Effect of neuropeptide S receptor antagonists and partial agonists on palatable food consumption in the rat

Neuropeptide S (NPS) is the endogenous ligand for the previously orphan G-protein-coupled-receptor, now termed NPS receptor (NPSR). NPS has both anxiolytic and pro-arousal properties and decreases food intake. In this work we use a rat model of palatable food intake to test in vivo different analogs of human NPS developed in our laboratories and characterized in previous in vitro experiments as partial agonists ([Ala³]NPS and [Aib⁵]NPS), or antagonists ([d-Cys(^tBu)⁵]NPS and [^tBu-d-Gly⁵]NPS). Our results confirmed that intracerebroventricular (ICV) injection of NPS (1 nmol) decreases standard chow intake in food restricted rats as well as in freely feeding animals fed with standard or palatable food diets. [Aib⁵]NPS (30 and 60 nmol), like NPS, reduced palatable food intake, thus confirming in vivo its ability to activate NPSR. [Ala³]NPS (60 nmol) did not affect palatable food intake per se but blocked the anorectic effect of NPS, thus suggesting its ability to function as an antagonist in this model. Finally, [d-Cys(^tBu)⁵]NPS (20-60 nmol) and [^tBu-d-Gly⁵]NPS (10-30 nmol), described in previous in vitro studies as pure NPSR antagonists, did not affect palatable food intake when given alone, but fully blocked the anorectic effect of NPS. These results provide an important characterization of the pharmacological properties of these NPS analogs in vivo. Of particular relevance are the data showing that [d-Cys(^tBu)⁵]NPS and [^tBu-d-Gly⁵]NPS behave as pure antagonists at NPSR regulating food intake, indicating that these molecules are suitable tools for further investigation of the physiopharmacology of the NPS/NPSR system.     

Neuropeptide S stimulates human monocyte chemotaxis via NPS receptor activation

Neuropeptide S (NPS) produces several biological actions by activating a formerly orphan GPCR, now named NPS receptor (NPSR). It has been previously demonstrated that NPS stimulates murine leukocyte chemotaxis in vitro. In the present study we investigated the ability of NPS, in comparison with the proinflammatory peptide formyl-Met-Leu-Phe (fMLP), to stimulate human monocyte chemotaxis. At a concentration of 10⁻⁸ M fMLP significantly stimulated chemotaxis. NPS produced a concentration dependent chemotactic action over the concentration range 10⁻¹² to 10⁻⁵ M. The NPSR antagonists [d-Cys(^tBu)⁵]NPS, [^tBu-d-Gly⁵]NPS and SHA 68 were used to pharmacologically characterize NPS action. Monocyte chemoattractant effect of NPS, but not fMLP, was completely blocked by either peptide antagonists or SHA with the nonpeptide molecule being more potent. None of the NPSR antagonists modified per se random cell migration. Thus, the present study demonstrated that NPS is able to stimulate human monocyte chemotaxis and that this effect is entirely due to selective NPSR activation.     

Analysis of the collar-whisker structure of temperate lactococcal bacteriophage TP901-1

Proteins homologous to the protein NPS (neck passage structure) are widespread among lactococcal phages. We investigated the hypothesis that NPS is involved in the infection of phage TP901-1 by analysis of an NPS- mutant. NPS was determined to form a collar-whisker complex but was shown to be nonessential for infection, phage assembly, and stability.     

Generalized Transduction of Small Yersinia enterocolitica Plasmids

To study phage-mediated gene transfer in Yersinia, the ability of Yersinia phages to transduce naturally occurring plasmids was investigated. The transduction experiments were performed with a temperate phage isolated from a pathogenic Yersinia enterocolitica strain and phage mixtures isolated from sewage. Small plasmids (4.3 and 5.8 kb) were transduced at a frequency of 10⁻⁵ to 10⁻⁷/PFU. However, we could not detect the transduction of any indigenous virulence plasmid (ca. 72 kb) in pathogenic Yersinia strains. Transductants obtained by infection with the temperate phage were lysogenic and harbored the phage genome in their chromosomes.     

Efficacy of cocktail phage therapy in treating Vibrio cholerae infection in rabbit model

Ability of a cocktail of five lytic vibriophages to combatting Vibrio cholerae O1 infection in rabbit model was examined. In one group, rabbits were administered 1 × 10⁸ plaque forming unit of phage cocktail 6 and 12 h prior to the administration of V. cholerae O1, while in the other group, same procedure was applied 6 and 12 h post infection. It was observed that oral administration of the phage cocktail after oral bacterial challenge lowered the shedding of bacteria significantly (p < 0.01). In contrast phage treatment prior to bacterial challenge had no such effect (p > 0.05). Results suggest that oral administration of phage subsequent to V. cholerae challenge could provide a possible means of combatting V. cholerae infection.     

Spackle and Immunity Functions of Bacteriophage T4

Cells of Escherichia coli B infected with the immunity-negative (imm2) mutant of bacteriophage T4 are able to develop a substantial level of immunity to superinfecting phage ghosts if the ghost challenge is made late in infection. This background immunity is not seen in infections with phage carrying the spackle (s) mutation in addition to the imm2 lesion. The level of immunity in s⁻ infections is intermediate between that of imm⁻ and wild-type infections under standard assay conditions. With respect to genetic exclusion of superinfecting phage, cells infected with imm⁻ phage are completely deficient, whereas infections with the s⁻ phage are only partially deficient compared to wild-type infections. Whereas s⁻-infected cells are unable to resist lysis from without by a high multiplicity of infection (MOI) of superinfecting phage, cells infected with imm⁻ phage show less than wild-type levels of resistance and the majority of cells remaining intact are unable to incorporate leucine or form infective centers. Under conditions of superinfection by low MOI of homologous phage, imm⁻-infected cells are lysis inhibited, whereas s⁻-infected cells do not show this property. Superinfecting phage inject their DNA into imm⁻-infected cells with the same efficiency as seen in wild-type infections, but this efficiency is reduced when the cells are first infected with s⁻ phage. The s function of T4 appears not only to affect the host cell wall as previously postulated by Emrich, but may also affect the junctures of cell wall and membrane with consequences similar to those of the imm function.     

Ter mutation and susceptibility to phi X174 phage in E. coli K12.

The Ter-15 mutant derived from E. coli K12 W2252-11U^? RC^str (wild type I) is found to be sensitive to φx174 phage infection. Lipopolysaccharide extracted from this mutant inactivates the phage, and has core oligosaccharides identical in amounts to those in the lipopolysaccharide from wild type cells.In contrast, the Ter-21 mutant derived from E. coli K12 W2252-11U^? RC^rel (wild type II) is not sensitive to this phage infection, and its lipopolysaccharide does not inactivate the phage. Its lipopolysaccharide sugars are found to be D-glucose and D-ribose, thus differing from the lipopolysaccharide sugars of the wild type cells.     

Intracellular events during infection by Haemophilus influenzae phage and transfection by its DNA

Intracellular events following infection of competent Haemophilus influenzae by HPlcl phage, or transfection by DNA from the phage, were examined. Physical separation of a large fraction of the intracellular phage DNA from the bulk of the host DNA was achieved by lysis of infected or transfected cells with digitonin, followed by low-speed centrifugation. The small amount of bacterial DNA remaining with the phage DNA in the supernatants could be distinguished from phage DNA by its ability to yield transformants. After infection by whole phage, three forms of intracellular phage DNA were observable by sedimentation velocity analysis: form III, the slowest-sedimenting one; form II, which sedimented 1.1 times faster than III, and form I, which sedimented 1.6 times faster than III. It was shown by electron microscopy, velocity sedimentation in alkali, and equilibrium sedimentation with ethidium bromide, that forms I, II and III are twisted circles, open circles, and linear duplexes, respectively.After the entry of phage DNA into wild-type cells in transfection, the DNA is degraded at early times, but later some of the fragments are reassembled, resulting in molecules that sediment faster than the monomer length of phage DNA. Some of the fast-sedimenting molecules are presumably concatemers and are generated by recombination. In strain rec₁^? the fast-sedimenting molecules do not appear and degradation of phage DNA is even more pronounced than in wild-type cells. In strain rec₂^? there is little degradation of phage DNA, and the proportion of fast-sedimenting molecules is much smaller than in wild-type cells. Since rec₁^? and rec₂^? are transfected with much lower efficiency than wild type, our hypothesis is that both fragmentation and generation of fast-sedimenting phage DNA by recombination are required for more efficient transfection.     

Modeling the fitness consequences of a cyanophage-encoded photosynthesis gene

Background

Phages infecting marine picocyanobacteria often carry a psbA gene, which encodes a homolog to the photosynthetic reaction center protein, D1. Host encoded D1 decays during phage infection in the light. Phage encoded D1 may help to maintain photosynthesis during the lytic cycle, which in turn could bolster the production of deoxynucleoside triphosphates (dNTPs) for phage genome replication.

Methodology / Principal Findings

To explore the consequences to a phage of encoding and expressing psbA, we derive a simple model of infection for a cyanophage/host pair — cyanophage P-SSP7 and Prochlorococcus MED4— for which pertinent laboratory data are available. We first use the model to describe phage genome replication and the kinetics of psbA expression by host and phage. We then examine the contribution of phage psbA expression to phage genome replication under constant low irradiance (25 µE m⁻² s⁻¹). We predict that while phage psbA expression could lead to an increase in the number of phage genomes produced during a lytic cycle of between 2.5 and 4.5% (depending on parameter values), this advantage can be nearly negated by the cost of psbA in elongating the phage genome. Under higher irradiance conditions that promote D1 degradation, however, phage psbA confers a greater advantage to phage genome replication.

Conclusions / Significance

These analyses illustrate how psbA may benefit phage in the dynamic ocean surface mixed layer.     

Bacteriophage T4 Virion Baseplate Thymidylate Synthetase and Dihydrofolate Reductase

Additional evidence is presented that both the phage T4D-induced thymidylate synthetase (gp td) and the T4D-induced dihydrofolate reductase (gp frd) are baseplate structural components. With regard to phage td it has been found that: (i) low levels of thymidylate synthetase activity were present in highly purified preparations of T4D ghost particles produced after infection with td⁺, whereas particles produced after infection with td⁻ had no measurable enzymatic activity; (ii) a mutation of the T4D td gene from td^ts to td⁺ simultaneously produced a heat-stable thymidylate synthetase enzyme and heat-stable phage particles (it should be noted that the phage baseplate structure determines heat lability); (iii) a recombinant of two T4D mutants constructed containing both td^ts and frd^ts genes produced particles whose physical properties indicate that these two molecules physically interact in the baseplate. With regard to phage frd it has been found that two spontaneous revertants each of two different T4D frd^ts mutants to frd⁺ not only produced altered dihydrofolate reductases but also formed phage particles with heat sensitivities different from their parents. Properties of T4D particles produced after infection with parental T4D mutants presumed to have a deletion of the td gene and/or the frd gene indicate that these particles still retain some characteristics associated with the presence of both the td and the frd molecules. Furthermore, the particles produced by the deletion mutants have been found to be physically different from the parent particles.     

Role of <Emphasis Type="Italic">sie</Emphasis> Gene in Transient Depression of Macromolecular Synthesis in Phage P22-infected <Emphasis Type="Italic">Salmonella typhimurium</Emphasis>

WE have shown that induction of the enzyme L-arabinose isomerase in Salmonella typhimurium ceases following infection with the bacteriophage P22 leading to lysis, whereas with infection leading to lysogeny there is a temporary inhibition of induction after which the synthesis of the enzyme begins again¹. After infection, there is a transient depression of the overall rate of RNA and protein synthesis¹. This phenomenon is similar to that observed in T-even phage and λ-infected E. coli^2–5. Arguments for and against the involvement of phage genes^2–12 in such phenomena have been put forward. We now present evidence to suggest that the sie gene of phage P22 is involved in the inhibition of host macromolecular synthesis.     

High-frequency transduction of pBR322 by cytosine-substituted T4 bacteriophage: evidence for encapsulation and transfer of head-to-tail plasmid concatemers

Transduction of plasmid pBR322 by cytosine-substituted T4 phages has been studied. Three T4 phage mutants which substitute cytosine for all of hydroxymethylcytosine residues in the DNA, were shown to transduce pBR322 at frequencies of 2 × 10^?2 to 4 × 10^?3 transductants per singly infected cell. Also, three T4 phage strains which partially substitute cytosine for hydroxymethylcytosine, transduced pBR322 at frequencies of 2 × 10^?3 to 2 × 10^?4. The transduction frequencies of pBR322 we attained are at least 10-fold higher than those reported by G. G. Wilson, K. Young, and G. J. Edlin (1979, Nature (London)280, 80–82). We found that multiplicity of infection in preparation of the transducing phage is the most important factor affecting the frequency of pBR322 transduction. When a lysate made at a multiplicity of infection ranging from 0.5 to 0.05 was used as the donor phage, transduction frequency of pBR322 was 10- to 40-fold higher than that of high-m.o.i. lysate. The transduction frequency was not affected by either restriction systems or amber suppressors of the recipient cells. However, no pBR322-containing transductant was obtained when either recA or polA mutants were used as the recipients. DNA from T4dC phage containing pBR322-transducing particles was analyzed on agarose gel electrophoresis after cleavage with restriction endonucleases. It was suggested that the pBR322 DNA in the T4dC phage particles exists as head-to-tail concatemers.     

Concomitant Conjugal Transfer of Reduced-Bacteriophage-Sensitivity Mechanisms with Lactose- and Sucrose-Fermenting Ability in Lactic Streptococci

Ten previously reported lactose-positive (Lac⁺) transconjugants from Streptococcus lactis, S. cremoris, and S. lactis subsp. diacetylactis and one sucrose-positive (Suc⁺) transconjugant from S. lactis were examined for their sensitivity to prolate- and small isometric-headed bacteriophages. Four of the Lac⁺ transconjugants showed a 10- to 100-fold reduction in the efficiency of plating (EOP) as well as a reduced plaque size for the prolate phage c2 and were insensitive to the small isometric phage 712. A fifth Lac⁺ transconjugant demonstrated a similar reduced sensitivity to phage c2; however, this transconjugant was able to plaque phage 712, but with a reduced plaque size and EOP. The other five Lac⁺ transconjugants were sensitive to both c2 and 712 phages. The Suc⁺ transconjugant plaqued phage 712 with a reduced plaque size and EOP, but no reduction in plaque size or EOP was observed for phage c2. The Lac⁺ and reduced bacteriophage sensitivity (Rbs⁺) phenotypes were correlated with specific plasmids in the Lac⁺ transconjugants. As four of the Lac⁺ transconjugants exhibited a phenotypically indistinguishable Rbs⁺, one (AB001) was selected for further study. The Rbs⁺ in AB001 for both small isometric- and prolate-headed phages was not related to adsorption, and the reduced EOP for phage c2 was not related to the presence of a restriction and modification system. The latent period for phage c2 was unchanged, but the burst size was reduced 80%. The presence of the plasmid coding for Rbs⁺ retarded the lysis of a mitomycin C-induced prophage-containing strain. The Rbs⁺ mechanism appears to be abortive phage infection. This study supports previous observations that Rbs⁺ and conjugal transfer ability are physically linked among some group N streptococci. The results presented have implications in the identification of plasmids coding for Rbs⁺ and may also aid in explaining the dissemination of Rbs⁺ genes among lactic streptococci.     

A Strategy for Rotation of Different Bacteriophage Defenses in a Lactococcal Single-Strain Starter Culture System

A new strategy for starter culture rotations was developed for a series of phage-resistant clones genetically derived from a single strain of Lactococcus lactis subsp. lactis. Phage-resistant derivatives carrying different defense systems were constructed via conjugation with various plasmids encoding abortive infection (Abi/Hsp) and/or restriction and modification (R/M) systems of different specificity. The plasmids included pTR2030 (Hsp⁺ R⁺/M⁺), pTN20 (Abi⁺ R⁺/M⁺), pTRK11 (R⁺/M⁺), and pTRK68 (R⁺/M⁺). Selected phage-resistant transconjugants or transformants were evaluated in different rotation sequences through cycles of the Heap-Lawrence starter culture activity test in milk contaminated with phage and whey from the previous cycle. When used in consecutive sequence, derivative strains carrying the R/M systems encoded by pTN20, pTRK11, and pTRK68 retarded phage development when the initial levels of phage contamination were below 10² PFU/ml but not when levels were increased to 10³ PFU/ml. Use of a derivative bearing pTR2030 (Hsp⁺ R⁺/M⁺) at the beginning of the rotation prevented phage development, even when the initial levels of phage contamination were high (10⁶ PFU/ml). Alternating the type and specificity of R/M and Abi defenses through the rotation prevented phage proliferation and in some cases eliminated contaminating phages. A model rotation sequence for the phage defense rotation strategy was developed and performed successfully over nine cycles of the Heap-Lawrence starter culture activity test in the presence of high-titer commercial phage composites. This phage defense rotation strategy is designed to protect a highly specialized Lactococcus strain from phage attack during continuous and extended use in the dairy industry.     

AbiQ, an Abortive Infection Mechanism from Lactococcus lactis

Lactococcus lactis W-37 is highly resistant to phage infection. The cryptic plasmids from this strain were coelectroporated, along with the shuttle vector pSA3, into the plasmid-free host L. lactis LM0230. In addition to pSA3, erythromycin- and phage-resistant isolates carried pSRQ900, an 11-kb plasmid from L. lactis W-37. This plasmid made the host bacteria highly resistant (efficiency of plaquing <10⁻⁸) to c2- and 936-like phages. pSRQ900 did not confer any resistance to phages of the P335 species. Adsorption, cell survival, and endonucleolytic activity assays showed that pSRQ900 encodes an abortive infection mechanism. The phage resistance mechanism is limited to a 2.2-kb EcoRV/BclI fragment. Sequence analysis of this fragment revealed a complete open reading frame (abiQ), which encodes a putative protein of 183 amino acids. A frameshift mutation within abiQ completely abolished the resistant phenotype. The predicted peptide has a high content of positively charged residues (pI = 10.5) and is, in all likelihood, a cytosolic protein. AbiQ has no homology to known or deduced proteins in the databases. DNA replication assays showed that phage c21 (c2-like) and phage p2 (936-like) can still replicate in cells harboring AbiQ. However, phage DNA accumulated in its concatenated form in the infected AbiQ⁺ cells, whereas the AbiQ⁻ cells contained processed (mature) phage DNA in addition to the concatenated form. The production of the major capsid protein of phage c21 was not hindered in the cells harboring AbiQ.     

Impact of a Single Phage and a Phage Cocktail Application in Broilers on Reduction of Campylobacter jejuni and Development of Resistance

Campylobacteriosis is currently the most frequent foodborne zoonosis in many countries. One main source is poultry. The aim of this study was to enhance the knowledge about the potential of bacteriophages in reducing colonization of broilers with Campylobacter , as there are only a few in vivo studies published. Commercial broilers were inoculated with 10⁴ CFU/bird of a Campylobacter jejuni field strain. Groups of 88 birds each were subsequently treated with a single phage or a four-phage cocktail (10⁷ PFU/bird in CaCO₃ buffered SM-Buffer). Control birds received the solvent only. Afterwards, subgroups of eleven birds each were examined for their loads with phages and Campylobacter on day 1, 3, 7, 14, 21, 28, 35 and 42 after phage application. The susceptibility of the Campylobacter population to phage infection was determined using ten isolates per bird. In total 4180 re-isolates were examined. The study demonstrated that the deployed phages persisted over the whole investigation period. The Campylobacter load was permanently reduced by the phage-cocktail as well as by the single phage. The reduction was significant between one and four weeks after treatment and reached a maximum of log₁₀ 2.8 CFU/g cecal contents. Phage resistance rates of initially up to 43% in the single phage treated group and 24% in the cocktail treated group later stabilized at low levels. The occurrence of phage resistance influenced but did not override the Campylobacter reducing effect. Regarding the reduction potential, the cocktail treatment had only a small advantage over the singe phage treatment directly after phage administration. However, the cocktail moderated and delayed the emergence of phage resistance.     

Dual Functions of Bacteriophage T4D Gene 28 Product: Structural Component of the Viral Tail Baseplate Central Plug and Cleavage Enzyme for Folyl Polyglutamates II. Folate Metabolism and Polyglutamate Cleavage Activity of Uninfected and Infected Escherichia coli Cells and Bacteriophage Particles

We investigated the role of the T4D bacteriophage gene 28 product in folate metabolism in infected Escherichia coli cells by using antifolate drugs and a newly devised assay for folyl polyglutamate cleavage activity. Preincubation of host E. coli cells with various sulfa drugs inhibited phage production by decreasing the burst size when the phage particles produced an altered gene 28 product (i.e., after infection under permissive conditions with T4D 28^ts or T4D am28). In addition, we found that another folate analog, pyrimethamine, also inhibited T4D 28^ts production and T4D 28am production, but this analog did not inhibit wild-type T4D production. A temperature-resistant revertant of T4D 28^ts was not sensitive to either sulfa drugs or pyrimethamine. We developed an assay to measure the enzymatic cleavage of folyl polyglutamates. The high-molecular-weight folyl polyglutamate substrate was isolated from E. coli B cells infected with T4D am28 in the presence of labeled glutamic acid and was characterized as a folate compound containing 12 to 14 labeled glutamate residues. Extracts of uninfected bacteria liberated glutamate residues from this substrate with a pH optimum of 8.4 to 8.5. Extracts of bacteriophage T4D-infected E. coli B cells exhibited an additional new folyl polyglutamate cleavage activity with a pH optimum of about 6.4 to 6.5, which was clearly distinguished from the preexisting activity in the uninfected host cells. This new activity was induced in E. coli B cells by infection with wild-type T4D and T4D amber mutants 29⁻, 26⁻, 27⁻, 51⁻, and 10⁻, but it was not induced under nonpermissive conditions by T4D am28 or by T4D 28^ts. Mutations in gene 28 affected the properties of the induced cleavage enzyme. Wild-type T4D-induced cleavage activity was not inhibited by pyrimethamine, whereas the T4D 28^ts activity induced at a permissive temperature was inhibited by this folate analog. Folyl polyglutamate cleavage activity characteristic of the activity induced in host cells by wild-type T4D or by T4D gene 28 mutants was also found in highly purified preparations of these phage ghost particles. The T4D-induced cleavage activity could be inhibited by antiserum prepared against highly purified phage baseplates. We concluded that T4D infection induced the formation of a new folyl polyglutamate cleavage enzyme and that this enzyme was coded for by T4D gene 28. Furthermore, since this gene product was a baseplate tail plug component which had both its antigenic sites and its catalytic sites exposed on the phage particle, it was apparent that this enzyme formed part of the distal surface of the phage baseplate central tail plug.     

Deoxyribonucleic Acid Synthesis in Bacteriophage SPO1-Infected Bacillus subtilis I. Bacteriophage Deoxyribonucleic Acid Synthesis and Fate of Host Deoxyribonucleic Acid in Normal and Polymerase-Deficient Strains

The effect of bacteriophage SPO1 infection of Bacillus subtilis and a deoxyribonucleic acid (DNA) polymerase-deficient (pol⁻) mutant of this microorganism on the synthesis of DNA has been examined. Soon after infection, the incorporation of deoxyribonucleoside triphosphates into acid-insoluble material by cell lysates was greatly reduced. This inhibition of host DNA synthesis was not a result of host chromosome degradation nor did it appear to be due to the induction of thymidine triphosphate nucleotidohydrolase. Examination of the host chromosome for genetic linkage throughout the lytic cycle indicated that no extensive degradation occurred. After the inhibition of host DNA synthesis, a new polymerase activity arose which directed the synthesis of phage DNA. This new activity required deoxyribonucleoside triphosphates as substrates, Mg²⁺ ions, and a sulfhydryl reducing agent, and it was stimulated in the presence of adenosine triphosphate. The phage DNA polymerase, like that of its host, was associated with a fast-sedimenting cell membrane complex. The pol⁻ mutation had no effect on the synthesis of phage DNA or production of mature phage particles.