CTP and parS coordinate ParB partition complex dynamics and ParA-ATPase activation for ParABS-mediated DNA partitioning.

ParABS partition systems, comprising the centromere-like DNA sequence parS, the parS-binding ParB-CTPase, and the nucleoid-binding ParA-ATPase, ensure faithful segregation of bacterial chromosomes and low-copy-number plasmids. F-plasmid partition complexes containing ParBF and parSF move by generating and following a local concentration gradient of nucleoid-bound ParAF. However, the process through which ParBF activates ParAF-ATPase has not been defined. We studied CTP- and parSF-modulated ParAF-ParBF complex assembly, in which DNA-bound ParAF-ATP dimers are activated for ATP hydrolysis by interacting with two ParBF N-terminal domains. CTP or parSF enhances the ATPase rate without significantly accelerating ParAF-ParBF complex assembly. Together, parSF and CTP accelerate ParAF-ParBF assembly without further significant increase in ATPase rate. Magnetic-tweezers experiments showed that CTP promotes multiple ParBF loading onto parSF-containing DNA, generating condensed partition complex-like assemblies. We propose that ParBF in the partition complex adopts a conformation that enhances ParBF-ParBF and ParAF-ParBF interactions promoting efficient partitioning.

The atlas of cytoophidia in Drosophila larvae.

In 2010, cytidine 5'-triphosphate synthase (CTPS) was reported to form the filamentous or serpentine structure in Drosophila, which we termed the cytoophidium. In the last decade, CTPS filaments/cytoophidia have been found in bacteria, budding yeast, human cells, mice, fission yeast, plants, and archaea, indicating that this mechanism is highly conserved in evolution. In addition to CTPS, other metabolic enzymes have been identified to have the characteristics of forming cytoophidia or similar advanced structures, demonstrating that this is a basic strategy of cells. Nevertheless, our understanding of the physiological function of the cytoophidium remains incomplete and elusive. Here, we took the larva of Drosophila melanogaster as a model to systematically describe the localization and distribution of cytoophidia in different tissues during larval development. We found that the distribution pattern of CTPS cytoophidia is dynamic and heterogenic in larval tissues. Our study provides a road map for further understanding of the function and regulatory mechanism of cytoophidia.

The proline synthesis enzyme P5CS forms cytoophidia in Drosophila.

Compartmentation of enzymes via filamentation has arisen as a mechanism for the regulation of metabolism. In 2010, three groups independently reported that CTP synthase (CTPS) can assemble into a filamentous structure termed the cytoophidium. In searching for CTPS-interacting proteins, here we perform a yeast two-hybrid screening of Drosophila proteins and identify a putative CTPS-interacting protein, △1-pyrroline-5-carboxylate synthase (P5CS). Using the Drosophila follicle cell as the in vivo model, we confirm that P5CS forms cytoophidia, which are associated with CTPS cytoophidia. Overexpression of P5CS increases the length of CTPS cytoophidia. Conversely, filamentation of CTPS affects the morphology of P5CS cytoophidia. Finally, in vitro analyses confirm the filament-forming property of P5CS. Our work links CTPS with P5CS, two enzymes involved in the rate-limiting steps in pyrimidine and proline biosynthesis, respectively.

Alternative transcription cycle for bacterial RNA polymerase.

RNA polymerases (RNAPs) transcribe genes through a cycle of recruitment to promoter DNA, initiation, elongation, and termination. After termination, RNAP is thought to initiate the next round of transcription by detaching from DNA and rebinding a new promoter. Here we use single-molecule fluorescence microscopy to observe individual RNAP molecules after transcript release at a terminator. Following termination, RNAP almost always remains bound to DNA and sometimes exhibits one-dimensional sliding over thousands of basepairs. Unexpectedly, the DNA-bound RNAP often restarts transcription, usually in reverse direction, thus producing an antisense transcript. Furthermore, we report evidence of this secondary initiation in live cells, using genome-wide RNA sequencing. These findings reveal an alternative transcription cycle that allows RNAP to reinitiate without dissociating from DNA, which is likely to have important implications for gene regulation.

Relationship between Ni(II) and Zn(II) coordination and nucleotide binding by the Helicobacter pylori [NiFe]-hydrogenase and urease maturation factor HypB.

The pathogen Helicobacter pylori requires two nickel-containing enzymes, urease and [NiFe]-hydrogenase, for efficient colonization of the human gastric mucosa. These enzymes possess complex metallocenters that are assembled by teams of proteins in multistep pathways. One essential accessory protein is the GTPase HypB, which is required for Ni(II) delivery to [NiFe]-hydrogenase and participates in urease maturation. Ni(II) or Zn(II) binding to a site embedded in the GTPase domain of HypB modulates the enzymatic activity, suggesting a mechanism of regulation. In this study, biochemical and structural analyses of H. pylori HypB (HpHypB) revealed an intricate link between nucleotide and metal binding. HpHypB nickel coordination, stoichiometry, and affinity were modulated by GTP and GDP, an effect not observed for zinc, and biochemical evidence suggests that His-107 coordination to nickel toggles on and off in a nucleotide-dependent manner. These results are consistent with the crystal structure of HpHypB loaded with Ni(II), GDP, and Pi, which reveals a nickel site distinct from that of zinc-loaded Methanocaldococcus jannaschii HypB as well as subtle changes to the protein structure. Furthermore, Cys-142, a metal ligand from the Switch II GTPase motif, was identified as a key component of the signal transduction between metal binding and the enzymatic activity. Finally, potassium accelerated the enzymatic activity of HpHypB but had no effect on the other biochemical properties of the protein. Altogether, this molecular level information about HpHypB provides insight into its cellular function and illuminates a possible mechanism of metal ion discrimination.

NTP-mediated nucleotide excision activity of hepatitis C virus RNA-dependent RNA polymerase.

Hepatitis C virus (HCV) RNA-dependent RNA polymerase replicates the viral genomic RNA and is a primary drug target for antiviral therapy. Previously, we described the purification of an active and stable polymerase-primer-template elongation complex. Here, we show that, unexpectedly, the polymerase elongation complex can use NTPs to excise the terminal nucleotide in nascent RNA. Mismatched ATP, UTP, or CTP could mediate excision of 3'-terminal CMP to generate the dinucleoside tetraphosphate products Ap(4)C, Up(4)C, and Cp(4)C, respectively. Pre-steady-state kinetic studies showed that the efficiency of NTP-mediated excision was highest with ATP. A chain-terminating inhibitor, 3'deoxy-CMP, could also be excised through this mechanism, suggesting important implications for nucleoside drug potency and resistance. The nucleotide excision reaction catalyzed by recombinant hepatitis C virus polymerase was 100-fold more efficient than the corresponding reaction observed with HIV reverse transcriptase.

Making sense of a missense mutation: characterization of MutT2, a Nudix hydrolase from Mycobacterium tuberculosis, and the G58R mutant encoded in W-Beijing strains of M. tuberculosis.

Recent polymorphism analyses of Mycobacterium tuberculosis strains have identified missense mutations unique to the W-Beijing lineage in genes belonging to the Nudix hydrolase superfamily. This study investigates the structure and function of one of these Nudix hydrolases, MutT2, and examines the effect that the W-Beijing mutation (G58R) has on enzyme characteristics. MutT2 has a preference for cytidine triphosphates, and although the G58R mutation does not alter nucleotide specificity, it reduces the protein's affinity for divalent cations. The K(D) of free Mg(2+) is 79-fold higher for the G58R mutant (3.30 +/- 0.19 mM) compared with that for the wild-type (41.7 +/- 1.4 microM). Circular dichroism and nuclear magnetic resonance spectroscopy measurements show that while the mutation does not perturb the overall structure of the protein, protein stability is significantly compromised by the presence of the arginine with DeltaG (H(2)O), the free-energy of unfolding, being reduced by 2.48 kcal mol(-1) in the G58R mutant. Homology modeling of MutT2 shows that Gly-58 is in close proximity (10.8 A) to the Mg(2+) binding site formed by the highly conserved Nudix box residues and hydrogen bonds with Ala-54 in the preceding alpha-helix. This may explain the increased divalent cation requirement and decreased stability observed when an arginine is substituted for glycine at this position. A role for MutT2 in the regulation of cytidine-triphosphates available for nucleotide-dependent reactions is postulated, and the impact that the G58R mutation may have on these reactions is discussed.

Known components of the immunoglobulin A:T mutational machinery are intact in Burkitt lymphoma cell lines with G:C bias.

The basis for mutations at A:T base pairs in immunoglobulin hypermutation and defining how AID interacts with the DNA of the immunoglobulin locus are major aspects of the immunoglobulin mutator mechanism where questions remain unanswered. Here, we examined the pattern of mutations generated in mice deficient in various DNA repair proteins implicated in A:T mutation and found a previously unappreciated bias at G:C base pairs in spectra from mice simultaneously deficient in DNA mismatch repair and uracil DNA glycosylase. This suggests a strand-biased DNA transaction for AID delivery which is then masked by the mechanism that introduces A:T mutations. Additionally, we asked if any of the known components of the A:T mutation machinery underscore the basis for the paucity of A:T mutations in the Burkitt lymphoma cell lines, Ramos and BL2. Ramos and BL2 cells were proficient in MSH2/MSH6-mediated mismatch repair, and express high levels of wild-type, full-length DNA polymerase eta. In addition, Ramos cells have high levels of uracil DNA glycosylase protein and are proficient in base excision repair. These results suggest that Burkitt lymphoma cell lines may be deficient in an unidentified factor that recruits the machinery necessary for A:T mutation or that AID-mediated cytosine deamination in these cells may be processed by conventional base excision repair truncating somatic hypermutation at the G:C phase. Either scenario suggests that cytosine deamination by AID is not enough to trigger A:T mutation, and that additional unidentified factors are required for full spectrum hypermutation in vivo.

Cosegregation of C-insertion at position 961 with the A1555G mutation of the mitochondrial 12S rRNA gene in a large Chinese family with maternally inherited hearing loss.

Mutations in the mitochondrial DNA have been shown to be one of the most important causes of sensorineural hearing loss. Here, we report the characterization of a large Chinese family (507 members in six generations) with maternally inherited non-syndromic hearing loss. Members of this family showed variable severity and age-of-onset of hearing impairment. In particular, the average age at onset of hearing loss in this family changed from 49 years (generation III) to 3 years (generation VI). Sequence analysis of the complete mitochondrial genome in this pedigree revealed the presence of a homoplasmic A1555G mutation in the 12S rRNA gene and other nucleotide changes. Of these changes, a C insertion at position 961 in the 12S rRNA gene is of special interest as mutations at this position have been found to be associated with aminoglycoside induced deafness in several genetically unrelated families. These data imply that the C insertion at position 961 in the 12S rRNA gene, acting as a secondary factor, could play a role in the phenotypic expression of the deafness associated A1555G mutation.

Association of the CD14 gene -159C polymorphism with progression of IgA nephropathy.

The risk factors associated with the progression of IgA nephropathy (IgAN), the most common form of glomerulonephritis, are unclear. It has been suggested that CD14 signalling in response to various microbes affects the natural history of chronic inflammatory conditions. It has been hypothesised that variants in the promoter region of the CD14 gene might alter the expression of CD14, and this in turn could influence the progressive nature of IgAN. PCR-RFLP was used to determine the polymorphism at the -159 site (T to C). The distribution of the CD14/-159 polymorphism was no different in patients with IgAN (n=216) compared to 171 healthy controls. After follow up for 86 months, it was found that an excess of the C genotype occurred in patients with progressive disease (p=0.03) and the risk of disease progression increased as the number of C alleles increased (p for trend = 0.002). The hazard ratio for progression in the patients with the CC genotype was 3.2 (p=0.025) compared with the patients possessing the TT genotype. After LPS stimulation, sCD14 was released more abundantly from the PBMCs of the TT subjects than from that of the CC subjects (p=0.006), even though mCD14 expression level was no different. In addition, the TT subjects released less IL-6 than the CC subjects after stimulation (p=0.0003). These results suggest that the CD14/-159 polymorphism is an important marker for the progression of IgAN and may modulate the level of the inflammatory responses.

Characterisation of Pt MYB1, an R2R3-MYB from pine xylem.

A cDNA encoding a member of the R2R3-MYB family of transcription factors was cloned from a library constructed from differentiating Pinus taeda (loblolly pine) xylem RNA. This MYB family member, Pinus taeda MYB1 (PtMYB1), was most abundantly expressed in differentiating xylem, as assessed by both ribonuclease protection assays, and by northern blot analysis with poly(A)-enriched RNA. Similar to other plant R2R3-MYB family members, recombinant Pt MYB1 protein was able to bind to AC elements in electrophoretic mobility shift assays (EMSAs). AC elements are DNA motifs rich in adenosine and cytosine that have been implicated in the xylem-localised regulation of genes encoding lignin biosynthetic enzymes. Pt MYB1 not only bound to AC elements, but was also able to induce AC-element-dependent shifts in the electrophoretic mobility of a plant promoter that contains three AC elements, the minimal PHENYLALANINE AMMONIA-LYASE 2 (PAL2) promoter from Phaseolus vulgaris. Transcriptional activation assays conducted using yeast showed that Pt MYB1 also activated transcription, and that it did so in an AC-element-dependent fashion. Pt MYB1 also activated transcription from the minimal PAL2 promoter in plant cells in an AC-element-dependent fashion, as revealed by transient transcriptional activation assays with microprojectile-bombarded tobacco NT-1 cells. Taken together, these finding are consistent with the hypothesis that Pt MYB1 may regulate transcription from cis -acting AC elements in pine xylem.

Strong natural pausing by RNA polymerase II within 10 bases of transcription start may result in repeated slippage and reextension of the nascent RNA.

We find that immediately following transcript initiation, RNA polymerase II pauses at several locations even in the presence of relatively high (200 microM) levels of nucleoside triphosphates. Strong pauses with half-lives of >30 s were observed at +7, +18/19, and about +25 on the template used in these experiments. We show that the strong pause at +7, after the synthesis of 5'-ACUCUCU, leads to repeated cycles of upstream slippage of the RNA-DNA hybrid followed by re-pairing with the DNA and continued RNA synthesis. The resulting transcripts are 2, 4, and 6 bases longer than predicted by the template sequence. Slippage is efficient when transcription is primed with the +1/+2 (ApC) dinucleotide, and it occurs at even higher levels with the +2/+3 primer (CpU). Slippage can occur at high levels with ATP initiation, but priming with CpA (-1/+1) supports very little slippage. This latter result is not simply an effect of transcript length at the point of pausing. Slippage can also occur with a second template on which the polymerase can be paused after synthesizing ACUCU. Slippage is not reduced by an ATP analog that blocks promoter escape, but it is inhibited by substitution of 5Br-U for U in the RNA. Our results reveal an unexpected flexibility of RNA polymerase II ternary complexes during the very early stage of transcription, and they suggest that initiation at different locations within the same promoter gives rise to transcription complexes with different properties.

Insertional editing in isolated Physarum mitochondria is linked to RNA synthesis.

The mitochondrial RNAs of Physarum polycephalum are edited efficiently by nucleotide insertion both in vivo and in isolated mitochondria. Our recent studies have demonstrated that nucleotide addition can occur within 14-22 nt of the 3' end of a nascent RNA, suggesting that insertional editing may be linked to transcription. To investigate the relationship between these processes, we have examined the effects of nucleotide concentration on templated and nontemplated nucleotide addition in isolated mitochondria. At very low CTP concentrations, transcription and editing proceed with high fidelity, but the efficiency of cytidine insertional editing decreases. Insertion of single uridine and dinucleotides is not diminished under conditions that yield unedited or partially edited C insertion sites, indicating that editing events occur independently of one another. Moreover, analysis of partially edited RNA demonstrates that single nucleotides can be added at dinucleotide insertion sites. Importantly, pulse-chase experiments indicate that nontemplated nucleotides are not inserted into previously synthesized RNA once editing conditions are restored, although RNA downstream of the unedited region is edited efficiently. This result indicates that insertional editing cannot occur posttranscriptionally under these conditions, and suggests that there is only a small "window of opportunity" in which nucleotide insertion can occur. Our data are consistent with an editing activity that functions in a strictly 5' to 3' direction and adds nucleotides at, or close to, the 3' end of nascent RNA in association with the transcription complex. Several possible models for the mechanism of insertional editing in Physarum are discussed.

Hypermutagenic in vitro transcription employing biased NTP pools and manganese cations.

In vitro DNA-dependent RNA transcription using bacteriophage T3 RNA polymerase may be rendered hypermutagenic by employing biased nucleoside triphosphate (NTP) concentrations and manganese cations. Using the E. coli R67 plasmid-encoded dihydrofolate reductase (DHFR) gene as target substitution rates approaching 4 x 10(-2) per base per reaction could be achieved, on a par with hypermutagenic reverse transcription. In all cases the majority of substitutions was that expected from the NTP pool bias. The addition of manganese ions increased the frequency of mutations, particularly the proportion of transversions. Functional DHFR hypermutants with up to 8% amino acid substitutions were readily obtained from a single reaction which, given the unique mutation matrix allows exploration of sequence space complementary to that accessed by other hypermutagenic protocols.

Bypass of DNA heterologies during RuvAB-mediated three- and four-strand branch migration.

During general genetic recombination and recombinational DNA repair, DNA damages and heterologies are often encountered which must be efficiently processed by the cellular recombination machinery. In RecA-mediated three-strand exchange reactions between single-stranded circular and linear duplex DNA, or four-strand exchange reactions between gapped circular and linear duplex DNA, heterologies can only be bypassed in vitro when they are short in length and are followed by homologous DNA downstream. Larger DNA inserts block RecA-mediated strand exchange, indicating that effective bypass requires other components of the recombination machinery. The RuvA and RuvB proteins of Escherichia coli form an important part of this machinery. In this work, we have analysed the ability of RuvA and RuvB to bypass large tracts of DNA heterology in both three- and four-strand exchange reactions, using recombination intermediates made by the E. coli RecA protein. Under optimal reaction conditions for RuvAB, up to 1000 bp of DNA heterology can by bypassed in three-strand reactions and 300 bp of DNA heterology can be bypassed in four-strand reactions. Whereas high concentrations of RuvB (in the absence of RuvA) can promote homologous branch migration, we find that RuvB alone is unable to catalyse heterologous bypass, indicating an essential role for both proteins in homologous recombination and recombinational DNA repair processes. Under certain conditions, the bypass of heterology is stimulated by the single-strand binding protein SSB.