The use of functionalized nanoparticles to treat Staphylococcus aureus-based surgical-site infections: a systematic review.

Staphylococcus aureus-based surgical site infections have become the leading cause of failure for total joint arthroplasty operations and remain a major issue across surgical specialties. Moreover, S. aureus-based infections are becoming drastically more difficult to treat due to the development of antibiotic resistant strains and due to the bacteria's propensity to produce biofilms. The emergence of highly resistant S. aureus infections has created the need for a novel antimicrobial treatment. Functionalized nanoparticles have recently been suggested as being a viable option to fill this void due to their strong antimicrobial and antibiofilm properties. However, said research remains a novel and developing field. The presented systematic review aimed to synthesize the best and most recent evidence available to accurately direct new research towards a viable treatment mechanism. In doing so, the authors performed a comprehensive literature search as directed by the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines. The results showed that nanoparticles-particularly those including an iron-oxide component or acidic capping agent-are a viable treatment for S. aureus infections both in vivo and in vitro, and show even greater efficacy when combined with exposure to a magnetic field and irradiation.

The intracellular function of extracellular signaling peptides.

A novel class of extracellular signaling peptides has been identified in Gram-positive bacteria that are actively transported into the cell to interact with intracellular receptors. The defining members of this novel class of signaling peptides are the Phr peptides of Bacillus subtilis and the mating pheromones of Enterococcus faecalis. These peptides are small and unmodified, gene encoded, and secreted by the bacterium. Most of these peptides diffuse into the extracellular medium, and when their concentration is sufficiently high, they are then actively transported into the cell by an oligopeptide permease (Opp). Once inside the cell, these peptides interact with an array of intracellular receptors. In B. subtilis, the Phr peptides regulate development of environmentally resistant spores and genetically competent cells (i.e. the natural ability to take up exogenous DNA). In E. faecalis, the mating pheromones regulate cell-cell transfer of plasmids, many of which encode antibiotic resistance or virulence factors. At least one component of the signaling pathway for these peptides is conserved in many bacteria, Opp. Opp is a non-specific transporter that transports peptides for use as carbon and nitrogen sources. The possibility that other bacteria could possess similar intracellularly functioning signaling peptides is discussed.

The sporulation transcription factor Spo0A is required for biofilm development in Bacillus subtilis.

Biofilms are structured communities of cells encased in a polymeric matrix and adherent to a surface, interface or each other. We report here that the soil bacterium Bacillus subtilis forms biofilms. By confocal scanning laser microscopy, we observed that B. subtilis adhered to abiotic surfaces and formed a three-dimensional structure > or =30 microm in depth. These biofilms appeared to be at least partly encased in an extracellular polysaccharide matrix, as they could be stained with Calcofluor, a polysaccharide-binding dye. To understand the molecular mechanism of biofilm formation, we screened previously characterized mutants for a defect in biofilm formation. We found that mutations in spo0A, which encodes the major early sporulation transcription factor, caused a defect in biofilm formation. spo0A mutant cells adhered to a surface in a monolayer of cells rather than a three-dimensional biofilm. The requirement of Spo0A for biofilm development appears to result from its role in negatively regulating AbrB. Mutations in abrB suppressed the biofilm defect of a spo0A mutant, indicating that AbrB negatively regulates at least one gene that is required for the transition from a monolayer of attached cells to a mature biofilm. Implications of biofilm development for the ecology of B. subtilis are discussed.

Quorum sensing and starvation: signals for entry into stationary phase.

Quorum sensing occurs at high cell density in many microorganisms. It regulates specialized processes such as genetic competence, bioluminescence, virulence, and sporulation. However, recent evidence suggests that quorum-sensing may play a more central role in the physiology of bacteria, where quorum-sensing pathways converge with starvation-sensing pathways to regulate cell entry into stationary phase.

An autoregulatory circuit affecting peptide signaling in Bacillus subtilis.

The competence and sporulation factor (CSF) of Bacillus subtilis is an extracellular pentapeptide produced from the product of phrC. CSF has at least three activities: (i) at low concentrations, it stimulates expression of genes activated by the transcription factor ComA; at higher concentrations, it (ii) inhibits expression of those same genes and (iii) stimulates sporulation. Because the activities of CSF are concentration dependent, we measured the amount of extracellular CSF produced by cells. We found that by mid-exponential phase, CSF accumulated to concentrations (1 to 5 nM) that stimulate ComA-dependent gene expression. Upon entry into stationary phase, CSF reached 50 to 100 nM, concentrations that stimulate sporulation and inhibit ComA-dependent gene expression. Transcription of phrC was found to be controlled by two promoters: P1, which precedes rapC, the gene upstream of phrC; and P2, which directs transcription of phrC only. Both RapC and CSF were found to be part of autoregulatory loops that affect transcription from P1, which we show is activated by ComA approximately P. RapC negatively regulates its own expression, presumably due to its ability to inhibit accumulation of ComA approximately P. CSF positively regulates its own expression, presumably due to its ability to inhibit RapC activity. Transcription from P2, which is controlled by the alternate sigma factor sigma(H), increased as cells entered stationary phase, contributing to the increase in extracellular CSF at this time. In addition to controlling transcription of phrC, sigmaH appears to control expression of at least one other gene required for production of CSF.

The ins and outs of peptide signaling.

Many bacteria communicate by secreting and responding to extracellular peptides (pheromones). Some peptide pheromones act via receptors on the cell surface, which are often membrane-bound histidine protein kinases. Other peptide pheromones are transported into the cell by an oligopeptide permease and interact with intracellular receptors to modulate gene expression.

A regulatory switch involving a Clp ATPase.

Clp ATPase chaperone proteins are found in procaryotes and eucaryotes. Recently, ClpC of Bacillus subtilis was found to be part of a regulatory switch(1). ClpC, in combination with the MecA and ComS proteins, regulates the activity of a transcription factor, ComK, which is necessary for the development of genetic competence (the ability to bind and take up exogenous DNA). The complex of ClpC:MecA:ComK renders ComK inactive. Interaction between ComS and the ternary complex releases active ComK. This regulatory switch controls ComK activity in response to cell density signals that affect production of ComS. Regulated interaction between Clp ATPase and target proteins might prove to be widespread.

An exported peptide functions intracellularly to contribute to cell density signaling in B. subtilis.

Competence development and sporulation in B. subtilis are partly controlled by peptides that accumulate in culture medium as cells grow to high density. We constructed two genes that encode mature forms of two different signaling molecules, the PhrA peptide that stimulates sporulation, and CSF, the competence- and sporulation-stimulating factor. Both pentapeptides are normally produced by secretion and processing of precursor molecules. The mature pentapeptides were functional when expressed inside the cell, indicating that they normally need to be imported to function. Furthermore, at physiological concentrations (10 nM), CSF was transported into the cell by the oligopeptide permease encoded by spo0K (opp). CSF was shown to have at least three different targets corresponding to its three activities: stimulating competence gene expression at low concentrations, and inhibiting competence gene expression and stimulating sporulation at high concentrations.

Purification and characterization of an extracellular peptide factor that affects two different developmental pathways in Bacillus subtilis.

We have purified and characterized an extracellular peptide factor that serves as a cell density signal for both competence development and sporulation in Bacillus subtilis. This competence and sporulation stimulating factor (CSF) was purified from conditioned medium (culture supernatant) based on its ability to stimulate expression of srfA (comS) in cells at low cell density. CSF is a 5-amino-acid peptide, glu-arg-gly-met-thr (ERGMT), that is, the carboxy-terminal 5 amino acids of the 40-amino-acid peptide encoded by phrC. No detectable CSF was produced in a phrC null mutant. The activity of chemically synthesized CSF (ERGMT) was virtually indistinguishable from that of CSF that was purified from culture supernatants. At relatively low concentrations (1-10 nM), CSF stimulated expression of srfA, whereas high concentrations of CSF stimulated the ability of cells at low cell density to sporulate. Stimulation of srfA expression by CSF requires the oligopeptide permease encoded by spo0K, a member of the ATP-binding-cassette family of transporters, and the putative phosphatase encoded by rapC, the gene immediately upstream of phrC. RapC was found to be a negative regulator of srfA expression, suggesting that the target of RapC is the transcription factor encoded by comA. We propose that CSF is transported into the cell by the Spo0K oligopeptide permease and stimulates competence gene expression by inhibiting (either directly or indirectly) the RapC phosphatase.

DNA binding and dimerization of the Fe-S-containing FNR protein from Escherichia coli are regulated by oxygen.

The transcription factor FNR from Escherichia coli regulates transcription of genes in response to oxygen deprivation. To determine how the activity of FNR is regulated by oxygen, a form of FNR had to be isolated that had properties similar to those observed in vivo. This was accomplished by purification of an FNR fraction which exhibited enhanced DNA binding in the absence of oxygen. Iron and sulfide analyses of this FNR fraction indicated the presence of an Fe-S cluster. To determine the type of Fe-S cluster present, an oxygen-stable mutant protein LH28-DA154 was also analyzed since FNR LH28-DA154 purified anoxically contained almost 3-fold more iron and sulfide than the wild-type protein. Based on the sulfide analysis, the stoichiometry (3.3 mol of S2-/FNR monomer) was consistent with either one [4Fe-4S] or two [2Fe-2S] clusters per mutant FNR monomer. However, since FNR has only four Cys residues as potential cluster ligands and an EPR signal typical of a 3Fe-4S cluster was detected on oxidation, we conclude that there is one [4Fe-4S] cluster present per monomer of FNR LH28-DA154. We assume that the wild type also contains one [4Fe-4S] cluster per monomer and that the lower amounts of iron and sulfide observed per monomer were due to partial occupancy. Consistent with this, the Fe-S cluster in the wild-type protein was found to be extremely oxygen-labile. In addition, molecular-sieve chromatographic analysis showed that the majority of the anoxically purified protein was a dimer as compared to aerobically purified FNR which is a monomer. The loss of the Fe-S cluster by exposure to oxygen was associated with a conversion to the monomeric form and decreased DNA binding. Taken together, these observations suggest that oxygen regulates the activity of wild-type FNR through the lability of the Fe-S cluster to oxygen.

Characterization of FNR* mutant proteins indicates two distinct mechanisms for altering oxygen regulation of the Escherichia coli transcription factor FNR.

In order to gain insight into the mechanism by which the Escherichia coli transcription factor FNR* is activated in response to anaerobiosis, we have analyzed FNR mutant proteins which, unlike the wild-type protein, stimulate gene expression in the presence of oxygen in vivo. Cell extracts containing seven different FNR* mutant proteins were tested in vitro for the ability to bind to the FNR consensus DNA site in a gel retardation assay under aerobic conditions. At the concentration of protein tested, only extracts which contained FNR* mutant proteins with amino acid substitutions at position 154 showed significant DNA binding. The three position-154 FNR* mutant proteins could be further distinguished from the other mutant proteins by analysis of the in vivo phenotypes of FNR* proteins containing amino acid substitutions at either of two essential cysteine residues. In the presence of oxygen, FNR* mutant proteins with amino acid substitutions at position 154 were the least affected when either Cys-23 or Cys-122 was substituted for Ser. On the basis of these in vivo and in vitro analyses, FNR* mutant proteins appear to segregate into at least two classes. Thus, it appears that each class of FNR* substitutions alters the normal pathway of FNR activation in response to oxygen deprivation by a different mechanism.

Addition of a bacterial alginate lyase to purulent CF sputum in vitro can result in the disruption of alginate and modification of sputum viscoelasticity.

Alginate is a large molecular weight exopolysaccharide present in the purulent airway secretions of cystic fibrosis (CF) patients. This polymer, produced by some of the opportunistic pathogens associated with the recurrent lung infections characteristic of CF, has been suggested to effect an increase in the viscoelastic properties of purulent CF airway secretions. We have investigated the use of an enzyme targeted at this exopolysaccharide, an alginate lyase obtained from a bacterial source, to disrupt its polymeric nature and effect a change in the rheological properties of CF sputum in vitro. Expectorated sputum samples obtained from hospitalized CF patients were found to contain 80-200 micrograms alginate per ml sputum with no measurable endogenous alginate lyase activity. Treatment with exogenous alginate lyase prepared from a mucoid strain of Pseudomonas aeruginosa resulted in the disruption of alginate and a decrease in sputum viscoelasticity in a small percentage of the samples tested. Similar treatment of these samples with recombinant human deoxyribonuclease I to cleave DNA present in purulent sputum and the use of alginate extracted from sputum as an alginate lyase assay substrate suggested that the inability of the exogenous alginate lyase to disrupt sputum alginate was not due to substrate inaccessibility or an unresponsive substrate. Concentrations of Ca2+ and Zn2+ in alginate lyase-resistant sputum samples, determined by metal ion analysis, were found to inhibit enzyme activity in studies using seaweed alginate as a substrate. High concentrations of Ca2+ and Zn2+ in sputum samples initially resistant to lyase activity could be reduced significantly in some samples by dialysis and these same samples acquired sensitivity to the lyase. Other sputum samples did not show reduced concentrations of Ca2+ and Zn2+ following dialysis and these samples remained lyase-insensitive. Together, these results suggest that bacterial alginate present within purulent CF sputum may be quite stable, that endogenous alginate lyase activities appear to be limited and that the in vitro addition of exogenous alginate lyase can lead to the disruption of alginate and a change in the viscoelastic properties of some purulent CF sputum samples.

The activity of the Escherichia coli transcription factor FNR is regulated by a change in oligomeric state.

The transcription factor FNR globally regulates gene expression in response to oxygen deprivation in Escherichia coli. To understand how oxygen deprivation activates FNR, a constitutively active FNR* mutant protein, DA154, was studied to determine how this mutant bypassed the normal regulation pathway. When purified from aerobically grown cells, the DA154 protein had a larger apparent native molecular mass and an increased affinity for a consensus FNR target site as compared with wild-type FNR prepared under identical conditions. These results suggested that FNR* DA154 may bypass the normal regulation pathway by converting FNR from an inactive monomer to an active dimer under aerobic conditions. To determine whether wild-type FNR is active as a dimer under anaerobic conditions, FNR mutants were isolated that inhibit the activity of wild-type FNR by forming mixed dimers (i.e., dominant-negative mutants). These dominant-negative FNR mutants were shown to have substitutions in the putative DNA-binding domain and to be defective in binding to a consensus FNR DNA target site in vitro. One representative dominant-negative mutant, EK209, was also shown to be unable to form mixed oligomers in vivo under aerobic conditions, suggesting that FNR may be monomeric in the inactive state. Taken together, these data have led us to propose that under anaerobic conditions FNR is a dimer that is active for DNA binding, and under aerobic conditions, FNR is inactivated by conversion to a monomer.