Efficacy assessment of PEV2 phage on Galleria mellonella larvae infected with a Pseudomonas aeruginosa dog otitis isolate.

Pseudomonas (P.) aeruginosa is the most frequently isolated Gram-negative bacteria in dog otitis. Antimicrobial resistance is particularly prevalent in P. aeruginosa and phage therapy represents a promising alternative therapeutic strategy. The aim of this study was to assess the efficacy of the PEV2 phage against a clinical P. aeruginosa isolate from a canine otitis using a Galleria (G.) mellonella larvae model. The genomic DNA of PAV237 P. aeruginosa isolate was sequenced and analysed. In a first main experiment, the efficacy of PEV2 phage against PAV237 was assessed at different multiplicities of infection (MOI) (50,000, 5000, 500, 50) by analyzing the larvae survival rate during 4 days. In a second experiment, the bacterial and phage titer evolutions were assessed depending on two MOIs (50,000, 5000). No significant survival increase was observed with PEV2 therapy in the infected larvae groups. The generated Kaplan-Meier curves showed that the rate of alive larvae was significantly higher in the non-infected larvae compared to the infected-treated ones irrespective of phage MOIs. An increase of the phage titer was observed at 24 and 48 h post-inoculation (HPI) with both MOIs and the P. aeruginosa titers were lower with MOI 50,000 and 5000 compared to the infectivity control at 24 and 48 HPI. Even if an ineffectiveness of the PEV2 phage was observed on the larvae survival, PEV2 is active against P. aeruginosa in this model and PEV2 replication is correlated with a lower bacterial proliferation in the phage treated larvae.

Pharmacokinetics/pharmacodynamics of antipseudomonal bacteriophage therapy in rats: a proof-of-concept study.

OBJECTIVES: Pan-drug-resistant (PDR) Pseudomonas aeruginosa is one of the three top-priority pathogens identified by the WHO, and bacteriophages have been investigated as an alternative therapy. However, knowledge on the pharmacokinetics/pharmacodynamics (PK/PD) of phage therapy is sparse, limiting its clinical applications. This study aimed to evaluate the PK/PD of the antipseudomonal phage øPEV20 in vivo following intravenous administration. METHODS: Healthy Sprague-Dawley rats were given øPEV20 as a single intravenous bolus of ~6, 9 and 11-log10PFU/rat. Arterial blood was sampled over 72 h. At 72 h, the animals were killed and multiple tissues were harvested for biodistribution studies. A PK model was developed using the importance sampling algorithm and deterministic simulations with a PD model were performed. RESULTS: A three-compartment model with non-linear clearance described the exposure of øPEV20 in blood. Model evaluation indicated that the model was robust and parameter estimates were accurate. The median (standard error) values of model-predicted PK parameters for VC, VP1, VP2, Q1, Q2, Vm and Km were 111 mL/rat (8.5%), 128 mL/rat (4.97%), 180 mL/rat (4.59%), 30.4 mL/h/rat (19.2%), 538 mL/h/rat (4.97%), 4.39 × 1010 PFU/h/rat (10.2%) and 1.64 × 107 PFU/mL/rat (3.6%), respectively. The distribution of øPEV20 was not homogeneous; there was preferential accumulation in the liver and spleen. Deterministic simulations with a PD model confirmed the importance of the host immune system in facilitating phage-mediated bacterial elimination. CONCLUSIONS: We developed a robust PK model to describe the disposition of phages in healthy rats. This model may have significant potential in facilitating future preclinical and clinical PK/PD investigations.

Bacteriophage Therapy as a Potential Management Option for Surgical Wound Infections.

To investigate the potential role of bacteriophages in the treatment of surgical infections, we conducted a retrospective analysis of four surgical patients who have sought treatment at the Eliava Phage Therapy Center, Tbilisi, Georgia. Two patients had chronic osteomyelitis, one presented with a diabetic foot ulcer, and the fourth patient had developed a severe infectious complication after skin grafting surgery. Patients were treated with different combinations of bacteriophage preparations, based on the sensitivity of the isolated bacterial strain toward commercially available bacteriophages. The treatment lasted on average for 1 month, and positive results were obtained in all four cases: the wounds have healed, the general health status of the patients has improved. No allergic or adverse reactions have been observed throughout the treatment.

An online adaptive screening procedure for selective neuronal responses.

BACKGROUND: A common problem in neurophysiology is to identify stimuli that elicit neuronal responses in a given brain region. Particularly in situations where electrode positions are fixed, this can be a time-consuming task that requires presentation of a large number of stimuli. Such a screening for response-eliciting stimuli is employed, e.g., as a standard procedure to identify 'concept cells' in the human medial temporal lobe. NEW METHOD: Our new method evaluates neuronal responses to stimuli online during a screening session, which allows us to successively exclude stimuli that do not evoke a response. Using this method, we can screen a larger number of stimuli which in turn increases the chances of finding responsive neurons and renders time-consuming offline analysis unnecessary. RESULTS: Our method enabled us to present 30% more stimuli in the same period of time with additional presentations of the most promising candidate stimuli. Our online method ran smoothly on a standard computer and network. COMPARISON WITH AN EXISTING METHOD: To analyze how our online screening procedure performs in comparison to an established offline method, we used the Wave_Clus software package. We did not observe any major drawbacks in our method, but a much higher efficiency and analysis speed. CONCLUSIONS: By transitioning from a traditional offline screening procedure to our new online method, we substantially increased the number of visual stimuli presented in a given time period. This allows to identify more response-eliciting stimuli, which forms the basis to better address a great number of questions in cognitive neuroscience.

Prevalence of Escherichia coli O157 and O157:H7-infecting bacteriophages in feedlot cattle feces.

AIM: To estimate the distribution and prevalence of both Escherichia coli O157 and O157:H7-infecting bacteriophages within a 50,000 head commercial beef feedlot. METHODS AND RESULTS: Escherichia coli O157 was detected in approximately 27% of the individual samples, distributed across seven of the 10 pens screened. In a simple initial screen to detect O157:H7-infecting phages, none were detected in any pen or individual sample. In contrast, after a series of enrichment procedures O157:H7-infecting phages were detected in every pen and in the majority of the samples from most pens; virulent bacteriophages active against E. coli O157:H7 were detected post-enrichment from 39/60 (65%) of the feedlot samples, and 58/60 (approximately 97%) contained phage that infected E. coli B or O157:H7. CONCLUSIONS: The data we present here indicates that we may be grossly underestimating the prevalence of O157:H7-infecting phages in livestock if we simply screen samples and that enrichment screening is required to truly determine the presence of phages in these ecosystems. SIGNIFICANCE AND IMPACT OF THE STUDY: Our data suggest that O157:H7-infecting phages may play a role in the ecology and transient colonization of cattle by E. coli O157:H7. Further, this and previous data suggest that before starting in vivo pathogen eradication studies using phage or any other regime, test animals should be enrichment screened for phage to avoid erroneous results.

Fecal prevalence of Escherichia coli O157, Salmonella, Listeria, and Bacteriophage Infecting E. coli O157:H7 in feedlot cattle in the Southern Plains region of the United States.

Escherichia coli O157:H7, Salmonella, and Listeria are foodborne pathogens of critical importance that often colonize cattle. E. coli O157:H7 can be specifically killed by lytic bacteriophage, and lytic bacteriophage treatment has been suggested as a pre-harvest intervention strategy to reduce foodborne pathogens in cattle. To date, no systematic approach to determine the incidence of E. coli O157:H7-infecting lytic bacteriophage has been published. Therefore, the current study was designed to determine (1) the incidence of E. coli O157, Salmonella spp., and Listeria and (2) the incidence of E. coli O157:H7-infecting bacteriophage in the feces of feedlot steers in commercial feedlots in the United States. Fecal samples (n=60) were collected from four feedlots in two Southern Great Plains states (total (n=240 fecal samples). Salmonella and E. coli O157:H7 were found in 3.8% and 11.7% of the fecal samples, respectively. Bacteriophage targeting E. coli O157:H7 were found in all four feedlots, in 15% of the individual fecal samples, and in 55% of the cattle pens. Our results indicate that such bacteriophage are widespread in feedlot cattle, suggesting that further research into the ecological role of bacteriophage in the gastrointestinal tract is needed.

Effects of the antibiotic ionophores monensin, lasalocid, laidlomycin propionate and bambermycin on Salmonella and E. coli O157:H7 in vitro.

AIMS: To examine the effects of ionophores on Salmonella and Escherichia coli O157:H7 in pure and mixed ruminal fluid cultures. METHODS AND RESULTS: Four Salmonella serotypes (Dublin, Derby, Typhimurium, and Enteriditis) and two strains of E. coli O157:H7 (ATCC 43895 and FDIU 6058) were cultured in the presence of varying concentrations of ionophores (monensin, lasalocid, laidlomycin propionate, and bambermycin) in pure and mixed ruminal fluid cultures. Bacterial growth rates in pure culture were not affected (P > 0.10) by ionophores at concentrations up to 10 times the approximate rumen ionophore concentration under normal feeding regimens. Likewise, ionophores had no effect (P > 0.10) on Salmonella or E. coli CFU plated from 24-h ruminal fluid incubations. Ionophore treatment decreased (P < 0.01) the acetate : propionate ratio in ruminal fluid cultures as expected. CONCLUSIONS: Ionophores had no effect on the foodborne pathogens Salmonella and E. coli O157:H7 in vitro. SIGNIFICANCE AND IMPACT OF THE STUDY: The results suggest that ionophore feeding would have little or no effect on Salmonella or E. coli populations in the ruminant.

The roles of the bacteriophage T4 r genes in lysis inhibition and fine-structure genetics: a new perspective.

Seldom has the study of a set of genes contributed more to our understanding of molecular genetics than has the characterization of the rapid-lysis genes of bacteriophage T4. For example, T4 rII mutants were used to define gene structure and mutagen effects at the molecular level and to help unravel the genetic code. The large-plaque morphology of these mutants reflects a block in expressing lysis inhibition (LIN), the ability to delay lysis for several hours in response to sensing external related phages attacking the cell, which is a unique and highly adaptive attribute of the T4 family of phages. However, surprisingly little is known about the mechanism of LIN, or how the various r genes affect its expression. Here, we review the extensive old literature about the r genes and the lysis process and try to sort out the major players affecting lysis inhibition. We confirm that superinfection can induce lysis inhibition even while infected cells are lysing, suggesting that the signal response is virtually instantaneous and thus probably the result of post-translational regulation. We identify the rI gene as ORF tk.-2, based on sequence analysis of canonical rI mutants. The rI gene encodes a peptide of 97 amino acids (Mr = 11.1 kD; pI = 4.8) that probably is secreted into the periplasmic space. This gene is widely conserved among T-even phage. We then present a model for LIN, postulating that rI is largely responsible for regulating the gpt holin protein in response to superinfection. The evidence suggests that the rIIA and B genes are not directly involved in lysis inhibition; rather, when they are absent, an alternate pathway for lysis develops which depends on the presence of genes from any of several possible prophages and is not sensitive to lysis inhibition.

Comparison of synonymous codon distribution patterns of bacteriophage and host genomes.

Synonymous codon usage patterns of bacteriophage and host genomes were compared. Two indexes, G + C base composition of a gene (fgc) and fraction of translationally optimal codons of the gene (fop), were used in the comparison. Synonymous codon usage data of all the coding sequences on a genome are represented as a cloud of points in the plane of fop vs. fgc. The Escherichia coli coding sequences appear to exhibit two phases, "rising" and "flat" phases. Genes that are essential for survival and are thought to be native are located in the flat phase, while foreign-type genes from prophages and transposons are found in the rising phase with a slope of nearly unity in the fgc vs. fop plot. Synonymous codon distribution patterns of genes from temperate phages P4, P2, N15 and lambda are similar to the pattern of E. coli rising phase genes. In contrast, genes from the virulent phage T7 or T4, for which a phage-encoded DNA polymerase is identified, fall in a linear curve with a slope of nearly zero in the fop vs. fgc plane. These results may suggest that the G + C contents for T7, T4 and E. coli flat phase genes are subject to the directional mutation pressure and are determined by the DNA polymerase used in the replication. There is significant variation in the fop values of the phage genes, suggesting an adjustment to gene expression level. Similar analyses of codon distribution patterns were carried out for Haemophilus influenzae, Bacillus subtilis, Mycobacterium tuberculosis and their phages with complete genomic sequences available.

Evolution of T4-related phages.

Much progress has been made in understanding T-even phage biology in the last 50 years. We now know the entire sequence of T4, encoding nearly 300 genes, only 69 of which have been shown to be essential under standard laboratory conditions; no specific function is yet known for about 140 of them. The origin of most phage genes is unclear, and only 42 genes in T4 have significant similarity to anything currently included in GenBank. Comparative analysis of related phages is now being used to gain insight into both the evolutionary origins and interrelationships of these phage genes, and the functions of their protein products. The genomes of phages isolated from Tbilisi hospitals, Long Island sewage plants, the Denver zoo, and Khabarovsk show basic similarity. However, these phages show substantial insertions and deletions in a number of regions relative to each other, and closer investigation of specific sequences often reveals much more complex relationships. There are only a few cases in T4-related phages in which there is evidence for evolution through DNA duplication. These include the fibrous products of genes 12, 34, and 37; head proteins gp23 and gp24; and the Alt enzyme and its downstream neighbors. T4 also contains 13 apparent relatives of group I and group II intron homing endonucleases. Distal portions of the tail fibers of various T-even phages contain segments closely related to tail-fiber regions of other DNA coliphages, such as Mu, P1, P2, and lambda. Horizontal gene transfer clearly emerges as a major factor in the evolution of at least the tail-fiber regions, where site-specific recombination probably is involved in the exchange of host-range determinants.

A non-essential domain of Escherichia coli RNA polymerase required for the action of the termination factor Alc.

An evolutionarily nonconserved region of approximately 250 amino acids can be deleted from the amino-terminal part of the beta subunit of Escherichia coli RNA polymerase without effect on the enzyme's basic function. The non-essential segment is located between two highly conserved motifs and is flanked by sequences participating in the rifampicin-binding site. The results define the second non-essential domain in the beta subunit, in addition to the more distal dispensable segment identified previously. The Alc protein of bacteriophage T4 participates in the host transcription shutoff after infection by causing premature termination of transcription on E. coli DNA. Point mutations which prevent Alc action in vivo change amino acids in the non-essential NH2-terminal domain of the beta subunit. These point mutations as well as deletions which remove the non-essential region also prevent Alc action. Thus, in the RNA polymerase molecule, the proximal non-essential domain of beta may function as an acceptor of Alc or other regulatory factors.

Identification of bacteriophage T4 prereplicative proteins on two-dimensional polyacrylamide gels.

Bacteriophage T4 makes a large number of prereplicative proteins, which are involved in directing the transition from host to phage functions, in producing the new T4 DNA, and in regulating transcriptional shifts. We have used two-dimensional gel electrophoresis (nonequilibrium pH gradient electrophoresis gels in the first dimension and sodium dodecyl sulfate-polyacrylamide gradient slab gels in the second) to identify a number of new prereplicative proteins. The products of many known genes are identified because they are missing in mutants with amber mutations of those genes, as analyzed by us and/or by previous workers. Some have also been identified by running purified proteins as markers on gels with labeled extracts from infected cells. Other proteins that are otherwise unknown are characterized as missing in infections with phage carrying certain large deletions and, in some cases, are correlated with sequence data.

Bacteriophage T4 Alc protein: a transcription termination factor sensing local modification of DNA.

Bacteriophage T4 Alc protein participates in shutting off host transcription after infection of E. coli. It is demonstrated that Alc acts as a site-specific termination factor. The Alc sites occur frequently in E. coli DNA, resulting in early cessation of elongation in several tested transcription units. Alc-dependent termination requires unimpeded propagation of the elongating complex as it approaches the Alc site. Temporary halting of RNA polymerase within 10-15 bp before the Alc site prevents termination. Bacteriophage T4 transcription is protected from the action of Alc by overall substitution of cytosine with 5-hydroxymethyl cytosine in T4 DNA. In vitro methylation of CpG sequences in the vicinity of an Alc site abolishes the effect of Alc. Thus, Alc-dependent termination involves local sensing of the state of cytosine modification and a short-term "memory" of recent pausing.

Inhibition of transcription of cytosine-containing DNA in vitro by the alc gene product of bacteriophage T4.

The alc gene product (gpalc) of bacteriophage T4 inhibits the transcription of cytosine-containing DNA in vivo. We examined its effect on transcription in vitro by comparing RNA polymerase isolated from Escherichia coli infected with either wild-type T4D+ or alc mutants. A 50 to 60% decline in RNA polymerase activity, measured on phage T7 DNA, was observed by 1 min after infection with either T4D+ or alc mutants; this did not occur when the infecting phage lacked gpalt. In the case of the T4D+ strain but not alc mutants, this was followed by a further decrease. By 5 min after infection the activity of alc mutants was 1.5 to 2.5 times greater than that of the wild type on various cytosine-containing DNA templates, whereas there was little or no difference in activity on T4 HMdC-DNA, in agreement with the in vivo specificity. Effects on transcript initiation and elongation were distinguished by using a T7 phage DNA template. Rifampin challenge, end-labeling with [gamma-32P]ATP, and selective initiation with a dinucleotide all indicate that the decreased in vitro activity of the wild-type polymerase relative to that of the alc mutants was due to inhibition of elongation, not to any difference in initiation rates. Wild-type (but not mutated) gpalc copurified with RNA polymerase on heparin agarose but not in subsequent steps. Immunoprecipitation of modified RNA polymerase also indicated that gpalc was not tightly bound to RNA polymerase intracellularly. It thus appears likely that gpalc inhibits transcript elongation on cytosine-containing DNA by interacting with actively transcribing core polymerase as a complex with the enzyme and cytosine-rich stretches of the template.

Comparative absorption of zinc picolinate, zinc citrate and zinc gluconate in humans.

The comparative absorption of zinc after oral administration of three different complexed forms was studied in 15 healthy human volunteers in a double-blind four-period crossover trial. The individuals were randomly divided into four groups. Each group rotated for four week periods through a random sequence of oral supplementation including: zinc picolinate, zinc citrate, and zinc gluconate (equivalent to 50 mg elemental zinc per day) and placebo. Zinc was measured in hair, urine, erythrocyte and serum before and after each period. At the end of four weeks hair, urine and erythrocyte zinc levels rose significantly (p less than 0.005, p less than 0.001, and p less than 0.001) during zinc picolinate administration. There was no significant change in any of these parameters from zinc gluconate, zinc citrate or placebo administration. There was a small, insignificant rise in serum zinc during zinc picolinate, zinc citrate and placebo supplementation. The results of this study suggest that zinc absorption in humans can be improved by complexing zinc with picolinic acid.

Identification and characterization of the alc gene product of bacteriophage T4.

Bacteriophage T4 infection rapidly and almost completely inhibits transcription of host and other phage DNAs. Two processes have been implicated to date in this inhibition: (1) ADP ribosylation of the alpha subunits of the RNA polymerase, involving gpalt (which is injected with the phage DNA) and, later, gpmod; and (2) the action of the T4 alc/unf gene product, synthesized immediately after infection. The latter unfolds the host genome and also blocks transcription of cytosine-containing DNA. Here, we describe the identification on two-dimensional polyacrylamide gels of gpalc/unf, the more precise mapping of the gene and the identification and analysis of the appropriate DNA sequence from an Unf+ alc mutant.

Regulation of a bacteriophage T4 late gene, soc, which maps in an early region.

We have sequenced and analyzed the expression of an early region of the bacteriophage T4 genome that surprisingly contains a late gene, soc. soc is oriented in the same direction as early genes, like the T4 lysozyme gene. Northern hybridization of early and late T4 RNA, using cloned T4 restriction fragments as probes, identified two long early transcripts and a short late transcript, all containing the soc-coding sequence. Thus, soc is transcribed both early and late. It is, however, translated only late. The inhibition of soc translation from the long early transcripts can be explained by formation of a hairpin in the RNA that sequesters the soc ribosome-binding site. The transcript initiated at the late promoter cannot form this hairpin and is, therefore, translated.

Inhibition of [3H]diazepam and [3H]3-carboethoxy-beta-carboline binding by irazepine: evidence for multiple "domains" of the benzodiazepine receptor.

The binding of [3H]diazepam and [3H]3-carboethoxy-beta-carboline was examined in rat brain synaptosomal membranes treated with irazepine, an alkylating benzodiazepine. Under incubation conditions that resulted in a 25-33% reduction in the Bmax of [3H]diazepam binding, only modest (less than 8.5%) reductions in the Bmax of [3H]3-carboethoxy-beta-carboline were observed. The differential effects of irazepine on the binding of these two compounds may be explained by the presence of multiple areas or "domains" on the benzodiazepine receptor.

Bacteriophage T4 alc gene product: general inhibitor of transcription from cytosine-containing DNA.

The alc gene of bacteriophage T4 was originally defined on the basis of mutations which allow late protein synthesis directed by T4 DNA containing cytosine rather than hydroxymethylcytosine. The question remained whether the normal alc gene product (gpalc) also blocks the transcription of early genes from cytosine-containing DNA. Complementation experiments were performed between hydroxymethylcytosine-containing phage which direct gpalc synthesis but carry mutations in a given gene(s) and cytosine-containing phage carrying that gene(s). The required protein would then have to be directed by the cytosine-containing DNA: it is looked for directly on polyacrylamide gels or through its physiological effects or both. For all early proteins examined in this way, no synthesis was observed when 95 to 100% of the hydroxymethylcytosine was substituted by cytosine in the infecting DNA, whereas there was significant synthesis with 75% substitution or less. The results indicate that gpalc is carried in with the infecting DNA or is made very early to block transcription of all cytosine-containing DNA.