Antigenic and immunogenic activity of flagella and fimbriae preparations from uropathogenic Proteus mirabilis

Immunization of chickens with Salmonella gallinarium ghosts expressing Salmonella Enteritidis NFliC-FimAC and CD40LC fusion antigen enhances cell-mediated immune responses and protects against wild-type challenges with both species

This study describes the construction and immunological characterization of a novel Salmonella gallinarium ghost vaccine to protect against S. gallinarium (SG) and S. Enteritidis (SE) serotypes. The SG ghost was designed to express N-terminus FliC (D0-D1 domain) and FimA retrieved from the SE genome, and the receptor-binding domain (RBD) of CD40L from the chicken as a single fusion construct. The construct was built in pJHL184, a phage lysis gene E-mediated ghost plasmid and the expression was confirmed by western blot resulting in an 85-kDa band. Chicken immunization was conducted by intramuscular route with SG ghost FliC-FimA-CD40L, vector control, or PBS alone in a prime-boost schedule. Antibody responses, cell-mediated immune responses (CMI), and cytokine induction was assessed in chicken demonstrating significantly high levels of IgY, CMI, cytokine responses in ghost immunized group delivering partial protection against SG wild type challenge and near complete protection against SE challenge wild type challenge.

Immunization of chicken with flagellin adjuvanted Salmonella enteritidis bacterial ghosts confers complete protection against chicken salmonellosis

The present study describes the generation of Salmonella enteritidis (SE) ghosts with a surface decorated Salmonella Typhimurium (ST) flagellin (FliC) antigen for immune enhancement and strain-specific protection. The ghosts were generated by biological means using pJHL184::fliC temperature inducible plasmid where the lysis occurs by phage PhiX174 lysis gene E expression. Being an inactivated strain, no environmental contamination was observed by fecal shedding upon inoculation into the chicken. To test the protective immune responses, ghost vaccination was conducted via the intramuscular route using chicken as the model organism. The development of antigen-specific humoral, cell-mediated, and protective immune responses was assessed. Compared to vector alone and phosphate-buffered saline (PBS) control groups, pJHL184::fliC ghost could generate significantly high antigen-specific IgY and cell-mediated immune (CMI) responses measured by a peripheral blood mononuclear cell proliferation, flow cytometer, and cytokine responses elicited by stimulated splenic T-cells (P < 0.05). The adjuvant effect induced by FliC was demonstrated by elicitation of Toll-like receptor 5 (TLR5). To test the protection efficacy, chickens were challenged with both SE and ST wild type (WT) strains, and the protection efficacy was assessed by determining the presence of challenging strains in the spleen and liver, and by assessing the histopathological alterations. Complete clearance of the challenged strain and least inflammatory signs were evident in the SE ghosts vaccinated group compared to the vector and PBS control. The elimination of both SE and ST in chicken organs ensures the intramuscular immunization of the present SE ghost vaccine can reduce SE and ST contamination levels in chicken that can be beneficial to prevent enteric infections in humans.

Parenteral immunization of Salmonella Typhimurium ghosts with surface-displayed Escherichia coli flagellin enhancesTLR-5 mediated activation of immune responses that protect the chicken against Salmonella infection

The present study investigates the enhancement of immunogenicity and protection efficacy of Salmonella Typhimurium ghosts surface-displayed with FliC against chicken salmonellosis. The membrane-anchored FliC is a potential TLR-5 agonist, delivers an essential adjuvant effect for the ghost vaccine candidate. The present ghost plasmid pJHL184 construct carries a convergent dual promoter system that has the temperature-dependent induction of the phage lysis gene E and the target antigen FliC at the same time. Under permissible conditions of temperatures, less than 30 °C at the presence of 20 mM l-arabinose effectively suppresses expression of the lysis gene. Once the temperature is up-lifted to 42 °C without arabinose, cause the generation of ST ghosts expelling the cytoplasmic content. The addition of FliC adjuvant significantly enhanced the IgY response, cell-mediated immune responses, regulatory cytokine induction and subsequently enhanced protection against Salmonella challenge. Further, intramuscular immunization with ST ghosts displaying FliC induced particularly high CD8⁺ response demarcating its proficiency to elicit Type I immune responses. Further, ST ghosts displaying FliC caused an increase in both CD4⁺ and CD8⁺ response compared to the PBS control suggesting its capability to engage both cell-mediated and humoral immune responses essential for the elimination of Salmonella. Upon the virulent challenge, we could observe a significant reduction in challenged bacterial load on spleen, liver and cecum tissues in the ST ghosts surface-displaying FliC adjuvant. Our study suggests the biological incorporation of FliC on ST ghosts enhances vaccine immunogenic potency and acts as a safe and effective prevention strategy against chicken salmonellosis.

Salmonella enterica serovar Enteritidis ghosts displaying a surface FliC adjuvant elicit a robust immune response and effective protection against virulent challenge

Salmonella Enteritidis (SE) is one of the most common culprits of foodborne disease in humans due to its horizontal transmission from infected animals to humans. The development of a safe vaccine against Salmonella would be important for both farm animals and humans concerning disease containment. The SE ghosts carrying FliC were genetically constructed using a special ghost plasmid pJHL184 that co-expressed FliC and the phage lysis gene E. These SE ghosts were characterized by ghost generation efficacy by increasing the culture temperature to "42 °C" in the absence of L-arabinose. This temperature change led to an ghost generation with almost complete lysis of the SE host strain in 48 hs. The expression of FliC was confirmed by Western blot analysis. Also, indirect ELISA was used to prove FliC specific antibody generation in immunized mice. The parenteral adjuvant effect of the FliC antigen was demonstrated by immunizing mice with pJHL184::flC, pJHL184 alone, or PBS alone. The mice were intramuscularly immunized at six weeks of age (n = 8) and boosted after three weeks of primary inoculation. A total of 32 mice were equally divided into four groups. Each group was treated with pJHL-ghosts alone, ghost surface displaying FliC adjuvant, and compared to the PBS and naïve control groups. The immunized mice demonstrated greater IgG and IgA antibody responses than did the PBS control group. Furthermore, the addition of the ghosts to the FliC led to a significant increase in both the humoral and cell-mediated immune responses compared to those in the ghost alone group. Besides, the in vitro antigen uptake and presentation studies revealed efficient antigen presentation on the mouse macrophage cell surfaces. This finding further corroborated the potential efficacy of immune stimulation by SE ghosts. After the virulent challenge, we observed a significant reduction in the bacterial load in the spleen and liver tissues in SE ghosts surface, displaying FliC adjuvant. Our results demonstrate a safe and effective strategy to prevent salmonellosis. They also suggest that the surface expression of flagellin (FliC) significantly enhances antigen-specific humoral and cell-mediated immune responses. This FliC expression can also enhance the protective efficacy of the bacterial ghosts-based vaccine against virulent challenge.

Purification of Native Flagellin

Flagella are effective organelles of locomotion and one of several virulence factors in Proteus mirabilis. To study their properties and role in virulence, we describe a protocol to extract and purify the native flagellin of P. mirabilis. Purified flagellin can be visualized by SDS-PAGE or immunoblot and is suitable for downstream applications such as immunization.

Construction and evaluation of the immune protection of a recombinant divalent protein composed of the MrpA from MR/P fimbriae and flagellin of Proteus mirabilis strain against urinary tract infection

Urinary tract infections (UTI) caused by Proteus mirabilis are prevalent among the catheterized patients. There is no effective vaccine to reduce the frequency of UTIs caused by P. mirabilis. In the present study, the immune responses and effectiveness of different combinations of MrpA and flagellin (FliC) of P. mirabilis were assessed intranasally in the mice model. The addition of FliC as adjuvant to MrpA in fusion form significantly raised the mucosal IgA and cellular (IFN-γ and IL-17) responses and maintained the serum IgG responses for 180 days after the first vaccination. Furthermore, MrpA in fusion form with FliC significantly increased the systemic, mucosal and IFN-γ responses of the FliC alone. In a bladder challenge assay with P. mirabilis, the fusion MrpA.FliC and the mixture of MrpA and FliC significantly decreased the colony count of the bacteria in the bladder and kidneys of mice in comparison to the control mice. It suggests a complex of the systemic, mucosal and cellular responses are needed for protection of the bladder and kidneys against P. mirabilis UTI. In our knowledge, the adjuvant property of the recombinant P. mirabilis flagellin was evaluated for the first time in a vaccine combination administered by an intranasal route. Our results suggest the recombinant flagellin of P. mirabilis could be used as an intranasal adjuvant in combination with other potential antigens against UTIs.

Pseudoalteromonas piratica strain OCN003 is a coral pathogen that causes a switch from chronic to acute Montipora white syndrome in Montipora capitata

Reports of mass coral mortality from disease have increased over the last two decades. Montipora white syndrome (MWS) is a tissue loss disease that has negatively impacted populations of the coral Montipora capitata in Kāne'ohe Bay, Hawai'i. Two types of MWS have been documented; a progressive disease termed chronic MWS (cMWS), that can be caused by Vibrio owensii strain OCN002, and a comparatively faster disease termed acute MWS (aMWS), that can be caused by Vibrio coralliilyticus strain OCN008. M. capitata colonies exhibiting cMWS can spontaneously switch to aMWS in the field. In this study, a novel Pseudoalteromonas species, P. piratica strain OCN003, fulfilled Koch's postulates of disease causation as another etiological agent of aMWS. Additionally, OCN003 induced a switch from cMWS to aMWS on M. capitata in laboratory infection trials. A comparison of OCN003 and Vibrio coralliilyticus strain OCN008, showed that OCN003 was more effective at inducing the cMWS to aMWS switch in M. capitata than OCN008. This study is the first to demonstrate that similar disease signs on one coral species (aMWS on M. capitata) can be caused by multiple pathogens, and describes the first Pseudoalteromonas species that infects coral.

Native flagellin does not protect mice against an experimental Proteus mirabilis ascending urinary tract infection and neutralizes the protective effect of MrpA fimbrial protein

Proteus mirabilis expresses several virulence factors including MR/P fimbriae and flagella. Bacterial flagellin has frequently shown interesting adjuvant and protective properties in vaccine formulations. However, native P. mirabilis flagellin has not been analyzed so far. Native P. mirabilis flagellin was evaluated as a protective antigen and as an adjuvant in co-immunizations with MrpA (structural subunit of MR/P fimbriae) using an ascending UTI model in the mouse. Four groups of mice were intranasally treated with either MrpA, native flagellin, both proteins and PBS. Urine and blood samples were collected before and after immunization for specific antibodies determination. Cytokine production was assessed in immunized mice splenocytes cultures. Mice were challenged with P. mirabilis, and bacteria quantified in kidneys and bladders. MrpA immunization induced serum and urine specific anti-MrpA antibodies while MrpA coadministered with native flagellin did not. None of the animals developed significant anti-flagellin antibodies. Only MrpA-immunized mice showed a significant decrease of P. mirabilis in bladders and kidneys. Instead, infection levels in MrpA-flagellin or flagellin-treated mice showed no significant differences with the control group. IL-10 was significantly induced in splenocytes of mice that received native flagellin or MrpA-flagellin. Native P. mirabilis flagellin did not protect mice against an ascending UTI. Moreover, it showed an immunomodulatory effect, neutralizing the protective role of MrpA. P. mirabilis flagellin exhibits particular immunological properties compared to other bacterial flagellins.

Outer membrane antigens of the uropathogen Proteus mirabilis recognized by the humoral response during experimental murine urinary tract infection

Proteus mirabilis, a gram-negative bacterium, is a frequent cause of complicated urinary tract infections in those with functional or anatomical abnormalities or those subject to long-term catheterization. To systematically identify surface-exposed antigens as potential vaccine candidates, proteins in the outer membrane fraction of bacteria were separated by two-dimensional gel electrophoresis and subjected to Western blotting with sera from mice experimentally infected with P. mirabilis. Protein spots reactive with sera were identified by mass spectrometry, which in conjunction with the newly completed genome sequence of P. mirabilis HI4320, was used to identify surface-exposed antigens. Culture conditions that may mimic in vivo conditions more closely than Luria broth (growth in human urine and under iron limitation and osmotic stress) were also used. Thirty-seven antigens to which a humoral response had been mounted, including 23 outer membrane proteins, were identified. These antigens are presumably expressed during urinary tract infection. Protein targets that are both actively required for virulence and antigenic may serve as protective antigens for vaccination; thus, five representative antigens were selected for use in virulence studies. Strains of P. mirabilis with mutations in three of the corresponding genes (the PMI0047 gene, rafY, and fadL) were not attenuated in the murine model of urinary tract infection. Putative iron acquisition proteins PMI0842 and PMI2596, however, both contribute to fitness in the urinary tract and thus emerge as vaccine candidates.

Development of an intranasal vaccine to prevent urinary tract infection by Proteus mirabilis

Proteus mirabilis commonly infects the complicated urinary tract and is associated with urolithiasis. Stone formation is caused by bacterial urease, which hydrolyzes urea to ammonia, causing local pH to rise, and leads to the subsequent precipitation of magnesium ammonium phosphate (struvite) and calcium phosphate (apatite) crystals. To prevent these infections, we vaccinated CBA mice with formalin-killed bacteria or purified mannose-resistant, Proteus-like (MR/P) fimbriae, a surface antigen expressed by P. mirabilis during experimental urinary tract infection, via four routes of immunization: subcutaneous, intranasal, transurethral, and oral. We assessed the efficacy of vaccination using the CBA mouse model of ascending urinary tract infection. Subcutaneous or intranasal immunization with formalin-killed bacteria and intranasal or transurethral immunization with purified MR/P fimbriae significantly protected CBA mice from ascending urinary tract infection by P. mirabilis (P < 0.05). To investigate the potential of MrpH, the MR/P fimbrial tip adhesin, as a vaccine, the mature MrpH peptide (residues 23 to 275, excluding the signal peptide), and the N-terminal receptor-binding domain of MrpH (residues 23 to 157) were overexpressed as C-terminal fusions to maltose-binding protein (MBP) and purified on amylose resins. Intranasal immunization of CBA mice with MBP-MrpH (residues 23 to 157) conferred effective protection against urinary tract infection by P. mirabilis (P < 0.002).

Proteus mirabilis mannose-resistant, Proteus-like fimbriae: MrpG is located at the fimbrial tip and is required for fimbrial assembly

The mannose-resistant, Proteus-like (MR/P) fimbria, responsible for mannose-resistant hemagglutination, is a virulence factor for uropathogenic Proteus mirabilis. Based on known fimbrial gene organization, we postulated that MrpG, a putative minor subunit of the MR/P fimbria, functions as an adhesin responsible for hemagglutination, while MrpA serves as the major structural subunit for the filamentous structure. To test this hypothesis, an mrpG mutant was constructed by allelic-exchange mutagenesis and verified by PCR and Southern blotting. The mrpG mutant was found to be negative for hemagglutination, while wild-type strain H14320 and the complemented mutant were positive. Western blots with antiserum raised against an overexpressed MrpG'-His6 fusion protein showed that MrpG was present in the fimbrial preparations of both the wild-type strain and the complemented mutant but absent in that of the mrpG mutant. The mrpG mutant was significantly less virulent in a CBA mouse model of ascending urinary tract infection. Western blots with antiserum to whole MR/P fimbriae showed that MrpA protein was also missing from the fimbrial preparation of the mrpG mutant. Using immunogold electron microscopy, we found that the normal MR/P-fimbrial structure was absent in the mrpG mutant, suggesting that MrpG is essential for initiation of normal fimbrial formation. In the wild-type strain, MrpG protein was localized to the tips of the fimbriae or at the surface of the cell when antiserum raised against overexpressed MrpG was used. Given the tip localization, MrpG may be required for initiation of assembly of MR/P fimbriae but does not appear to be the fimbrial adhesin.

Potential virulence factors of Proteus bacilli

The object of this review is the genus Proteus, which contains bacteria considered now to belong to the opportunistic pathogens. Widely distributed in nature (in soil, water, and sewage), Proteus species play a significant ecological role. When present in the niches of higher macroorganisms, these species are able to evoke pathological events in different regions of the human body. The invaders (Proteus mirabilis, P. vulgaris, and P. penneri) have numerous factors including fimbriae, flagella, outer membrane proteins, lipopolysaccharide, capsule antigen, urease, immunoglobulin A proteases, hemolysins, amino acid deaminases, and, finally, the most characteristic attribute of Proteus, swarming growth, enabling them to colonize and survive in higher organisms. All these features and factors are described and commented on in detail. The questions important for future investigation of these facultatively pathogenic microorganisms are also discussed.

Proteus mirabilis ambient-temperature fimbriae: cloning and nucleotide sequence of the aft gene cluster

Uropathogenic Proteus mirabilis produces at least four types of fimbriae. Amino acid sequences from two peptides, derived by tryptic digestion of the structural subunit of one type of these fimbriae, the ambient-temperature fimbriae, were determined: NVVPGQPSSTQ and LIEGENQLNYNA. PCR primers, based on these sequences and that of the N terminus, were used to amplify a 359-bp fragment. A cosmid clone, isolated from a P. mirabilis genomic library by hybridization with the 359-bp PCR product, was used to determine the nucleotide sequence of the atf gene cluster. A 3,903-bp region encodes three polypeptides: AtfA, the structural subunit; AtfB, the chaperone; and AtfC, the outer membrane molecular usher. No fimbria-related genes are evident either 5' or 3' to the three contiguous genes. AtfA demonstrates significant amino acid sequence identity with type 1 major fimbrial subunits of several enteric species. The 359-bp PCR product hybridized strongly with all Proteus isolates (n = 9) and 25% of 355 Escherichia coli isolates but failed to hybridize with any of 26 isolates among nine other uropathogenic species. Ambient-temperature fimbriae of P. mirabilis may represent a novel type of fimbriae of enteric species.

Construction of an MR/P fimbrial mutant of Proteus mirabilis: role in virulence in a mouse model of ascending urinary tract infection

Proteus mirabilis, a cause of acute pyelonephritis, produces at least four types of fimbriae, including MR/P (mannose-resistant/Proteus-like) fimbriae. To investigate the contribution of MR/P fimbriae to colonization of the urinary tract, we constructed an MR/P fimbrial mutant by allelic exchange. A 4.2-kb BamHI fragment carrying the mrpA gene was subcloned into a mobilizable plasmid, pSUP202. A 1.3-kb Kanr cassette was inserted into the mrpA open reading frame, and the construct was transferred to the parent P. mirabilis strain by conjugation. Following passage on nonselective medium, 1 of 500 transconjugants screened was found to have undergone allelic exchange as demonstrated by Southern blot. Colony immunoblot, Western immunoblot, and immunogold labeling with a monoclonal antibody to MR/P fimbriae revealed that MrpA was not expressed. Complementation with cloned mrpA restored MR/P expression as shown by hemagglutination, Western blot, and immunogold electron microscopy. To assess virulence, we challenged 40 CBA mice transurethrally with 10(7) CFU of wild-type or mutant strains. After 1 week, geometric means of log10 CFU per milliliter of urine or per gram of bladder or kidney for the wild-type and mutant strains were as follows: urine, 7.79 (wild type) versus 7.02 (mutant) (P = 0.035); bladder, 6.22 versus 4.78 (P = 0.019); left kidney, 5.02 versus 3.31 (P = 0.009); and right kidney, 5.28 versus 4.46 (P = 0.039). Mice challenged with the wild-type strain showed significantly more severe renal damage than did mice challenged with the MR/P-negative mutant (P = 0.007). We conclude that MR/P fimbriae contribute significantly to colonization of the urinary tract and increase the risk of development of acute pyelonephritis.

Proteus mirabilis MR/P fimbrial operon: genetic organization, nucleotide sequence, and conditions for expression

Proteus mirabilis, an agent of urinary tract infection, expresses at least four fimbrial types. Among these are the MR/P (mannose-resistant/Proteus-like) fimbriae. MrpA, the structural subunit, is optimally expressed at 37 degrees C in Luria broth cultured statically for 48 h by each of seven strains examined. Genes encoding this fimbria were isolated, and the complete nucleotide sequence was determined. The mrp gene cluster encoded by 7,293 bp predicts eight polypeptides: MrpI (22,133 Da), MrpA (17,909 Da), MrpB (19,632 Da), MrpC (96,823 Da), MrpD (27,886 Da), MrpE (19,470 Da), MrpF (17,363 Da), and MrpG (13,169 Da). mrpI is upstream of the gene encoding the major structural subunit gene mrpA and is transcribed in the direction opposite to that of the rest of the operon. All predicted polypeptides share > or = 25% amino acid identity with at least one other enteric fimbrial gene product encoded by the pap, fim, smf, fan, or mrk gene clusters.

Proteus mirabilis MR/P fimbriae: molecular cloning, expression, and nucleotide sequence of the major fimbrial subunit gene

Proteus mirabilis, a cause of serious urinary tract infection and acute pyelonephritis, produces several putative virulence determinants, among them, fimbriae. Principally, two fimbrial types are produced by this species: mannose-resistant/Proteus-like (MR/P) fimbriae and mannose-resistant/Klebsiella-like (MR/K) fimbriae. To isolate MR/P fimbrial gene sequences, a P. mirabilis cosmid library was screened by immunoblotting and by hybridization with an oligonucleotide probe based on the N-terminal amino acid sequence of the isolated fimbrial polypeptide, ADQGHGTVKFVGSIIDAPCS. One clone, pMRP101, reacted strongly with a monoclonal antibody specific for MR/P fimbriae and with the DNA probe. This clone hemagglutinated both tannic acid-treated and untreated chicken erythrocytes with or without 50 mM D-mannose and was shown to be fimbriated by transmission electron microscopy. A 525-bp open reading frame, designated mrpA, predicted a 175-amino-acid polypeptide including a 23-amino-acid hydrophobic leader peptide. The unprocessed and processed polypeptides are predicted to be 17,909 and 15,689 Da, respectively. The N-terminal amino acid sequence of the processed fimbrial subunit exactly matched amino acid residues 24 to 43 predicted by the mrpA nucleotide sequence. The MrpA polypeptide shares 57% amino acid sequence identity with SmfA, the major fimbrial subunit of Serratia marcescens mannose-resistant fimbriae.