Characterization of CoCas9 nuclease from Capnocytophaga ochracea.

Cas9 nucleases are widely used for genome editing and engineering. Cas9 enzymes encoded by CRISPR-Cas defence systems of various prokaryotic organisms possess different properties such as target site preferences, size, and DNA cleavage efficiency. Here, we biochemically characterized CoCas9 from Capnocytophaga ochracea, a bacterium that inhabits the oral cavity of humans and contributes to plaque formation on teeth. CoCas9 recognizes a novel 5'-NRRWC-3' PAM and efficiently cleaves DNA in vitro. Functional characterization of CoCas9 opens ways for genetic engineering of C. ochracea using its endogenous CRISPR-Cas system. The novel PAM requirement makes CoCas9 potentially useful in genome editing applications.

[Type II CRISPR-Cas System Nucleases: A Pipeline for Prediction and In Vitro Characterization].

The use of CRISPR-Cas bacterial adaptive immunity system components for targeted DNA changes has opened broad prospects for programmable genome editing of higher organisms. The most widely used gene editors are based on the Cas9 effectors of the type II CRISPR-Cas systems. In complex with guide RNAs, Cas9 proteins are able to directionally introduce double-stranded breaks into DNA regions that are complementary to guide RNA sequences. Despite the wide range of characterized Cas9s, the search for new Cas9 variants remains an important task, since the available Cas9 editors have several limitations. This paper presents a workflow for the search for and subsequent characterization of new Cas9 nucleases developed in our laboratory. Detailed protocols describing the bioinformatical search, cloning, and isolation of recombinant Cas9 proteins, testing for the presence of nuclease activity in vitro, and determining the PAM sequence, which is required for recognition of DNA targets, are presented. Potential difficulties that may arise, as well as ways to overcome them, are considered.

[Editing of Phage Genomes - Recombineering-Assisted SpCas9 Modification of Model Coliphages T7, T5, and T3].

Bacteriophages-viruses that infect bacterial cells - are the most abundant biological entities on Earth. The use of phages in fundamental research and industry requires tools for precise manipulation of their genomes. Yet, compared to bacterial genome engineering, modification of phage genomes is challenging because of the lack of selective markers and thus requires laborious screenings of recombinant/mutated phage variants. The development of the CRISPR-Cas technologies allowed to solve this issue by the implementation of negative selection that eliminates the parental phage genomes. In this manuscript, we summarize current methods of phage genome engineering and their coupling with CRISPR-Cas technologies. We also provide examples of our successful application of these methods for introduction of specific insertions, deletions, and point mutations in the genomes of model Escherichia coli lytic phages T7, T5, and T3.

[Repair of Double-Stranded DNA Breaks Generated by CRISPR-Cas9 in Pseudomonas putida KT2440].

Pseudomonas putida KT2440 is a metabolically versatile bacterium with considerable promise as a chassis strain for production and degradation of complex organic compounds. Unlike most bacteria, P. putida KT2440 encodes the Ku and LigD proteins involved in Non-Homologous End Joining (NHEJ). This pathway of repair of double-strand breaks (DSBs) in DNA has an intrinsic mutagenic potential that could be exploited in combination with currently available genome editing tools that generate programmable DSBs. Here, we investigated the effect of removal or overproduction of NHEJ-associated P. putida KT2440 enzymes on mutations generated upon repair of Cas9-mediated DSBs with the double purpose of characterizing the NHEJ pathway and investigating how it functionally interacts with the current gold standard tool for gene editing. The results of our work shed light on non-templated mechanisms of DSB repair in P. putida KT2440, an information that will serve as foundation to expand the gene engineering toolbox for this important microorganism.

Diversity and Functions of Type II Topoisomerases.

The DNA double helix provides a simple and elegant way to store and copy genetic information. However, the processes requiring the DNA helix strands separation, such as transcription and replication, induce a topological side-effect - supercoiling of the molecule. Topoisomerases comprise a specific group of enzymes that disentangle the topological challenges associated with DNA supercoiling. They relax DNA supercoils and resolve catenanes and knots. Here, we review the catalytic cycles, evolution, diversity, and functional roles of type II topoisomerases in organisms from all domains of life, as well as viruses and other mobile genetic elements.

Diversity of CRISPR-Cas-Mediated Mechanisms of Adaptive Immunity in Prokaryotes and Their Application in Biotechnology.

CRISPR-Cas systems of adaptive immunity in prokaryotes consist of CRISPR arrays (clusters of short repeated genomic DNA fragments separated by unique spacer sequences) and cas (CRISPR-associated) genes that provide cells with resistance against bacteriophages and plasmids containing protospacers, i.e. sequences complementary to CRISPR array spacers. CRISPR-Cas systems are responsible for two different cellular phenomena: CRISPR adaptation and CRISPR interference. CRISPR adaptation is cell genome modification by integration of new spacers that represents a unique case of Lamarckian inheritance. CRISPR interference involves specific recognition of protospacers in foreign DNA followed by introduction of breaks into this DNA and its destruction. According to the mechanisms of action, CRISPR-Cas systems have been subdivided into two classes, five types, and numerous subtypes. The development of techniques based on CRISPR interference mediated by the Type II system Cas9 protein has revolutionized the field of genome editing because it allows selective, efficient, and relatively simple introduction of directed breaks into target DNA loci. However, practical applications of CRISPR-Cas systems are not limited only to genome editing. In this review, we focus on the variety of CRISPR interference and CRISPR adaptation mechanisms and their prospective use in biotechnology.

[Mechanisms of action of RNA polymerase-binding transcription factors that do not bind to DNA].

The mechanism of the regulation of gene expression, a constantly expanding area of research, has been studied. DNA-dependent RNA polymerase is the enzyme of transcription, the first stage of gene expression, and a major target of regulation. (Most transcription factors interact with DNA). A class of transcription factors, including the prokaryotic proteins GreA, GreB, Gfh1, Rnk, DksA, and TraR and eukaryotic TFIIS, that do not bind DNA but directly interact wth RNA polymerase have been considered. Upon binding to RNAP polymerase, these factors reach out to the RNA polymerase catalitic center through the enzyme secondary channel and modulte the catalytic center activity. GreA, GreB, and TFIIS act by stimulating the intrinsic endonucleolytic cleavage activity of RNA polymerase catalytic center. This activity promotes RNA polymerase read-through through transcription pauses and arrest sites. The biochemical activities of other factors of these class are less clear. In this work, the data that accumulated during the last 15 years of research on this exciting group of factors are reviewed.

[Regulation of gene expression in type II restriction-modification system].

Type II restriction-modification systems are comprised of a restriction endonuclease and methyltransferase. The enzymes are coded by individual genes and recognize the same DNA sequence. Endonuclease makes a double-stranded break in the recognition site, and methyltransferase covalently modifies the DNA bases within the recognition site, thereby down-regulating endonuclease activity. Coordinated action of these enzymes plays a role of primitive immune system and protects bacterial host cell from the invasion of foreign (for example, viral) DNA. However, uncontrolled expression of the restriction-modification system genes can result in the death of bacterial host cell because of the endonuclease cleavage of host DNA. In the present review, the data on the expression regulation of the type II restriction-modification enzymes are discussed.

RNA polymerase -the third class of primases.

Multisubunit RNA polymerase transcribes DNA in all living organisms. RNA polymerase is also known to synthesize DNA replication primers in some replication systems, a function that is commonly performed by primases. There are two unrelated types of primases, the bacterial and eukaryal-archaeal types; RNA polymerase has no evolutionary relationship to either type. Here we discuss the mechanism of primer synthesis by RNA polymerase and compare it to mechanisms used by primases of both types as well as to the mechanisms used by RNA polymerase during transcription.

[Bacillus cereus pore-forming toxins hemolysin II and cytotoxin K: polymorphism and distribution of genes among representatives of the cereus group].

Abstract-Phylogenetic interrelation between 40 strains of the Bacillus cereus group has been established using BcREP fingerprinting. The PCR method has shown that the frequency of occurrence of the genes of cytotoxin K (cytK) and hemolysin II (hlyII) is 61% and 56%, respectively, and the gene of the hemolysin II regulator (hlyIIR) occurs together with hlyII. Comparison of the results of fingerprinting, PCR, and RFLP of the toxin genes showed that bacteria with the hlyII+ and cytK+ genotypes did not form separate clusters. However, microorganisms with the similar fingerprints were shown to have toxin genes of the same type. The proposed variant of RFLP analysis made it possible to clearly distinguish between the cytK1 and cytK2 genes. Twenty-three strains having the cytK genes carried no cytK1 dangerous for mammals. Additionally, the entire collection of microorganisms was tested for the ability to grow at 4 degrees C. This property was revealed for five strains, which should most likely be classified as B. weihenstephanensis. Two of the five psychrotolerant microorganisms carried the hemolysin II gene variant of the same type according to RFLP. None of the five strains had the cytK gene. These strains did not form close groups upon clustering by the applied method of Bc-REP fingerprints.

[Interactions of DNA-dependent bacterial RNA polymerase with promoters].

Transcription initiation is the most regulated stage of the transcription cycle that directly affects the overall level of gene expression. In bacteria, recognition of promoters by RNA polymerase is controlled by the a subunit. Recent structural analysis of RNA polymerase and its complexes with nucleic acids reveals that distinct structural domains of the RNA polymerase core enzyme are close to or contact promoter DNA, suggesting that they too may participate in promoter recognition and control promoter complex stability and activity. In this review, the data from our laboratory that highlight the role of RNA polymerase core-enzyme in promoter recognition is discussed.

[Low-molecular weight inhibitors of bacterial DNA-dependent RNA polymerase].

In this review, current data on low molecular weight inhibitors of bacterial RNA polymerases, both classical and those recently discovered, are summarised. This area has progressed rapidly in recent years largely due to availability of high-resolution structures of RNA polymerase and its complexes with inhibitors. The structural information, together with biochemical data, allows to understand molecular mechanisms of transcription inhibition by rifampicin, sorangicin, tagetitoxin, streptolydigin, and microcin J25. In its turn, the mechanistic understanding of the action of these inhibitors provides better understanding of transcription mechanism and RNA polymerase structure-function.

[Posttranslationally modified microcins].

Microcins are antibacterial compounds that are encoded in the bacterial genome and synthesized via ribosomal translation. Microcins play an important role in microbial ecology and are promising as antibiotics. To exert their effect, most microcins are incorporated in the membrane of sensitive cells to increase its permeability. The review considers the known classes of posttranslationally modified microcins. These microcins are unusual in structure and inhibit the grown of sensitive cells by entering their cytoplasm and affecting intracellular targets, such as DNA gyrase, DNA-dependent RNA polymerase, and aspartyl-tRNA synthase.

A regulator that inhibits transcription by targeting an intersubunit interaction of the RNA polymerase holoenzyme.

The structures of the bacterial RNA polymerase holoenzyme have provided detailed information about the intersubunit interactions within the holoenzyme. Functional analysis indicates that one of these is critical in enabling the holoenzyme to recognize the major class of bacterial promoters. It has been suggested that this interaction, involving the flap domain of the beta subunit and conserved region 4 of the sigma subunit, is a potential target for regulation. Here we provide genetic and biochemical evidence that the sigma region 4/beta-flap interaction is targeted by the transcription factor AsiA. Specifically, we show that AsiA competes directly with the beta-flap for binding to sigma region 4, thereby inhibiting transcription initiation by disrupting the sigma region 4/beta-flap interaction.

Binding of the initiation factor sigma(70) to core RNA polymerase is a multistep process.

The interaction of RNA polymerase and its initiation factors is central to the process of transcription initiation. To dissect the role of this interface, we undertook the identification of the contact sites between RNA polymerase and sigma(70), the Escherichia coli initiation factor. We identified nine mutationally verified interaction sites between sigma(70) and specific domains of RNA polymerase and provide evidence that sigma(70) and RNA polymerase interact in at least a two-step process. We propose that a cycle of changes in the interface of sigma(70) with core RNA polymerase is associated with progression through the process of transcription initiation.

Mapping the molecular interface between the sigma(70) subunit of E. coli RNA polymerase and T4 AsiA.

Bacteriophage T4 antisigma protein AsiA (10 kDa) orchestrates a switch from the host and early viral transcription to middle viral transcription by binding to the sigma(70) subunit of E. coli RNA polymerase. The molecular determinants of sigma(70)-AsiA complex formation are not known. Here, we used combinatorial peptide chemistry, protein-protein crosslinking, and mutational analysis to study the interaction between AsiA and its target, the 33 amino acid residues-long sigma(70) peptide containing conserved region 4.2. Many region 4.2 amino acid residues contact AsiA, which likely completely occludes the DNA-binding surface of region 4.2. Though none of region 4.2 amino acid residues is singularly responsible for the very tight interaction with AsiA, sigma(70) Lys593 and Arg596 which lie outside the putative DNA recognition element of region 4.2, contribute the most. In AsiA, the first 20 amino acid residues are both necessary and sufficient for interactions with sigma(70). Our results clarify details of sigma(70)-AsiA interaction and open the way for engineering AsiA derivatives with altered specificities.

The beta ' subunit of Escherichia coli RNA polymerase is not required for interaction with initiating nucleotide but is necessary for interaction with rifampicin.

Using a modification of a highly selective affinity labeling protocol, we demonstrated that the alpha(2)beta subassembly of Escherichia coli RNA polymerase efficiently and specifically interacts with the initiating purine nucleotide. Isolated beta is also active in this reaction. In contrast, neither beta nor alpha(2)beta is able to interact with a chimeric molecule composed of rifampicin attached to an initiation substrate. Based on these results, we conclude that the RNA polymerase initiation site, specific for purine nucleotides, which ultimately become the 5'-end of the transcript, is essentially complete in the absence of the largest subunit, beta'. However, the rifampicin binding center is formed only in the alpha(2)betabeta' core enzyme. We interpret our results in light of the high resolution structure of core RNA polymerase from Thermus aquaticus.

Bacterial RNA polymerase subunit omega and eukaryotic RNA polymerase subunit RPB6 are sequence, structural, and functional homologs and promote RNA polymerase assembly.

Bacterial DNA-dependent RNA polymerase (RNAP) has subunit composition beta'betaalpha(I)alpha(II)omega. The role of omega has been unclear. We show that omega is homologous in sequence and structure to RPB6, an essential subunit shared in eukaryotic RNAP I, II, and III. In Escherichia coli, overproduction of omega suppresses the assembly defect caused by substitution of residue 1362 of the largest subunit of RNAP, beta'. In yeast, overproduction of RPB6 suppresses the assembly defect caused by the equivalent substitution in the largest subunit of RNAP II, RPB1. High-resolution structural analysis of the omega-beta' interface in bacterial RNAP, and comparison with the RPB6-RPB1 interface in yeast RNAP II, confirms the structural relationship and suggests a "latching" mechanism for the role of omega and RPB6 in promoting RNAP assembly.

Recombinant Thermus aquaticus RNA polymerase, a new tool for structure-based analysis of transcription.

The three-dimensional structure of DNA-dependent RNA polymerase (RNAP) from thermophilic Thermus aquaticus has recently been determined at 3.3 A resolution. Currently, very little is known about T. aquaticus transcription and no genetic system to study T. aquaticus RNAP genes is available. To overcome these limitations, we cloned and overexpressed T. aquaticus RNAP genes in Escherichia coli. Overproduced T. aquaticus RNAP subunits assembled into functional RNAP in vitro and in vivo when coexpressed in E. coli. We used the recombinant T. aquaticus enzyme to demonstrate that transcription initiation, transcription termination, and transcription cleavage assays developed for E. coli RNAP can be adapted to study T. aquaticus transcription. However, T. aquaticus RNAP differs from the prototypical E. coli enzyme in several important ways: it terminates transcription less efficiently, has exceptionally high rate of intrinsic transcript cleavage, and is highly resistant to rifampin. Our results, together with the high-resolution structural information, should now allow a rational analysis of transcription mechanism by mutation.