Mechanisms by which T7 lysozyme specifically regulates T7 RNA polymerase during different phases of transcription

Transcriptomics-Driven Characterization of LUZ100, a T7-like Pseudomonas Phage with Temperate Features

Autographiviridae is a diverse yet distinct family of bacterial viruses marked by a strictly lytic lifestyle and a generally conserved genome organization. Here, we characterized Pseudomonas aeruginosa phage LUZ100, a distant relative of type phage T7. LUZ100 is a podovirus with a limited host range which likely uses lipopolysaccharide (LPS) as a phage receptor. Interestingly, infection dynamics of LUZ100 indicated moderate adsorption rates and low virulence, hinting at temperate characteristics. This hypothesis was supported by genomic analysis, which showed that LUZ100 shares the conventional T7-like genome organization yet carries key genes associated with a temperate lifestyle. To unravel the peculiar characteristics of LUZ100, ONT-cappable-seq transcriptomics analysis was performed. These data provided a bird's-eye view of the LUZ100 transcriptome and enabled the discovery of key regulatory elements, antisense RNA, and transcriptional unit structures. The transcriptional map of LUZ100 also allowed us to identify new RNA polymerase (RNAP)-promoter pairs that can form the basis for biotechnological parts and tools for new synthetic transcription regulation circuitry. The ONT-cappable-seq data revealed that the LUZ100 integrase and a MarR-like regulator (proposed to be involved in the lytic/lysogeny decision) are actively cotranscribed in an operon. In addition, the presence of a phage-specific promoter transcribing the phage-encoded RNA polymerase raises questions on the regulation of this polymerase and suggests that it is interwoven with the MarR-based regulation. This transcriptomics-driven characterization of LUZ100 supports recent evidence that T7-like phages should not automatically be assumed to have a strictly lytic life cycle. IMPORTANCE Bacteriophage T7, considered the "model phage" of the Autographiviridae family, is marked by a strictly lytic life cycle and conserved genome organization. Recently, novel phages within this clade have emerged which display characteristics associated with a temperate life cycle. Screening for temperate behavior is of utmost importance in fields like phage therapy, where strictly lytic phages are generally required for therapeutic applications. In this study, we applied an omics-driven approach to characterize the T7-like Pseudomonas aeruginosa phage LUZ100. These results led to the identification of actively transcribed lysogeny-associated genes in the phage genome, pointing out that temperate T7-like phages are emerging more frequent than initially thought. In short, the combination of genomics and transcriptomics allowed us to obtain a better understanding of the biology of nonmodel Autographiviridae phages, which can be used to optimize the implementation of phages and their regulatory elements in phage therapy and biotechnological applications, respectively.

Strategies for efficient production of recombinant proteins in Escherichia coli: alleviating the host burden and enhancing protein activity

Escherichia coli, one of the most efficient expression hosts for recombinant proteins (RPs), is widely used in chemical, medical, food and other industries. However, conventional expression strains are unable to effectively express proteins with complex structures or toxicity. The key to solving this problem is to alleviate the host burden associated with protein overproduction and to enhance the ability to accurately fold and modify RPs at high expression levels. Here, we summarize the recently developed optimization strategies for the high-level production of RPs from the two aspects of host burden and protein activity. The aim is to maximize the ability of researchers to quickly select an appropriate optimization strategy for improving the production of RPs.

Cloning, overexpression, purification, characterization and structural modelling of a metabolically active Fe2+ dependent 2,6-dichloro-p-hydroquinone 1,2-dioxygenase (CpsA) from Bacillus cereus strain AOA-CPS_1

2,6-Dichloro-p-hydroquinone (DiCHQ) aromatic-ring cleavage by DiCHQ 1,2-dioxygenase (CpsA) is very crucial for complete transformation of pentachlorophenol (PCP) to 2-chloromaleylacetate in Bacillus cereus AOA-CPS_1 (BcAOA). The 978 bp gene (cpsA) was detected and amplified in the genome of BcAOA; cloned, overexpressed and purified to homogeneity. CpsA showed a single ≅36.9 kDa protein band on SDS-PAGE and exhibited optimum activity at 30 °C and pH 9.0. CpsA was stable between 20 °C and 40 °C, and also retained about 90% of its activity at 60 °C for 120 min. The enzyme retained about 90% activity between pH 9.0 and 11.5 and 60% activity at pH 13.0. CpsA was found to be Fe²⁺ dependent as about 90% increased activity was observed in the presence of FeSO₄. CpsA showed apparent v_max, K_m, k_cat and k_cat/K_m of 27.77 ± 0.9 μMs^-1, 0.990 ± 0.03 mM, 4.20 ± 0.04 s^-1 and 4.24 ± 0.03 s^-1 mM^-1, respectively at pH 9.0. Analysis of the reaction products via GC-MS confirmed 2-chloromaleylacetate as the ring-cleavage product. CpsA 3D structure revealed a conserved 2-His-1-carboxylate facial triad motif (His 9, His 244 and Thr 11), with Fe³⁺ at the centre. Findings from this study provide new insights into the involvement of this enzyme in PCP degradation and suggests alternate possible mechanism of ring-cleavage by dioxygenases.

Chloroacetaldehyde dehydrogenase from Ancylobacter aquaticus UV5: Cloning, expression, characterization and molecular modeling

1,2-Dichloroethane (1,2-DCE) is oxidatively converted to a carcinogenic intermediate compound, chloroacetaldehyde by chloroacetaldehyde dehydrogenase (CAldA) during its biodegradation by many bacterial strains, including Xanthobacter autotrophicus and Ancylobacter aquaticus. In this study, a 55kDa NAD-dependent CAldA expressed by chromosomally encoded aldA gene, is reported in an indigenous Ancylobacter aquaticus UV5. A. aquaticus UV5 aldA gene was found to be 99% homologous to the plasmid (pXAU1) encoded aldA gene reported in X. autotrophicus GJ10. Pulse-field gel electrophoresis (PFGE) and PCR experiments revealed the absence of pXAU1 in A. aquaticus UV5 and that aldA was chromosomal encoded. A 6× His-tag fused CAldA cloned in pET15b, overexpressed and purified on Co-agarose affinity column using AKTA purification system showed M_r of 57,526. CAldA was active optimally at pH9 and 30°C. The K_m and v_max for the substrate, acetaldehyde were found to be 115μM and 650mU/mg, respectively. CAldA substrate specificity was found to be low for chloroacetaldehyde, formaldehyde, propionaldehyde, butyraldehyde, benzaldehyde and glutaraldehyde as compared to acetaldehyde. Computational modeling revealed a predicted structure of CAldA consisting of five β-sheets that comprise seven antiparallel β-strands and 11 mix strands. The Molecular Dynamics and Docking studies showed that acetaldehyde bind to CaldA more tightly as compared to chloroacetaldehyde.

Bacteriophage protein-protein interactions

Bacteriophages T7, λ, P22, and P2/P4 (from Escherichia coli), as well as ϕ29 (from Bacillus subtilis), are among the best-studied bacterial viruses. This chapter summarizes published protein interaction data of intraviral protein interactions, as well as known phage-host protein interactions of these phages retrieved from the literature. We also review the published results of comprehensive protein interaction analyses of Pneumococcus phages Dp-1 and Cp-1, as well as coliphages λ and T7. For example, the ≈55 proteins encoded by the T7 genome are connected by ≈43 interactions with another ≈15 between the phage and its host. The chapter compiles published interactions for the well-studied phages λ (33 intra-phage/22 phage-host), P22 (38/9), P2/P4 (14/3), and ϕ29 (20/2). We discuss whether different interaction patterns reflect different phage lifestyles or whether they may be artifacts of sampling. Phages that infect the same host can interact with different host target proteins, as exemplified by E. coli phage λ and T7. Despite decades of intensive investigation, only a fraction of these phage interactomes are known. Technical limitations and a lack of depth in many studies explain the gaps in our knowledge. Strategies to complete current interactome maps are described. Although limited space precludes detailed overviews of phage molecular biology, this compilation will allow future studies to put interaction data into the context of phage biology.

Ribosome-inactivating proteins: from plant defense to tumor attack

Ribosome-inactivating proteins (RIPs) are EC3.2.32.22 N-glycosidases that recognize a universally conserved stem-loop structure in 23S/25S/28S rRNA, depurinating a single adenine (A4324 in rat) and irreversibly blocking protein translation, leading finally to cell death of intoxicated mammalian cells. Ricin, the plant RIP prototype that comprises a catalytic A subunit linked to a galactose-binding lectin B subunit to allow cell surface binding and toxin entry in most mammalian cells, shows a potency in the picomolar range. The most promising way to exploit plant RIPs as weapons against cancer cells is either by designing molecules in which the toxic domains are linked to selective tumor targeting domains or directly delivered as suicide genes for cancer gene therapy. Here, we will provide a comprehensive picture of plant RIPs and discuss successful designs and features of chimeric molecules having therapeutic potential.

Real-time observation of the transition from transcription initiation to elongation of the RNA polymerase

The transition from initiation to elongation of the RNA polymerase (RNAP) is an important stage of transcription that often limits the production of the full-length RNA. Little is known about the RNAP transition kinetics and the steps that dictate the transition rate, because of the challenge in monitoring subpopulations of the transient and heterogeneous transcribing complexes in rapid and real time. Here, we have dissected the complete transcription initiation pathway of T7 RNAP by using kinetic modeling of RNA synthesis and by determining the initiation (IC) to elongation (EC) transition kinetics at each RNA polymerization step using single-molecule and stopped-flow FRET methods. We show that the conversion of IC to EC in T7 RNAP consensus promoter occurs only after 8- to 12-nt synthesis, and the 12-nt synthesis represents a critical juncture in the transcriptional initiation pathway when EC formation is most efficient. We show that the slow steps of transcription initiation, including DNA scrunching/RNAP-promoter rotational changes during 5- to 8-nt synthesis, not the major conformational changes, dictate the overall rate of EC formation in T7 RNAP and represent key steps that regulate the synthesis of full-length RNA.

Folding in solution of the C-catalytic protein fragment of angiotensin-converting enzyme

Angiotensin-converting enzyme (ACE) is a key molecule of the renin-angiotensin-aldosterone system which is responsible for the control of blood pressure. For over 30 years it has become the target for fighting off hypertension. Many inhibitors of the enzyme have been synthesized and used widely in medicine despite the lack of ACE structure. The last 5 years the crystal structure of ACE separate domains has been revealed, but in order to understand how the enzyme works it is necessary to study its structure in solution. We present here the cloning, overexpression in Escherichia coli, purification and structural study of the Ala(959) to Ser(1066) region (ACE_C) that corresponds to the C-catalytic domain of human somatic angiotensin-I-converting enzyme. ACE_C was purified under denatured conditions and the yield was 6 mg/l of culture. Circular dichroism (CD) spectroscopy indicated that 1,1,1-trifluoroethanol (TFE) is necessary for the correct folding of the protein fragment. The described procedure can be used for the production of an isotopically labelled ACE(959-1066) protein fragment in order to study its structure in solution by NMR spectroscopy.

Design and implementation of three incoherent feed-forward motif based biological concentration sensors

Synthetic biology is a useful tool to investigate the dynamics of small biological networks and to assess our capacity to predict their behavior from computational models. In this work we report the construction of three different synthetic networks in Escherichia coli based upon the incoherent feed-forward loop architecture. The steady state behavior of the networks was investigated experimentally and computationally under different mutational regimes in a population based assay. Our data shows that the three incoherent feed-forward networks, using three different macromolecular inhibitory elements, reproduce the behavior predicted from our computational model. We also demonstrate that specific biological motifs can be designed to generate similar behavior using different components. In addition we show how it is possible to tune the behavior of the networks in a predicable manner by applying suitable mutations to the inhibitory elements.

Bi-functional activities of chimeric lysozymes constructed by domain swapping between bacteriophage T7 and K11 lysozymes

The lysozymes encoded by bacteriophage T7 and K11 are both bifunctional enzymes sharing an extensive sequence homology (75%). The constructions of chimeric lysozymes were carried out by swapping the N-terminal and C-terminal domains between phage T7 and K11 lysozymes. This technique generated two chimeras, T7K11-lysozyme (N-terminal T7 domain and C-terminal K11 domain) and K11T7-lysozyme (N-terminal K11 domain and C-terminal T7 domain), which are both enzymatically active. The amidase activity of T7K11-lysozyme is comparable with the parental enzymes while K11T7-lysozyme exhibits an activity that is approximately 45% greater than the wild-type lysozymes. Moreover, these chimeric constructs have optimum pH of 7.2-7.4 similar to the parental lysozymes but exhibit greater thermal stabilities. On the other hand, the chimeras inhibit transcription comparable with the parental lysozymes depending on the source of their N-terminals. Taken together, our results indicated that domain swapping technique localizes the N-terminal region as the domain responsible for the transcription inhibition specificity of the wild type T7 and K11 lysozymes. Furthermore, we were able to develop a simple and rapid purification scheme in purifying both the wild-type and chimeric lysozymes.

Sensitivity of the yeast mitochondrial RNA polymerase to +1 and +2 initiating nucleotides

Despite a simple consensus sequence, there is considerable variation of promoter strengths, transcription rates, and the kinetics of initiating nucleotide incorporation among the promoters found in the Saccharomyces cerevisiae mitochondrial genome. We asked how changes in the initiating (+1 and +2) nucleotides, conformation of the promoter DNA template, and mutation of the mitochondrial RNA polymerase (mtRNAP) affect the kinetics of nucleotide (NTP) utilization. Using a highly purified in vitro mitochondrial transcription system, we found that 1) the mtRNAP requires the highest concentrations of the +1 and +2 initiating NTPs, intermediate concentrations of NTPs at positions 5 to 11, and low concentrations of elongating NTPs; 2) the mtRNAP requires a higher concentration of the +2 NTP than the +1 NTP for initiation; 3) the kinetics of +2 NTP utilization are altered by a point mutation in the mtRNAP subunit Mtf1; and 4) a supercoiled or pre-melted promoter DNA template restores normal +2 NTP utilization by the Mtf1 mutant. Based on comparisons to the structural and biochemical properties of the bacterial RNAP and the closely related T7 RNAP, we propose that initiating nucleotides, particularly the +2 NTP, are required at high concentrations to drive mitochondrial promoter opening or to stabilize a productive open complex.

Mitochondrial transcription is regulated via an ATP "sensing" mechanism that couples RNA abundance to respiration

The information encoded in both the nuclear and mitochondrial genomes must be coordinately regulated to respond to changes in cellular growth and energy states. Despite identification of the mitochondrial RNA polymerase (mtRNAP) from several organisms, little is known about mitochondrial transcriptional regulation. Studying the shift from fermentation to respiration in Saccharomyces cerevisiae, we have demonstrated a direct correlation between in vivo changes in mitochondrial transcript abundance and in vitro sensitivity of mitochondrial promoters to ATP concentration (K(m)ATP). Consistent with the idea that the mtRNAP itself senses in vivo ATP levels, we found that transcript abundance correlates with respiration, but only when coupled to mitochondrial ATP synthesis. In addition, we characterized mutations in the mitochondrial promoter and the mtRNAP accessory factor Mtf1 that alter both in vitro K(m)ATP and in vivo transcription in response to respiratory changes. We propose that shifting cellular pools of ATP coordinately control nuclear and mitochondrial transcription.

Translocation by T7 RNA polymerase: a sensitively poised Brownian ratchet

Studies of halted T7 RNA polymerase (T7RNAP) elongation complexes (ECs) or of T7RNAP transcription against roadblocks due to DNA-bound proteins indicate that T7RNAP translocates via a passive Brownian ratchet mechanism. Crystal structures of T7RNAP ECs suggest that translocation involves an active power-stroke. However, neither solution studies of halted or slowed T7RNAP ECs, nor crystal structures of static complexes, are necessarily relevant to how T7RNAP translocates during rapid elongation. A recent single molecule study of actively elongating T7RNAPs provides support for the Brownian ratchet mechanism. Here, we obtain additional evidence for the existence of a Brownian ratchet during active T7RNAP elongation by showing that both rapidly elongating and halted complexes are equally sensitive to pyrophosphate. Using chemical nucleases tethered to the polymerase we achieve sub-ångström resolution in measuring the average position of halted T7RNAP ECs and find that the positional equilibrium of the EC is sensitively poised between pre-translocated and post-translocated states. This may be important in maximizing the sensitivity of the polymerase to sequences that cause pausing or termination. We also confirm that a crystallographically observed disorder to order transition in a loop formed by residues 589-612 also occurs in solution and is coupled to pyrophosphate or NTP release. This transition allows the loop to make interactions with the DNA that help stabilize the laterally mobile, ligand-free EC against dissociation.

Esterified whey proteins can protect Lactococcus lactis against bacteriophage infection. Comparison with the effect of native basic proteins and L-polylysines

Inhibitory action of basic esterified milk whey proteins [methylated (Met) or ethylated (Et) beta-lactoglobulin (BLG) and alpha-lactalbumin (ALA)], basic native proteins (chicken egg white lysozyme and calf thymus histone), and basic protein-like substances (L-polylysines) against the activity and replication of lactococcal bacteriophages (bIL66, bIL67, and bIL170) was tested. Chemical interactions of these proteins with phage DNA were determined as well as their protective effect on the growth of a laboratory plasmid-cured Lactococcus lactis subjected to an infection by the bacteriophages. All the proteins studied showed inhibitory activity against the three bacteriophages as tested by marked reduction of their lytic activities and decreasing the replication of studied phages. Histone and Met-BLG were more active toward bIL66 and bIL67, respectively, while both proteins were highly and equally active toward bIL170. Lysozyme showed lower antiviral activity. Antiviral activity of Et-BLG was a little bit lower than that observed in the case of the Met derivative. Esterified ALA also showed considerable but slightly lower antiviral activity as compared to other proteins. L-polylysines also showed an antiviral effect against the three bacteriophages studied, their influence being highly dependent on their molecular size. The best effective size of L-polylysines was in the range 15-70 kDa. Replication of bIL67 was inhibited by the presence of esterified ALA or BLG and native basic proteins. Complete inhibition of replication of bIL67 occurred when using polylysines with molecular masses in the ranges 4-15, 15-30, and 30-70 kDa, while protein-like substrates with lower molecular masses had only a slight effect. The presence of histone and Met-BLG at a concentration of 0.13 mg/mL in the incubation medium protected L. lactis against lysis when it was subjected to an infection by bIL67 (10(5) pfu/mL). The same action was achieved by l-polylysine (15-30 kDa) used at a concentration of 0.03 mg/mL in the incubation medium.

Nonessential genes of phage phiYeO3-12 include genes involved in adaptation to growth on Yersinia enterocolitica serotype O:3

Bacteriophage phiYeO3-12 is a T7/T3-related lytic phage that naturally infects Yersinia enterocolitica serotype O:3 strains by using the lipopolysaccharide O polysaccharide (O antigen) as its receptor. The phage genome is a 39,600-bp-long linear, double-stranded DNA molecule that contains 58 genes. The roles of many of the genes are currently unknown. To identify nonessential genes, the isolated phage DNA was subjected to MuA transposase-catalyzed in vitro transposon insertion mutagenesis with a lacZ' gene-containing reporter transposon. Following electroporation into Escherichia coli DH10B and subsequent infection of E. coli JM109/pAY100, a strain that expresses the Y. enterocolitica O:3 O antigen on its surface, mutant phage clones were identified by their beta-galactosidase activity, manifested as a blue color on indicator plates. Transposon insertions were mapped in a total of 11 genes located in the early and middle regions of the phage genome. All of the mutants had efficiencies of plating (EOPs) and fitnesses identical to those of the wild-type phage when grown on E. coli JM109/pAY100. However, certain mutants exhibited altered phenotypes when grown on Y. enterocolitica O:3. Transposon insertions in genes 0.3 to 0.7 decreased the EOP on Y. enterocolitica O:3, while the corresponding deletions did not, suggesting that the low EOP was not caused by inactivation of the genes per se. Instead, it was shown that in these mutants the low EOP was due to the delayed expression of gene 1, coding for RNA polymerase. On the other hand, inactivation of gene 1.3 or 3.5 by either transposon insertion or deletion decreased phage fitness when grown on Y. enterocolitica. These results indicate that phiYeO3-12 has adapted to utilize Y. enterocolitica as its host and that these adaptations include the products of genes 1.3 and 3.5, DNA ligase and lysozyme, respectively.

Multiple Roles of T7 RNA Polymerase and T7 Lysozyme During Bacteriophage T7 Infection

T7 RNA polymerase selectively transcribes T7 genes during infection but is also involved in DNA replication, maturation and packaging. T7 lysozyme is an amidase that cuts a bond in the peptidoglycan layer of the cell wall, but it also binds T7 RNA polymerase and inhibits transcription, and it stimulates replication and packaging of T7 DNA. To better understand the roles of these two proteins during T7 infection, mutants of each were constructed or selected and their biochemical and physiological behavior analyzed. The amidase activity of lysozyme is needed for abrupt lysis and release of phage particles but appears to have no role in replication and packaging. The interaction between polymerase and lysozyme stimulates both replication and packaging. Polymerase mutants that gain the ability to grow normally in the absence of an interaction with lysozyme still fail to shut down late transcription and, remarkably, have become hypersensitive to inhibition when lysozyme is able to bind. These lysozyme-hypersensitive polymerases behave without lysozyme similarly to wild-type polymerase with lysozyme: both remain longer at the promoter before establishing a lysozyme-resistant elongation complex and both increase the length of pausing when elongation complexes encounter an eight-base recognition sequence involved in DNA packaging. Replication origins contain T7 promoters, but the role of T7 RNA polymerase in initiating replication is not understood well enough to more than speculate how the lysozyme-polymerase interaction stimulates replication. Maturation and packaging is apparently initiated through interaction between prohead-terminase complexes and transcription elongation complexes paused at the sequence TATCTGT(T/A), well conserved at the right-end of the concatemer junction of T7-like phages. A model that is consistent with the structure of an elongation complex and a large body of mutational and biochemical data is proposed to explain sequence-specific pausing and potential termination at the consensus recognition sequence (C/T)ATCTGT(T/A).

T7 Lysozyme Represses T7 RNA Polymerase Transcription by Destabilizing the Open Complex during Initiation

Bacteriophage T7 lysozyme binds to T7 RNA polymerase and inhibits transcription initiation and the transition from initiation to elongation. We have investigated each step of transcription initiation to determine where T7 lysozyme has the most effect. Stopped flow and equilibrium DNA binding studies indicate that T7 lysozyme does not inhibit the formation of the preinitiation open complex (open complex in the absence of initiating nucleotide). T7 lysozyme, however, does prevent the formation of a fully open initiation complex (open complex in the presence of the initiating nucleotide). This is consistent with the results that in the presence of T7 lysozyme the rate of G ladder RNA synthesis is about 5-fold slower and the GTP Kd is about 2-fold higher, but T7 lysozyme does not inhibit the initial rate of RNA synthesis with a premelted bulge-6 promoter (bubble from -4 to +2). Neither the RNA synthesis rate nor the extent of promoter opening is restored by increasing the initiating nucleotide concentration, indicating that T7 lysozyme represses transcription by interfering with the formation of a stable and a fully open initiation bubble or by altering the structure of the DNA in the initiation complex. As a consequence of the unstable initiation bubble and/or the inhibition of the conformational changes in the N-terminal domain of T7 RNAP, T7 lysozyme causes an increased production of abortive products from 2- to 5-mer that delays the transition from the initiation to the elongation phase.

Genomic Analysis of Bacteriophages SP6 and K1-5, an Estranged Subgroup of the T7 Supergroup

We have determined the genome sequences of two closely related lytic bacteriophages, SP6 and K1-5, which infect Salmonella typhimurium LT2 and Escherichia coli serotypes K1 and K5, respectively. The genome organization of these phages is almost identical with the notable exception of the tail fiber genes that confer the different host specificities. The two phages have diverged extensively at the nucleotide level but they are still more closely related to each other than either is to any other phage currently characterized. The SP6 and K1-5 genomes contain, respectively, 43,769 bp and 44,385 bp, with 174 bp and 234 bp direct terminal repeats. About half of the 105 putative open reading frames in the two genomes combined show no significant similarity to database proteins with a known or predicted function that is obviously beneficial for growth of a bacteriophage. The overall genome organization of SP6 and K1-5 is comparable to that of the T7 group of phages, although the specific order of genes coding for DNA metabolism functions has not been conserved. Low levels of nucleotide similarity between genomes in the T7 and SP6 groups suggest that they diverged a long time ago but, on the basis of this conservation of genome organization, they are expected to have retained similar developmental strategies.

A Mutation in the Yeast Mitochondrial Core RNA Polymerase, Rpo41, Confers Defects in Both Specificity Factor Interaction and Promoter Utilization

The yeast mitochondrial RNA polymerase (RNAP) is composed of the core RNAP, Rpo41, and the mitochondrial transcription factor, Mtf1. Both are required for mitochondrial transcription, but how the two proteins interact to create a functional, promoter-selective holoenzyme is still unknown. Rpo41 is similar to the single polypeptide bacteriophage T7RNAP, which does not require additional factors for promoter-selective initiation but whose activity is modulated during infection by association with T7 lysozyme. In this study we used the co-crystal structure of T7RNAP and T7 lysozyme as a model to define a potential Mtf1 interaction surface on Rpo41, making site-directed mutations in Rpo41 at positions predicted to reside at the same location as the T7RNAP/T7 lysozyme interface. We identified Rpo41 mutant E1224A as having reduced interactions with Mtf1 in a two-hybrid assay and a temperature-sensitive petite phenotype in vivo. Although the E1224A mutant has full activity in a non-selective in vitro transcription assay, it is temperature-sensitive for selective transcription from linear DNA templates containing the 14S rRNA, COX2, and tRNAcys mitochondrial promoters. The tRNAcys promoter defect can be rescued by template supercoiling but not by addition of a dinucleotide primer. The fact that mutation of Rpo41 results in selective transcription defects indicates that the core RNAP, like T7RNAP, plays an important role in promoter utilization.

Structural Basis for the Transition from Initiation to Elongation Transcription in T7 RNA Polymerase

To make messenger RNA transcripts, bacteriophage T7 RNA polymerase (T7 RNAP) undergoes a transition from an initiation phase, which only makes short RNA fragments, to a stable elongation phase. We have determined at 2.1 angstrom resolution the crystal structure of a T7 RNAP elongation complex with 30 base pairs of duplex DNA containing a "transcription bubble" interacting with a 17-nucleotide RNA transcript. The transition from an initiation to an elongation complex is accompanied by a major refolding of the amino-terminal 300 residues. This results in loss of the promoter binding site, facilitating promoter clearance, and creates a tunnel that surrounds the RNA transcript after it peels off a seven-base pair heteroduplex. Formation of the exit tunnel explains the enhanced processivity of the elongation complex. Downstream duplex DNA binds to the fingers domain, and its orientation relative to upstream DNA in the initiation complex implies an unwinding that could facilitate formation of the open promoter complex.

Structural transitions mediating transcription initiation by T7 RNA polymerase

During transcription initiation, RNA polymerases appear to retain promoter interactions while transcribing short RNAs that are frequently released from the complex. Upon transition to elongation, the polymerase releases promoter and forms a stable elongation complex. Little is known about the changes in polymerase conformation or polymerase:DNA interactions that occur during this process. To characterize the transitions that occur in the T7 RNA polymerase transcription complex during initiation, we prepared enzymes with Fe-BABE conjugated at 11 different positions. Addition of H(2)O(2) to transcription complexes prepared with these enzymes led to nucleic acid strand scission near the conjugate. Changes in the cleavage sites revealed a series of conformational changes and rearrangements of protein:nucleic acid contacts that mediate progression through the initiation reaction.

Kinetic and thermodynamic basis of promoter strength: multiple steps of transcription initiation by T7 RNA polymerase are modulated by the promoter sequence

Transcription initiation by T7 RNA polymerase (T7 RNAP) is regulated by the specific promoter DNA sequence that is classically divided into two major domains, the binding domain (-17 to -5) and the initiation domain (-4 to +6). The occurrence of non-consensus bases within these domains is responsible for the diversity of promoter strength, the basis of which was investigated by studying T7 promoters with changes in the promoter specificity region (-13 to -6) of the binding domain and/or the melting region (-4 to -1) of the initiation domain. The transient state kinetics and thermodynamic studies revealed that multiple steps in the pathway of transcription initiation are modulated by the promoter DNA sequence. Three base changes in the promoter specificity region at -11, -12, and -13, found in the natural phi 3.8 promoter, reduced the overall affinity of the T7 RNAP for the promoter DNA by 2-3-fold and decreased the rate of pppGpG synthesis, the first RNA product. Promoter opening is thermodynamically driven in T7 RNAP, and a single base change in the melting region (TATA to TAAA) decreased the extent of open complex generated at equilibrium. This base change in the melting region also increased the K(d) of (+1) GTP and the dissociation rate of pppGpG. Thus, transcription initiation at various T7 promoters is differentially regulated by initiating GTP concentration. The specificity and melting regions of T7 promoter DNA act both independently and synergistically to affect distinct steps of transcription initiation. Although each step in the initiation pathway is affected to a small degree by promoter sequence variations, the cumulative effect dictates the overall promoter strength.

T7 promoter release mediated by DNA scrunching

Transcription initiation includes a phase in which short transcripts dissociate from the transcription complex and the polymerase appears not to move away from the promoter. During this process DNA may scrunch within the complex or the polymerase may transiently break promoter contacts to transcribe downstream DNA. Promoter release allowing extended downstream movement of the polymerase may be caused by RNA-mediated disruption of promoter contacts, or by limits on the amount of DNA that can be scrunched. Using exonuclease and KMnO4 footprinting of T7RNAP transcription complexes we show that the DNA scrunches during progression through initial transcription. To determine whether promoter release is determined by RNA length or by the amount of DNA scrunched, we compared release at promoters where the polymerase is forced to initiate at +2 with those where it initiates at +1. For RNAs of identical length, release is greater when more DNA is scrunched. Release is inhibited when a nick introduced into the template relieves the strain of scrunching. DNA scrunching therefore makes an important contribution to T7 promoter release.

Sequence-specific termination by T7 RNA polymerase requires formation of paused conformation prior to the point of RNA release

BACKGROUND

The sequence-specific, hairpin-independent termination signal for the bacteriophage RNA polymerases in Escherichia coli rrnB t1 terminator consists of two modules. The upstream module includes the conserved sequence and the downstream one is U-rich.

RESULTS

Elongation complexes of T7 RNA polymerase paused 2 bp before reaching the termination site at a 500 microM concentration of NTP. At 5-50 microM NTP, however, they paused and terminated there or resumed elongation beyond the termination site. Only at higher concentrations of NTP (500 microM), the pause complex proceeded slowly to and became incompetent at the termination site. At 4 bp or more before the termination site, the unprotected single-stranded region of transcription bubble shrank at the trailing edge to 4-5 bp from approximately 10 bp, resulting from duplex formation of the conserved sequence. The pause and bubble collapse were not observed with an inactive mutant of the termination signal.

CONCLUSION

Sequence-specific termination requires the slow elongation mode of paused conformation, working only at high concentrations of NTP for a few bp prior to the RNA release site. The collapse of bubble that was observed several base pairs before the termination site and/or the resulting duplex might subsequently lead to the paused conformation of T7 elongation complexes.

Scanning mutagenesis reveals roles for helix n of the bacteriophage T7 RNA polymerase thumb subdomain in transcription complex stability, pausing, and termination

Deletions within the thumb subdomain (residues 335-408) of T7 RNA polymerase decrease elongation complex stability and processivity, but the structure of a T7RNAP initial transcription complex containing a 3-nucleotide RNA reveals no interactions between the thumb and the RNA or DNA. Modeling of a longer RNA in this structure, using a T7DNAP-primer-template structure as a guide, suggests that the phosphate ribose backbone of the RNA contacts a stretch of mostly positively charged side chains between residues 385 and 395 of helix N of the thumb. Scanning mutagenesis of this region reveals that alanine substitutions of Arg(391), Ser(393), and Arg(394) destabilize elongation complexes and that substitutions at 393 and 394 increase termination of transcripts 5 or more bases in length. The alpha-carbons of all 3 of these residues lie on the side of helix N, which faces into the template-binding cleft of the RNA polymerase, and modeling suggests that they can contact the RNA 4-5 bases away from the 3'-end. Alanine substitutions of other residues within 385-395 do not have marked effects on transcription complex stability, but alanine substitutions of Asp(388) and Tyr(385) reduce pausing and termination at the T7 concatemer junction. Both of these side chains lie on the outer side of helix N, pointing away from the template binding cleft. The thumb subdomain of T7RNAP therefore has roles both in transcription complex stabilization and in pausing and termination at the T7 concatemer junction.

Characterization of halted T7 RNA polymerase elongation complexes reveals multiple factors that contribute to stability

We have constructed a series of plasmid templates that allow T7 RNA polymerase (RNAP) to be halted at defined intervals downstream from its promoter in a preserved sequence context. While transcription complexes halted at +3 to +6 are highly unstable, complexes halted at +10 to +14 dissociate very slowly and gradually lose their capacity to extend transcripts. Complexes halted at +18 and beyond dissociate more readily, but the stability of the these complexes is enhanced significantly in the presence of the next incoming nucleotide. Unexpectedly, the stability of complexes halted at +14 and beyond was found to be lower on supercoiled templates than on linear templates. To explore this further, we used synthetic DNA templates in which the nature of the non-template (NT) strand was varied. Whereas initiation complexes are less stable in the presence of a complementary NT strand, elongation complexes are more stable in the presence of a complementary NT strand, and the presence of a non-complementary NT strand (a mismatched bubble) results in even greater stability. The results suggest that the NT strand plays an important role in displacing the nascent RNA, allowing its interaction with an RNA product binding site in the RNAP. The NT strand may also contribute to stabilization by interacting directly with the enzyme. A mutant RNAP that has a deletion in the flexible "thumb" domain responds to changes in template topology in a manner that is similar to that of the wild-type (WT) enzyme, but halted complexes formed by the mutant enzyme are particularly dependent upon the presence of the NT strand for stability. In contrast, an N-terminal RNAP mutant that has a decreased capacity to bind single-stranded RNA forms halted complexes with much lower levels of stability than the WT enzyme, and these complexes are not stabilized by the presence of the NT strand. The distinct responses of the mutant RNAPs to changes in template structure indicate that the N-terminal and thumb domains have quite different functions in stabilizing the transcription complex.

Misincorporation by wild-type and mutant T7 RNA polymerases: identification of interactions that reduce misincorporation rates by stabilizing the catalytically incompetent open conformation

We have characterized the misincorporation properties of wild-type (wt) T7 RNAP and of 45 T7RNAP point mutants. The wt enzyme selects strongly against incorporation of an incorrect nucleotide. From the measured rates of misincorporation, an average error frequency of 1 in 2 x 10(4) is estimated. RNAs bearing 3'-mismatches are extended more slowly than correctly paired 3'-termini, and mismatches one or two bases away from the RNA 3'-end can also slow extension severely even when the 3'-base is correctly paired. Though it has been reported that T7RNAP has a 3' --> 5' nuclease activity, we were unable to detect any endogenous T7RNAP RNase activity in elongation complexes. Pyrophosphorolysis was detected but does not appear to contribute to proofreading. Therefore, unlike other RNAPs, T7RNAP fidelity appears to depend entirely on discrimination against incorporation of the incorrect nucleotide and not on post-misincorporation proofreading. Alanine substitution of the H784 side chain, which interacts with the 3' RNA.template base pair, increases both misincorporation and mismatch extension, while substitutions at G640, F644, and G645 increase misincorporation, but not mismatch extension. The latter three amino acids are in a part of the RNAP which interacts with the templating base and with the base immediately 5' to the templating base. Mutation of these amino acids not only increases misincorporation, but also eliminates pausing during promoter clearance. The effects of these mutations and the interactions observed in a crystal structure of a transcribing complex indicate that these mutations disrupt interactions which limit misincorporation rates by stabilizing the catalytically incompetent open conformation of the RNAP.