Inactivated influenza vaccine adjuvanted with bacterium-like particles induce systemic and mucosal influenza A virus specific T-cell and B-cell responses after nasal administration in a TLR2 dependent fashion.

BACKGROUND: Nasal vaccination is considered to be a promising alternative for parenteral vaccination against influenza virus as it is non-invasive and offers the opportunity to elicit strong antigen-specific responses both systemic and locally at the port of entry of the pathogen. Previous studies showed that non-living bacterium-like particles (BLPs) from the food-grade bacterium Lactococcus lactis are effective stimulators of local and systemic immune responses when administered intranasally. Moreover, in vitro, BLPs specifically interact with human Toll-like receptor 2 (TLR2), suggestive of a role for TLR2 dependent immune activation by BLPs. METHODS: In the present study, we examined the role of TLR2 in vivo in immune activation after nasal administration of BLP mixed with split influenza vaccine (BLP-SV) of influenza A virus (IAV) using TLR2 knockout mice. RESULTS: The systemic Th1 cell and subsequent B-cell responses induced after intranasal BLP-SV vaccination depended on the interaction of BLPs with TLR2. Notably, the BLP-SV-induced class switch to IgG2c depended on the interaction of BLP with TLR2. Local induced IAV-specific Th1 cell responses and the mucosal B-cell responses also depended on interaction of BLP with TLR2. Strongly reduced SIgA levels were observed in TLR2 knockout mice both in the nasal and vaginal lavages. In addition, detailed analysis of the T-cell response revealed that nasal BLP-SV vaccination promoted Th1/Th17 immune responses that coincided with increased IAV-specific IgG2c antibody production. DISCUSSION: Altogether these results indicate that nasal BLP-SV vaccination induces IAV-specific T-cell and B-cell responses, both systemically and at the site of virus entry in a TLR2-dependent manner.

Cleavage of group 1 coronavirus spike proteins: how furin cleavage is traded off against heparan sulfate binding upon cell culture adaptation.

A longstanding enigmatic feature of the group 1 coronaviruses is the uncleaved phenotype of their spike protein, an exceptional property among class I fusion proteins. Here, however, we show that some group 1 coronavirus spike proteins carry a furin enzyme recognition motif and can actually be cleaved, as demonstrated for a feline coronavirus. Interestingly, this feature can be lost during cell culture adaptation by a single mutation in the cleavage motif; this, however, preserves a heparan sulfate binding motif and renders infection by the virus heparan sulfate dependent. We identified a similar cell culture adaptation for the human coronavirus OC43.

The carbohydrate-binding plant lectins and the non-peptidic antibiotic pradimicin A target the glycans of the coronavirus envelope glycoproteins.

OBJECTIVES: Many enveloped viruses carry carbohydrate-containing proteins on their surface. These glycoproteins are key to the infection process as they are mediators of the receptor binding and membrane fusion of the virion with the host cell. Therefore, they are attractive therapeutic targets for the development of novel antiviral therapies. Recently, carbohydrate-binding agents (CBA) were shown to possess antiviral activity towards coronaviruses. The current study further elucidates the inhibitory mode of action of CBA. METHODS: Different strains of two coronaviruses, mouse hepatitis virus and feline infectious peritonitis virus, were exposed to CBA: the plant lectins Galanthus nivalis agglutinin, Hippeastrum hybrid agglutinin and Urtica dioica agglutinin (UDA) and the non-peptidic mannose-binding antibiotic pradimicin A. RESULTS AND CONCLUSIONS: Our results indicate that CBA target the two glycosylated envelope glycoproteins, the spike (S) and membrane (M) protein, of mouse hepatitis virus and feline infectious peritonitis virus. Furthermore, CBA did not inhibit virus-cell attachment, but rather affected virus entry at a post-binding stage. The sensitivity of coronaviruses towards CBA was shown to be dependent on the processing of the N-linked carbohydrates. Inhibition of mannosidases in host cells rendered the progeny viruses more sensitive to the mannose-binding agents and even to the N-acetylglucosamine-binding UDA. In addition, inhibition of coronaviruses was shown to be dependent on the cell-type used to grow the virus stocks. All together, these results show that CBA exhibit promising capabilities to inhibit coronavirus infections.

Antiviral activity of carbohydrate-binding agents against Nidovirales in cell culture.

Coronaviruses are important human and animal pathogens, the relevance of which increased due to the emergence of new human coronaviruses like SARS-CoV, HKU1 and NL63. Together with toroviruses, arteriviruses, and roniviruses the coronaviruses belong to the order Nidovirales. So far antivirals are hardly available to combat infections with viruses of this order. Therefore, various antiviral strategies to counter nidoviral infections are under evaluation. Lectins, which bind to N-linked oligosaccharide elements of enveloped viruses, can be considered as a conceptionally new class of virus inhibitors. These agents were recently evaluated for their antiviral activity towards a variety of enveloped viruses and were shown in most cases to inhibit virus infection at low concentrations. However, limited knowledge is available for their efficacy towards nidoviruses. In this article the application of the plant lectins Hippeastrum hybrid agglutinin (HHA), Galanthus nivalis agglutinin (GNA), Cymbidium sp. agglutinin (CA) and Urtica dioica agglutinin (UDA) as well as non-plant derived pradimicin-A (PRM-A) and cyanovirin-N (CV-N) as potential antiviral agents was evaluated. Three antiviral tests were compared based on different evaluation principles: cell viability (MTT-based colorimetric assay), number of infected cells (immunoperoxidase assay) and amount of viral protein expression (luciferase-based assay). The presence of carbohydrate-binding agents strongly inhibited coronaviruses (transmissible gastroenteritis virus, infectious bronchitis virus, feline coronaviruses serotypes I and II, mouse hepatitis virus), arteriviruses (equine arteritis virus and porcine respiratory and reproductive syndrome virus) and torovirus (equine Berne virus). Remarkably, serotype II feline coronaviruses and arteriviruses were not inhibited by PRM-A, in contrast to the other viruses tested.

Soluble receptor-mediated targeting of mouse hepatitis coronavirus to the human epidermal growth factor receptor.

The mouse hepatitis coronavirus (MHV) infects murine cells by binding of its spike (S) protein to murine CEACAM1a. The N-terminal part of this cellular receptor (soR) is sufficient for S binding and for subsequent induction of the conformational changes required for virus-cell membrane fusion. Here we analyzed whether these characteristics can be used to redirect MHV to human cancer cells. To this end, the soR domain was coupled to single-chain monoclonal antibody 425, which is directed against the human epidermal growth factor receptor (EGFR), resulting in a bispecific adapter protein (soR-425). The soR and soR-425 proteins, both produced with the vaccinia virus system, were able to neutralize MHV infection of murine LR7 cells. However, only soR-425 was able to target MHV to human EGFR-expressing cancer cells. Interestingly, the targeted infections induced syncytium formation. Furthermore, the soR-425-mediated infections were blocked by heptad repeat-mimicking peptides, indicating that virus entry requires the regular S protein fusion process. We conclude that the specific spike-binding property of the CEACAM1a N-terminal fragment can be exploited to direct the virus to selected cells by linking it to a moiety able to bind a receptor on those cells. This approach might be useful in the development of tumor-targeted coronaviruses.

The Bacillus subtilis competence transcription factor, ComK, overrides LexA-imposed transcriptional inhibition without physically displacing LexA.

During the development of competence in Bacillus subtilis the recA gene is activated by the competence transcription factor, ComK, which is presumably required to alleviate the transcriptional repression of recA by LexA. To investigate the mechanism by which ComK activates recA transcription we examined the binding of ComK and LexA to the recA promoter in vitro. Using hydroxyl radical protection analyses to establish the location of ComK dimer-binding sites within the recA promoter, we identified four AT-boxes in a configuration unique for ComK-regulated promoters. Gel mobility shift experiments showed that all four ComK dimer-binding sites were occupied at ComK concentrations in the physiological range. In addition, occupation of all ComK-binding sites did not prevent LexA from binding to the recA promoter, despite the fact that the ComK and LexA recognition motifs partially overlap. Although ComK did not replace LexA from the recA promoter, in vitro transcription analyses indicated that the presence of ComK is sufficient to alleviate LexA repression of recA.

A ComGA-dependent checkpoint limits growth during the escape from competence.

In Bacillus subtilis, competence for transformation develops in 5-10% of the cells in a stationary phase culture. These cells exhibit a prolonged lag in the resumption of growth and cell division during the escape from competence. To better understand the basis of this lag, we have characterized competent cultures microscopically. To distinguish the minority of competent cells, a translational fusion between ComK, the competence transcription factor, and the green fluorescent protein (GFP) was used as a marker. Only 5-10% of the cells in a competent culture were fluorescent, indicating that ComK synthesis is an all or nothing event. To validate the identification of competent cells, we demonstrated the coincident expression of comEA, a late competence gene, and comK-gfp. Competent cells resemble stationary phase cells; the majority are single (not in chains), contain single nucleoids, and rarely contain FtsZ rings. Upon dilution into fresh medium, competent cells maintain this appearance for about 2 h. In contrast, the majority of non-competent cells rapidly resume growth, exhibiting chaining, nuclear division and FtsZ-ring formation. The late competence protein ComGA is required for the competence-related block in chromosome replication and cell division. In the competent cells of a comGA mutant culture, chromosomal replication and FtsZ-ring formation were no longer blocked, although competent comGA mutant cells were abnormal in appearance. It is likely that one role for ComGA is to prevent growth, chromosome replication and cell division until ComK can be eliminated by degradation. A mutation in the ATP-binding site of comGA inactivated the protein for transformation but did not prevent it from inhibiting DNA replication and cell division. The buoyant density difference between competent and non-competent cells depends on the competence-specific growth arrest.

Role of enzymes of homologous recombination in illegitimate plasmid recombination in Bacillus subtilis.

The structural stability of plasmid pGP1, which encodes a fusion between the penicillinase gene (penP) of Bacillus licheniformis and the Escherichia coli lacZ gene, was investigated in Bacillus subtilis strains expressing mutated subunits of the ATP-dependent nuclease, AddAB, and strains lacking the major recombination enzyme, RecA. Strains carrying a mutation in the ATP-binding site of the AddB subunit exhibited high levels of plasmid instability, whereas a comparable mutation in the A subunit did not affect plasmid stability. Using an alternative plasmid system, pGP100, we were able to demonstrate that the differences in stability reflected differences in initial recombination frequencies. Based on a comparison of endpoint sequences observed in the various hosts, we speculate that at least two different mechanisms underlie the deletion events involved, the first (type I) occurring between nonrepeated sequences, and the second (type II) occurring between short direct repeats (DRs). The latter event was independent of single-strand replication intermediates and the mode of replication and possibly requires the introduction of double-strand breaks (DSBs) between the repeats. In the absence of functional AddAB complex, or the AddB subunit, DSBs are likely to be processed via a recA-independent mechanism, resulting in intramolecular recombination between the DRs. In wild-type cells, such DSBs are supposed to be either repaired by a mechanism involving AddAB-dependent recombination or degraded by the AddAB-associated exonuclease activity. Plasmid stability assays in a recA mutant showed that (i) the level of deletion formation was considerably higher in this host and (ii) that deletions between short DRs occurred at higher frequencies than those described previously for the parental strain. We propose that in wild-type cells, the recA gene product is involved in recombinational repair of DSBs.

A conserved helicase motif of the AddA subunit of the Bacillus subtilis ATP-dependent nuclease (AddAB) is essential for DNA repair and recombination.

Various mutations were introduced in a conserved helicase domain (motif VI) of the AddA subunit of the Bacillus subtilis ATP-dependent nuclease (AddAB) by site-directed mutagenesis. These mutations affected the helicase activity and the ATP-dependent exonuclease activity on double-stranded DNA (dsDNA) as the substrate to various degrees, but had hardly any effect on the exonuclease activity on single-stranded DNA (ssDNA), suggesting that exonuclease activity on dsDNA of the enzyme requires unwinding of the DNA. This idea was supported by the finding that, initially, the rate and extent of unwinding of the DNA were higher than those of its degradation to acid-soluble products by the exonucleolytic activity. The effects of the mutations on DNA repair and recombination correlated strongly with their effects on helicase activity. Taken together, these results suggest that motif VI is essential for the helicase activity, and that this activity is required for DNA repair and recombination.

Regulated expression of the dinR and recA genes during competence development and SOS induction in Bacillus subtilis.

It has been hypothesized that the dinR gene product of Bacillus subtilis acts as a repressor of the SOS regulon by binding to DNA sequences located upstream of SOS genes, including dinR and recA. Following activation as a result of DNA damage, RecA is believed to catalyse DinR-autocleavage, thus derepressing the SOS regulon. The present results support this hypothesis: a dinR insertion mutation caused a high, constitutive expression of both dinR and recA, which could not be further elevated by SOS-induction. In addition, gel-retardation assays demonstrated a direct interaction between the dinR gene product and the recA and dinR promoter regions. Epistatic interactions and gel-retardation assays demonstrated that the previously reported competence-specific expression of recA directly depended upon the gene product of comK, the competence transcription factor. These data demonstrate the existence of a direct regulatory link between the competence signal-transduction pathway and the SOS reguion.

Replacement of the lysine residue in the consensus ATP-binding sequence of the AddA subunit of AddAB drastically affects chromosomal recombination in transformation and transduction of Bacillus subtilis.

The ATP-dependent deoxyribonuclease enzyme complex (AddAB) of Bacillus subtilis possesses two consensus ATP-binding sequences, located in the N-terminal region of both subunits. The highly conserved lysine residues in both consensus ATP-binding sequences were replaced by glycine, resulting in the mutant enzyme complexes AddAB-A-K36G (AddA*B) and AddAB-B-K14G (AddAB*). The mutation in subunit AddA reduced DNA repair and chromosomal transformation, and abolished bacteriophage PBS1-mediated transduction. This mutation also resulted in a complete loss of the ATP-dependent exonuclease and helicase activity. In contrast, the mutation in subunit AddB had only marginal effects. The recF and addAB genes are not required for transformation with plasmid DNA, but have overlapping activities in transformation with chromosomal DNA. By contrast to RecF, the AddAB enzyme is essential for PBS1-mediated transduction. However, recF has a more important function with respect to DNA repair than addAB.

The C terminus of the AddA subunit of the Bacillus subtilis ATP-dependent DNase is required for the ATP-dependent exonuclease activity but not for the helicase activity.

Comparison of subunit AddA of the Bacillus subtilis AddAB enzyme, subunit RecB of the Escherichia coli RecBCD enzyme, and subunit RecB of the Haemophilus influenzae RecBCD enzyme revealed several regions of homology. Whereas the first seven regions are common among helicases, the two C-terminally located regions are unique for RecB of E. coli and H. influenzae and AddA. Deletion of the C-terminal region resulted in the production of an enzyme which showed moderately impaired levels of ATP-dependent helicase activity, whereas the ATP-dependent exonuclease activity was completely destroyed. The mutant enzyme was almost completely capable of complementing E. coli recBCD and B. subtilis addAB strains with respect to DNA repair and homologous recombination. These results strongly suggest that at least part of the C-terminal region of the AddA protein is indispensable for exonuclease activity and that, in contrast to the exonuclease activity, the helicase activity of the addAB gene product is important for DNA repair and homologous recombination.

Effects of lysine-to-glycine mutations in the ATP-binding consensus sequences in the AddA and AddB subunits on the Bacillus subtilis AddAB enzyme activities.

The N-terminal regions of both subunits AddA and AddB of the Bacillus subtilis AddAB enzyme contain amino acid sequences, designated motif I, which are commonly found in ATP-binding enzymes. The functional significance of the motif I regions was studied by replacing the highly conserved lysine residues of the regions in both subunits by glycines and by examination of the resulting mutant enzymes with respect to their enzymatic properties. This study shows that the mutation in subunit AddB hardly affected the ATPase, helicase, and exonuclease activities of the AddAB enzyme. However, the mutation in subunit AddA drastically reduced these activities, as well as the kcat for ATP hydrolysis. The apparent Km for ATP in ATP hydrolysis did not significantly deviate from that of the wild-type enzyme. These results suggest that the lysine residue in motif I of subunit AddA of the AddAB enzyme is not essential for the binding of the nucleotide but has a role in ATP hydrolysis, which is required for the exonuclease and helicase activities of the enzyme.

Overproduction of the ATP-dependent nuclease AddAB improves the structural stability of a model plasmid system in Bacillus subtilis.

The effect of the ATP-dependent exonuclease AddAB complex on the structural stability of plasmid pGP1 in Bacillus subtilis was studied. Using deletion mutagenesis and gene amplification techniques, B. subtilis strains were constructed either lacking or overproducing the AddAB complex, a key enzyme in homologous recombination. The deletion mutant possessed no residual ATP-dependent nuclease activity; in contrast, the nuclease activity was up to 30 times higher in lysates of strains carrying multiple copies of the addAB genes in the chromosome. Southern blot analyses of these strains indicated that a linear relationship exists between the number of chromosomal gene copies and the level of AddAB activity. The structural stability of pGP1 was analyzed in the AddAB-deficient and over-producing backgrounds. Frequencies of deletion formation in the plasmid, as monitored by the expression of the pGP1-encoded penP-lacZ fusion on media containing X-gal, were shown to be increased at least 25-fold in the addAB knock-out mutant, whereas the stability of pGP1 was improved up to 15-fold in strains overproducing the AddAB enzyme. A possible explanation for these findings is that interactions between AddAB and plasmid molecules prevent the formation of secondary structures that constitute potential deletion target sites, and thereby enhance the structural stability of plasmids.

Expression of the ATP-dependent deoxyribonuclease of Bacillus subtilis is under competence-mediated control.

Transcription of the ATP-dependent deoxynuclease operon (addAB), as monitored by means of an addAB-lacZ transcriptional fusion, has a low, constitutive level and is initiated from a sigma A type promoter. Transcription of addAB is independent of DNA-damaging agents known to induce the SOS response in Bacillus subtilis. However, addAB transcription increased significantly during competence development. This competence-specific induction was dependent on the gene products of srfA, degU and comK, but not on that of recA. Deletion analysis of the addAB promoter region demonstrated that the competence-specific transcription induction requires DNA sequences located upstream of the addAB promoter that associated with ComK, the competence transcription factor. The latter finding indicates that a direct regulatory link exists between the establishment of the competent state and the synthesis of AddAB, required for recombination of internalized donor DNA.

The Bacillus subtilis addAB genes are fully functional in Escherichia coli.

An Escherichia coli recBCD deletion mutant was transformed with plasmids containing the Bacillus subtilis add genes. The transformants had relatively high ATP-dependent exonuclease- and ATP-dependent helicase activities, and their viability, the ability to repair u.v.-damaged DNA and the recombination in conjugation were nearly completely restored. The B. subtilis Add enzyme did not show Chi-activity in phage lambda recombination. The individual B. subtilis Add proteins were not able to form an enzymatically active complex with the E. coli RecB,C,D proteins, and they could not complement the recB,C,D deficiency. Evidence is presented that only two subunits are involved in the B. subtilis ATP-dependent exonuclease. This is in contrast to E. coli in which the RecBCD enzyme consists of three subunits.