E. coli mismatch repair enhances AT-to-GC mutagenesis caused by alkylating agents.

Alkylating agents are known to induce the formation of O6-alkylguanine (O6-alkG) and O4-alkylthymine (O4-alkT) in DNA. These lesions have been widely investigated as major sources of mutations. We previously showed that mismatch repair (MMR) facilitates the suppression of GC-to-AT mutations caused by O6-methylguanine more efficiently than the suppression of GC-to-AT mutations caused by O6-ethylguanine. However, the manner by which O4-alkyT lesions are repaired remains unclear. In the present study, we investigated the repair pathway involved in the repair of O4-alkT. The E. coli CC106 strain, which harbors Δprolac in its genomic DNA and carries the F'CC106 episome, can be used to detect AT-to-GC reverse-mutation of the gene encoding ß-galactosidase. Such AT-to-GC mutations should be induced through the formation of O4-alkT at AT base pairs. As expected, an O6-alkylguanine-DNA alkyltransferase (AGT) -deficient CC106 strain, which is defective in both ada and agt genes, exhibited elevated mutant frequencies in the presence of methylating agents and ethylating agents. However, in the UvrA-deficient strain, the methylating agents were less mutagenic than in wild-type, while ethylating agents were more mutagenic than in wild-type, as observed with agents that induce O6-alkylguanine modifications. Unexpectedly, the mutant frequencies decreased in a MutS-deficient strain, and a similar tendency was observed in MutL- or MutH-deficient strains. Thus, MMR appears to promote mutation at AT base pairs. Similar results were obtained in experiments employing double-mutant strains harboring defects in both MMR and AGT, or MMR and NER. E. coli MMR enhances AT-to-GC mutagenesis, such as that caused by O4-alkylthymine. We hypothesize that the MutS protein recognizes the O4-alkT:A base pair more efficiently than O4-alkT:G. Such a distinction would result in misincorporation of G at the O4-alkT site, followed by higher mutation frequencies in wild-type cells, which have MutS protein, compared to MMR-deficient strains.

Early induction of direct hemoperfusion with a polymyxin-B immobilized column is associated with amelioration of hemodynamic derangement and mortality in patients with septic shock.

This study was conducted to clarify the effectiveness of induction timing of direct hemoperfusion with a polymyxin-B immobilized column (PMX-DHP) for amelioration of hemodynamic derangement and outcome in patients with septic shock. Suspected Gram-negative septic shock patients who received PMX-DHP therapy from January 2010 to December 2014 in our ICU were enrolled in this study. The patients were divided into two groups that received PMX-DHP therapy within 8 h (early group) and more than 8 h (late group) from catecholamine administration. Changes in catecholamine dose [catecholamine index (CAI)], catecholamine dose/mean arterial pressure [catecholamine index pressure (CAIP)], PaO2/FiO2 and PEEP level were determined at the start of and 24 h after the start of PMX-DHP therapy. Ventilator-free days (VFD), ICU-free days (IFD), 28-day and hospital mortality were also determined. There were no significant differences in patients' characteristics between the two groups. CAI and CAIP were significantly decreased in the early group. PaO2/FiO2 was not changed whereas PEEP level in the early group was significantly decreased during PMX-DHP therapy. IFD and VFD were not different in the two groups. Mortality at 28 days was significantly improved in the early group. Endotoxin acts as an early mediator in sepsis patients with suspected Gram-negative infection. Earlier induction of PMX-DHP therapy as in our study is closely associated with earlier weaning from hemodynamic derangement and with improvement of mortality. Therefore, early induction of PMX-DHP therapy is recommended for the treatment of septic shock in patients with presumed Gram-negative infection.

A streptolysin S homologue is essential for ß-haemolytic Streptococcus constellatus subsp. constellatus cytotoxicity.

Streptococcus constellatus is a member of the Anginosus group streptococci (AGS) and primarily inhabits the human oral cavity. S. constellatus is composed of three subspecies: S. constellatus subsp. constellatus (SCC), S. constellatus subsp. pharyngis and the newly described subspecies S. constellatus subsp. viborgensis. Although previous studies have established that SCC contains ß-haemolytic strains, the factor(s) responsible for ß-haemolysis in ß-haemolytic SCC (ß-SCC) has yet to be clarified. Recently, we discovered that a streptolysin S (SLS) homologue is the ß-haemolytic factor of ß-haemolytic Streptococcus anginosus subsp. anginosus (ß-SAA), another member of the AGS. Furthermore, because previous studies have suggested that other AGS species, except for Streptococcus intermedius, do not possess a haemolysin(s) belonging to the family of cholesterol-dependent cytolysins, we hypothesized that, as with ß-SAA, the SLS homologue is the ß-haemolytic factor of ß-SCC, and therefore aimed to investigate and characterize the haemolytic factor of ß-SCC in the present study. PCR amplification revealed that all of the tested ß-SCC strains were positive for the sagA homologue of SCC (sagA(SCC)). Further investigations using ß-SCC strain W277 were conducted to elucidate the relationship between sagA(SCC) and ß-haemolysis by constructing sagA(SCC) deletion mutants, which completely lost ß-haemolytic activity. This loss of ß-haemolytic activity was restored by trans-complementation of sagA(SCC). Furthermore, a co-cultivation assay established that the cytotoxicity of ß-SCC was clearly dependent on the presence of sagA(SCC). These results demonstrate that sagA(SCC) is the factor responsible for ß-SCC ß-haemolysis and cytotoxicity.

A protein-protein interaction assay based on the functional complementation of mutant firefly luciferases.

We report a novel bioluminescent protein-protein interaction (PPI) assay, which is based on the functional complementation of two mutant firefly luciferases (Fluc). The chemical reaction catalyzed by Fluc is divided into two half reactions of ATP-driven luciferin adenylation and subsequent oxidative reactions. In the former adenylation half-reaction, a luciferyl-adenylate (LH2-AMP) intermediate is produced from LH2 and ATP. With this intermediate, the latter oxidative reactions produce oxyluciferin via proton abstraction at the C4 carbon of LH2-AMP. We created and optimized two Fluc mutants; one is named "Donor", which virtually lacks oxidative activity, while the other, named "Acceptor", is almost defective in the adenylation activity. Then, the two mutants are fused to interacting partners, and prepared as pure proteins. When the interaction between the partners is induced, higher efficiency of LH2-AMP transfer between the Donor and Acceptor enzymes resulted in increased luminescence. The assay was found to work both in vitro and in cultured cells with strong signals. This would be the first example of reconstituting two divided reactions of one enzyme to detect PPI, which will not only be utilized as a robust PPI assay, but also open a way to control the activity of similar enzymes in acyl/adenylate-forming enzyme superfamily.

Distinct pathways for repairing mutagenic lesions induced by methylating and ethylating agents.

DNA alkylation damage can be repaired by nucleotide excision repair (NER), base excision repair (BER) or by direct removal of alkyl groups from modified bases by O(6)-alkylguanine DNA alkyltransferase (AGT; E.C. 2.1.1.63). DNA mismatch repair (MMR) is also likely involved in this repair. We have investigated alkylation-induced mutagenesis in a series of NER- or AGT-deficient Escherichia coli strains, alone or in combination with defects in the MutS, MutL or MutH components of MMR. All strains used contained the F'prolac from strain CC102 (F'CC102) episome capable of detecting specifically lac GC to AT reverse mutations resulting from O(6)-alkylguanine. The results showed the repair of O(6)-methylguanine to be performed by AGT ≫ MMR > NER in order of importance, whereas the repair of O(6)-ethylguanine followed the order NER > AGT > MMR. Studies with double mutants showed that in the absence of AGT or NER repair pathways, the lack of MutS protein generally increased mutant frequencies for both methylating and ethylating agents, suggesting a repair or mutation avoidance role for this protein. However, lack of MutL or MutH protein did not increase alkylation-induced mutagenesis under these conditions and, in fact, reduced mutagenesis by the N-alkyl-N-nitrosoureas MNU and ENU. The combined results suggest that little or no alkylation damage is actually corrected by the mutHLS MMR system; instead, an as yet unspecified interaction of MutS protein with alkylated DNA may promote the involvement of a repair system other than MMR to avoid a mutagenic outcome. Furthermore, both mutagenic and antimutagenic effects of MMR were detected, revealing a dual function of the MMR system in alkylation-exposed cells.

Novel twin streptolysin S-like peptides encoded in the sag operon homologue of beta-hemolytic Streptococcus anginosus.

Streptococcus anginosus is a member of the anginosus group streptococci, which form part of the normal human oral flora. In contrast to the pyogenic group streptococci, our knowledge of the virulence factors of the anginosus group streptococci, including S. anginosus, is not sufficient to allow a clear understanding of the basis of their pathogenicity. Generally, hemolysins are thought to be important virulence factors in streptococcal infections. In the present study, a sag operon homologue was shown to be responsible for beta-hemolysis in S. anginosus strains by random gene knockout. Interestingly, contrary to pyogenic group streptococci, beta-hemolytic S. anginosus was shown to have two tandem sagA homologues, encoding streptolysin S (SLS)-like peptides, in the sag operon homologue. Gene deletion and complementation experiments revealed that both genes were functional, and these SLS-like peptides were essential for beta-hemolysis in beta-hemolytic S. anginosus. Furthermore, the amino acid sequence of these SLS-like peptides differed from that of the typical SLS of S. pyogenes, especially in their propeptide domain, and an amino acid residue indicated to be important for the cytolytic activity of SLS in S. pyogenes was deleted in both S. anginosus homologues. These data suggest that SLS-like peptides encoded by two sagA homologues in beta-hemolytic S. anginosus may be potential virulence factors with a different structure essential for hemolytic activity and/or the maturation process compared to the typical SLS present in pyogenic group streptococci.