

Since the establishment of molecular biology until the present, a shift has taken place by which engineering of biology has increased in its scope, power, and influence. Synthetic biology is the latest term that advances the overall goal of engineering control of biological systems. Enabled by the recent progress in the ability to read and write nucleic acids, synthetic biology stands out in its desire for standardization of parts, processes, assays, and even organisms. This standardization has led to multiple successful outcomes which justify its utility. However, this standardization via synthetic biology is imbued with an implicit hubris: it may be that certain aspects of biological phenomena are too complex to lend themselves to systemization. Engineering biology, unlike other engineering disciplines, is not obviously governed by a simple series of equations but, rather, united by one universal theme: evolution happens. Because of this, much work has been done in order to study not just how evolution works and but also into controlling, accelerating, and biasing it in a laboratory setting. The former work can be generally classified as “evolutionary biology” and the latter called “directed evolution”. In this dissertation, work is presented which blurs the line between evolutionary biology and directed evolution yielding unanticipated outcomes and new methods of biological control. Three projects are presented in which evolution of bacteriophage T7 is studied in response to rationally engineered design constraints. In the first, the predictability of bacteriophage T7 promoter evolution in response to a novel RNA polymerase is determined. In the second, the evolution of the entirety of the transcriptional apparatus of bacteriophage T7 is studied in the context of an evolutionarily adapted bacteriophage population. Finally, the construction, exploration, and optimization of a designed bacteriophage T7 life-cycling system reliant on proteases are described. Together, this work provides evidence that although the ability to rationally design biology is important, various ways to rationally control and direct evolution offer a complementary strategy to the systematization of synthetic biology.Cellular and Molecular Biolog

Flavivirus reverse genetic systems, construction techniques and applications: A historical perspective

AbstractThe study of flaviviruses, which cause some of the most important emerging tropical and sub-tropical human arbovirus diseases, has greatly benefited from the use of reverse genetic systems since its first development for yellow fever virus in 1989. Reverse genetics technology has completely revolutionized the study of these viruses, making it possible to manipulate their genomes and evaluate the direct effects of these changes on their biology and pathogenesis. The most commonly used reverse genetics system is the infectious clone technology. Whilst flavivirus infectious clones provide a powerful tool, their construction as full-length cDNA molecules in bacterial vectors can be problematic, laborious and time consuming, because they are often unstable, contain unwanted induced substitutions and may be toxic for bacteria due to viral protein expression. The incredible technological advances that have been made during the past 30years, such as the use of PCR or new sequencing methods, have allowed the development of new approaches to improve preexisting systems or elaborate new strategies that overcome these problems. This review summarizes the evolution and major technical breakthroughs in the development of flavivirus reverse genetics technologies and their application to the further understanding and control of these viruses and their diseases

The evolution and engineering of T7 RNA polymerase

textT7 RNA polymerase is a single protein capable of driving transcription from a simple promoter in virtually any context. This has made it a powerful tool in a range of biotechnology applications. In this work, previous efforts to evolve or engineer T7 RNA polymerase are reviewed. This work is then expanded upon, first with the development of a method for the cell-free evolution of T7 RNA polymerase based on the functioning of an autogene. The autogene is a transcriptional feedback circuit in which active T7 RNA polymerase proteins transcribe their own gene, resulting in exponential amplification of their genetic information. While this system is doomed by an error catastrophe, this can be delayed by the use of in vitro compartmentalization. In response to the limits of the autogene, a novel directed evolution approach termed compartmentalized partnered replication (CPR) is presented. CPR couples the in vivo functionality of a gene to its subsequent in vitro amplification by emulsion PCR. The use of CPR to generate a panel of six versions of T7 RNA polymerase, each specific to one of six promoters, is described. Separately, a rational engineering approach, taken to facilitate the high-yield transcription of fully 2′-modified RNA, is detailed. Two sets of mutations to T7 RNA polymerase, previously known to confer thermal stability and enhance promoter clearance respectively, can be used to enhance the activity of existing T7 RNA polymerase mutants that utilize non-standard nucleotides as their substrates. Next, CPR and random mutagenesis is used to populate the functional fitness landscape of T7 RNA polymerase. This neutral drift library is then challenged to increase the processivity of T7 RNA polymerase, enabling long-range transcription. Finally, the lessons that can be learned about T7 RNA polymerase specifically and molecular evolution and protein engineering generally are discussed.Cellular and Molecular Biolog

Regional mutagenesis of the gene encoding the phage Mu late gene activator C identifies two separate regions important for DNA binding

Lytic development of bacteriophage Mu is controlled by a regulatory cascade and involves three phases of transcription: early, middle and late. Late transcription requires the host RNA polymerase holoenzyme and a 16.5-kDa Mu-encoded activator protein C. Consistent with these requirements, the four late promoters Plys, PI, PP and Pmom have recognizable −10 hexamers but lack typical −35 hexamers. The C protein binds to a 16-bp imperfect dyad-symmetrical sequence element centered at −43.5 and overlapping the −35 region. Based on the crystal structure of the closely related Mor protein, the activator of Mu middle transcription, we predict that two regions of C are involved in DNA binding: a helix-turn-helix region and a β-strand region linking the dimerization and helix-turn-helix domains. To test this hypothesis, we carried out mutagenesis of the corresponding regions of the C gene by degenerate oligonucleotide-directed PCR and screened the resulting mutants for their ability to activate a Plys-galK fusion. Analysis of the mutant proteins by gel mobility shift, β-galactosidase and polyacrylamide gel electrophoresis assays identified a number of amino acid residues important for C DNA binding in both regions

A 'resource allocator' for transcription based on a highly fragmented T7 RNA polymerase

Synthetic genetic systems share resources with the host, including machinery for transcription and translation. Phage RNA polymerases (RNAPs) decouple transcription from the host and generate high expression. However, they can exhibit toxicity and lack accessory proteins (σ factors and activators) that enable switching between different promoters and modulation of activity. Here, we show that T7 RNAP (883 amino acids) can be divided into four fragments that have to be co‐expressed to function. The DNA‐binding loop is encoded in a C‐terminal 285‐aa ‘σ fragment’, and fragments with different specificity can direct the remaining 601‐aa ‘core fragment’ to different promoters. Using these parts, we have built a resource allocator that sets the core fragment concentration, which is then shared by multiple σ fragments. Adjusting the concentration of the core fragment sets the maximum transcriptional capacity available to a synthetic system. Further, positive and negative regulation is implemented using a 67‐aa N‐terminal ‘α fragment’ and a null (inactivated) σ fragment, respectively. The α fragment can be fused to recombinant proteins to make promoters responsive to their levels. These parts provide a toolbox to allocate transcriptional resources via different schemes, which we demonstrate by building a system which adjusts promoter activity to compensate for the difference in copy number of two plasmids.United States. Office of Naval Research (N00014‐13‐1‐0074)National Institutes of Health (U.S.) (5R01GM095765)National Science Foundation (U.S.) (Synthetic Biology Engineering Research Center (SA5284‐11210))United States. Dept. of Defense (National Defense Science and Engineering Graduate Fellowship (NDSEG) Program))Hertz Foundation (Fellowship

A Temperature-sensitive Mutant of Escherichia Coli Affected in the Alpha Subunit of RNA Polymerase

A temperature-sensitive mutant of Escherichia coli affected in the alpha subunit of RNA polymerase has been investigated. Gene mapping and complementation experiments placed the mutation to temperature-sensitivity within the alpha operon at 72 min on the bacterial chromosome. The rate of RNA synthesis in vivo and the accumulation of ribosomal RNA were significantly reduced in the mutant at 44\sp\circC. The thermostability at 44\sp\circC of the purified holoenzyme from mutant cells was about 20% of that of the normal enzyme. Assays with T7 DNA as a template showed that the fraction of active enzyme competent for transcription was reduced as a function of assay temperature but that initiation and elongation were not significantly affected by the alpha mutation. A major effect on the fidelity of transcription was observed with the mutant enzyme, with misincorporation on two different templates stimulated about four fold at 37\sp\circC. The role of the alpha dimer in the structure and function of RNA polymerase is discussed. In addition during the course of this study a new procedure for the purification of E. coli RNA polymerase was developed. This method is rapid, convenient, and useful for the preparation of enzyme from 1-5 grams of cells in two days. The ease and speed of this method allowed the rapid characterization of the mutant enzyme. This system should also find application for the purification of small quantities of other bacterial RNA polymerases that share the general chromatographic properties of E. coli RNA polymerase

Intracellular directed evolution of proteins from combinatorial libraries based on conditional phage replication

Directed evolution is a powerful tool to improve the characteristics of biomolecules. Here we present a protocol for the intracellular evolution of proteins with distinct differences and advantages in comparison with established techniques. These include the ability to select for a particular function from a library of protein variants inside cells, minimizing undesired coevolution and propagation of nonfunctional library members, as well as allowing positive and negative selection logics using basally active promoters. A typical evolution experiment comprises the following stages: (i) preparation of a combinatorial M13 phagemid (PM) library expressing variants of the gene of interest (GOI) and preparation of the Escherichia coli host cells; (ii) multiple rounds of an intracellular selection process toward a desired activity; and (iii) the characterization of the evolved target proteins. The system has been developed for the selection of new orthogonal transcription factors (TFs) but is capable of evolving any gene—or gene circuit function—that can be linked to conditional M13 phage replication. Here we demonstrate our approach using as an example the directed evolution of the bacteriophage λ cI TF against two synthetic bidirectional promoters. The evolved TF variants enable simultaneous activation and repression against their engineered promoters and do not cross-react with the wild-type promoter, thus ensuring orthogonality. This protocol requires no special equipment, allowing synthetic biologists and general users to evolve improved biomolecules within ~7 weeks

Riboregulation of Bacterial Transposons

Bacterial transposons typically exist in a mutually beneficial relationship with the host cell. Limited transposition can benefit the host while also ensuring the survival of the element. An important component of this relationship is that transposition must be tightly regulated. In this thesis I explore ways that the host and transposon each control transposition in E. coli and provide evidence that a transposon can also control host gene expression in S. enterica Typhimurium. Post-transcriptional regulation with small non-coding RNAs (sRNA) has emerged as a key way that bacteria respond to stress and regulate many cellular processes. The RNA-binding protein Hfq is the nexus of sRNA regulatory networks and acts by promoting base-pairing interactions between sRNAs and their target mRNAs. Previous work found that Hfq is a potent negative regulator of IS10 transposition in E. coli and suggested that Hfq inhibited transposase translation using an IS10-encoded sRNA (RNA-OUT) as well as an undefined mechanism that was independent of RNA-OUT. I show that Hfq promotes base-pairing between RNA-OUT and IS10 transposase mRNA (RNA-IN) by melting the secondary structure of both RNAs to expose residues involved in intermolecular base-pairing. I also investigated how Hfq can repress translation of RNA-IN in the absence of RNA-OUT and demonstrate that Hfq-binding to an mRNA can directly repress translation in the absence of any sRNA. The data suggested Hfq may regulate other transposons and I show that the unrelated IS200 element is also subject to Hfq regulation. In contrast to the IS10 system, Hfq represses IS200 transposase (tnpA) translation completely independent of the IS200-encoded sRNA (art200). Translation initiation on tnpA is inhibited \u3e350-fold by the cooperation of Hfq, art200, and an RNA structural element in the tnpA 5’UTR illustrating how host- and transposon-encoded factors can coordinate to repress transposition. Lastly, I demonstrate that tnpA is processed to produce an sRNA that alters transcript abundance \u3e2-fold for 73 S. enterica Typhimurium genes, which provides a new twist on our understanding of host-transposon interactions. Taken together, this work suggests that RNA transactions play an important role in governing host-transposon relationships in bacteria

Evolution of phage-type RNA polymerases in higher plants

In mono- und eudikotylen Pflanzen kodiert eine Genfamilie (RpoT, RNA-Polymerase des T3/T7-Typs) mitochondriale und plastidäre RNA-Polymerasen (RNAP), die den ungeraden T-Phagen-Polymerasen ähneln. RpoT-Gene von Angiospermen sind gut charakterisiert, während aus tiefer abzweigenden Pflanzenspecies bisher lediglich die Gene aus dem Moos Physcomitrella beschrieben wurden. Um einen Beitrag zur Aufklärung der molekularen Evolution der RpoT-Polymerasen im Pflanzenreich zu liefern und um Erkenntnisse über die potentielle Bedeutung von multiplen Phagen-Typ (RNAP) in Pflanzen zu gewinnen, wurden die RpoT-Gene aus dem Lycophyten Selaginella moellendorffii und aus dem basalen Angiosperm Nuphar advena identifiziert und charakterisiert. Selaginella moellendorffii (Moosfarn)-Trace-Sequenzdaten mit hoher Ähnlichkeit zu RpoT-Sequenzen von Angiospermen wurden benutzt, um das full-length SmRpoT-Gen und die entsprechende cDNA zu isolieren. Die SmRpoT-mRNA ist 3542 nt lang und weist einen offenen Leserahmen von 3006 nt auf, der für ein putatives Protein aus 1002 Aminosäuren mit einer molekularen Masse von 113 kDa kodiert. Das SmRpoT-Gen besteht aus 19 Exons und 18 Introns, die in ihren Positionen mit denen aus den Angiosperm- und Physcomitrella-Genen konserviert sind. Mittels Southernblot-Analyse wurde nachgewiesen, dass S. moellendorffii ein single-copy RpoT-Gen kodiert. Für das N-terminale Transitpeptid von SmRpoT konnte gezeigt werden, dass es bei transienter Expression in Arabidopsis- und Selaginella-Protoplasten den Transport von GFP (green fluorescent protein) exclusiv in Mitochondrien vermittelt. In N. advena wurden mittels Screening einer BAC-Bibliothek drei RpoT-Gene identifiziert. Sowohl die genomischen als auch die cDNA-Sequenzen wurden aufgeklärt. Die NaRpoT-mRNAs kodieren putative Polypeptide von 996, 990 und 985 Aminosären. Alle drei Gene besitzen 19 Exons und 18 Introns, die in ihren Positionen mit denen der RpoT-Gene aus Selaginella und allen anderen Landpflanzen konserviert sind. Die kodierten Proteine weisen auf Aminosäureebene einen hohen Konservierungsgrad auf, einschließlich aller essentiellen Regionen und Aminosäurereste, die für die T7-RNAP bekannt sind. Die N-terminalen Transitpeptide zweier der kodierten RNAP, NaRpoTm1 und NaRpoTm2, vermittelten den Import von GFP exclusiv in Mitochondrien, während die dritte Polymerase, NaRpoTp, in Chloroplasten importiert wurde. Interessanterweise muß die Translation der NaRpoTp-mRNA an einem CUG-Codon initiiert werden, um ein funktionelles Protein mit plastidärem Transitpeptid zu erhalten. Die N. advena RpoTp-RNAP ist somit neben AGAMOUS aus Arabidopsis und der RpoTp-RNAP aus Nicotiana, ein weiteres Beispiel für jene selten vorkommenden pflanzlichen mRNAs, deren Translation exclusiv an nicht-AUG-Codons initiiert wird. Die Rekonstruktion von phylogenetischen Bäumen resultierte in unterschiedlichen Positionen für die Selaginella- und Nuphar-Polymerasen: Im Gegensatz zu der RpoT-Polymerase aus S. moellendorffii und denen aus Physcomitrella, die in den phylogenetischen Analysen Schwesterpositionen zu allen anderen Phagentyp-RNAP der Angiospermen einnehmen, clusterten die Nuphar-RpoTs zusammen mit den deutlich separierten mitochondrialen (NaRpoTm1 und NaRpoTm2) und plastidären (NaRpoTp) Polymerasen. Selaginella kodiert eine einzige mitochondriale RNAP, während Nuphar zwei mitochondriale und eine plastidäre RNAP besitzt. Die Identifizierung einer Plastiden-lokalisierten Phagentyp-RNAP in diesem basalen Eudikotylen, die ortholog zu allen anderen RpoT-Enzymen der Blütenpflanzen ist, läßt darauf schließen, daß die Acquisition einer nukleär kodierten plastidären RNAP, die noch in den Lycopoden fehlt, nach der Trennung der Leucopoden von allen anderen Tracheophyten erfolgte. Eine “dual-targeting” RNAP (mitochondrial und plastidär lokalisiert), wie sie in Eudikotylen, nicht jedoch in Monokotylen vorkommt, wurde weder in Selaginella noch in Nuphar nachgewiesen, vermutlich ist sie ein evolutionäres Novum von eudikotylen Pflanzen wie Arabidopsis.In mono- and eudicot plants, a small nuclear gene family (RpoT, RNA polymerase of the T3/T7 type) encodes mitochondrial as well as chloroplast RNA polymerases homologous to the T-odd bacteriophage enzymes. RpoT genes from angiosperms are well characterized, whereas data from deeper branching plant species until recently were limited to the moss Physcomitrella. To elucidate the molecular evolution of the RpoT polymerases in the plant kingdom and to get more insight into the potential importance of having more than one phage-type RNA polymerase (RNAP) available, we identified and characterized RpoT genes in the lycophyte Selaginella moellendorffii and the basal eudicot Nuphar advena. Selaginella moellendorffii (spikemoss) sequence trace data encoding a polypeptide highly similar to angiosperm and moss phage-type organelle RNA polymerases were used to isolate a BAC clone containing the full-length gene SmRpoT as well as the corresponding cDNA. The SmRpoT mRNA comprises 3452 nt with an open reading frame of 3,006 nt, encoding a putative protein of 1,002 amino acids with a molecular mass of 113 kDa. The SmRpoT gene comprises 19 exons and 18 introns, conserved in their position with those of the angiosperm and Physcomitrella RpoT genes. Using Southern blot analysis, it was shown that S. moellendorffii encodes a single RpoT gene. The N-terminal transit peptide of SmRpoT was shown to confer targeting of green fluorescent protein (GFP) exclusively to mitochondria after transient expression in Arabidopsis and Selaginella protoplasts. In Nuphar advena three RpoT genes were identified by BAC library screening. Both genomic gene sequences and full-length cDNAs were determined. The NaRpoT mRNAs specify putative polypeptides of 996, 990 and 985 amino acids, respectively. All three genes comprise 19 exons and 18 introns, conserved in their positions with those from S. moellendorffii and the RpoT genes of other land plants. The encoded proteins show a high degree of conservation at the amino acid sequence level, including all functional crucial regions and residues known from the phage T7 RNAP. The N-terminal transit peptides of two of the encoded polymerases, NaRpoTm1 and NaRpoTm2, conferred targeting of GFP exclusively to mitochondria, whereas the third polymerase, NaRpoTp, was targeted to chloroplasts. Remarkably, translation of NaRpoTp mRNA has to be initiated at a CUG codon to generate a functional plastid transit peptide. Thus, besides AGAMOUS in Arabidopsis and the Nicotiana RpoTp polymerase, N. advena RpoTp provides another example for a plant mRNA that is exclusively translated from a non-AUG codon. Reconstruction of phylogenetic trees revealed different positions of the RpoTs from the lycophyte Selaginella and the basal eudicot Nuphar. In contrast to the RpoTs of S. moellendorffii and those of the moss Physcomitrella, which are according to the phylogenetic analyses in sister positions to all other phage-type polymerases of angiosperms, the Nuphar RpoTs clustered with the well separated clades of mitochondrial (NaRpoTm1 and NaRpoTm2) and plastid (NaRpoTp) polymerases. Selaginella encodes a single mitochondrial RNAP, whereas Nuphar harbors two mitochondrial and one plastid phage-type polymerases. Identification of a plastid localized phage-type RNAP in this basal eudicot, orthologous to all other RpoTp enzymes of flowering plants, suggests that the acquisition of a nuclear encoded plastid RNA polymerase, not present in lycopods, took place after the split of lycopods from all other tracheophytes. A dual-targeted mitochondrial and plastid RNA polymerase (RpoTmp), as present in eudicots but not monocots, was not detected in Nuphar or Selaginella suggesting that its occurrence is an evolutionary novelty of eudicotyledoneous plants like Arabidopsis