CDC has updated the interim guidance for U.S. health care providers caring for pregnant women with possible Zika virus exposure in response to 1) declining prevalence of Zika virus disease in the World Health Organization's Region of the Americas (Americas) and 2) emerging evidence indicating prolonged detection of Zika virus immunoglobulin M (IgM) antibodies. Zika virus cases were first reported in the Americas during 2015-2016; however, the incidence of Zika virus disease has since declined. As the prevalence of Zika virus disease declines, the likelihood of false-positive test results increases. In addition, emerging epidemiologic and laboratory data indicate that, as is the case with other flaviviruses, Zika virus IgM antibodies can persist beyond 12 weeks after infection. Therefore, IgM test results cannot always reliably distinguish between an infection that occurred during the current pregnancy and one that occurred before the current pregnancy, particularly for women with possible Zika virus exposure before the current pregnancy. These limitations should be considered when counseling pregnant women about the risks and benefits of testing for Zika virus infection during pregnancy. This updated guidance emphasizes a shared decision-making model for testing and screening pregnant women, one in which patients and providers work together to make decisions about testing and care plans based on patient preferences and values, clinical judgment, and a balanced assessment of risks and expected outcomes.

INTRODUCTION: Antimicrobial resistance threatens to undermine treatment for severe infection; new therapeutic strategies are urgently needed. Pre-clinical work shows that augmented passive immunotherapy with P4 peptide increases phagocytic activity and shows promise as a novel therapeutic strategy. Our aim was to determine ex vivo P4 activity in a target population of patients admitted to critical care with severe infection. METHODS: We prospectively recruited UK critical care unit patients with severe sepsis and observed clinical course (≥3 months post discharge). Blood samples were taken in early (≤ 48hrs post-diagnosis, n = 54), latent (seven days post-diagnosis, n = 39) and convalescent (3-6 months post-diagnosis, n = 18) phases of disease. The primary outcome measure was killing of opsonised S.pneumoniae by neutrophils with and without P4 peptide stimulation. We also used a flow cytometric whole blood phagocytosis assay to determine phagocyte association and oxidation of intraphagosomal reporter beads. RESULTS: P4 peptide increased neutrophil killing of opsonised pneumococci by 8.6% (C.I. 6.35 - 10.76, p < 0.001) in all phases of sepsis, independent of infection source and microbiological status. This represented a 54.9% increase in bacterial killing compared to unstimulated neutrophils (15.6%) in early phase samples. Similarly, P4 peptide treatment significantly increased neutrophil and monocyte intraphagosomal reporter bead association and oxidation, independent of infection source. CONCLUSIONS: We have extended pre-clinical work to demonstrate that P4 peptide significantly increases phagocytosis and bacterial killing in samples from a target patient population with severe sepsis. This study supports the rationale for augmented passive immunotherapy as a therapeutic strategy in severe sepsis.

Bordetella pertussis (Bp) is the etiologic agent of pertussis (whooping cough), a highly communicable infection. Although pertussis is vaccine preventable, in recent years there has been increased incidence, despite high vaccine coverage. Possible reasons for the rise in cases include the following: Bp strain adaptation, waning vaccine immunity, increased surveillance, and improved clinical diagnostics. A pertussis outbreak impacted California (USA) in 2010; children and preadolescents were the most affected but the burden of disease fell mainly on infants. To identify protein biomarkers associated with this pertussis outbreak, we report a whole cellular protein characterization of six Bp isolates plus the pertussis acellular vaccine strain Bp Tohama I (T), utilizing gel-free proteomics-based mass spectrometry (MS). MS/MS tryptic peptide detection and protein database searching combined with western blot analysis revealed three Bp isolates in this study had markedly reduced detection of pertactin (Prn), a subunit of pertussis acellular vaccines. Additionally, antibody affinity capture technologies were implemented using anti-Bp T rabbit polyclonal antisera and whole cellular proteins to identify putative immunogens. Proteome profiling could shed light on pathogenesis and potentially lay the foundation for reduced infection transmission strategies and improved clinical diagnostics.

Pneumococcal surface adhesin A (PsaA) is a multifunctional lipoprotein known to bind nasopharyngeal epithelial cells, and is significantly involved in bacterial adherence and virulence. Identification of PsaA peptides that optimally bind human leucocyte antigen (HLA) and elicit a potent immune response would be of great importance to vaccine development. However, this is hindered by the multitude of HLA polymorphisms in humans. To identify the conserved immunodominant epitopes, we used an experimental dataset of 28 PsaA synthetic peptides and in silico methods to predict specific peptide-binding to HLA and murine MHC class II molecules. We also characterized spleen and cervical lymph node (CLN) -derived T helper (Th) lymphocyte cytokine responses to these peptides after Streptococcus pneumoniae strain EF3030 challenge in mice. Individual, yet overlapping, peptides 15 amino acids in length revealed residues of PsaA that consistently caused the highest interferon-gamma, interleukin-2 (IL-2), IL-5 and IL-17 responses and proliferation as well as moderate IL-10 and IL-4 responses by ex vivo re-stimulated splenic and CLN CD4+ T cells isolated from S. pneumoniae strain EF3030-challenged F1 (B6 x BALB/c) mice. In silico analysis revealed that peptides from PsaA may interact with a broad range of HLA-DP, -DQ and -DR alleles, due in part to regions lacking beta-turns and asparagine endopeptidase sites. These data suggest that Th cell peptides (7, 19, 20, 22, 23 and 24) screened for secondary structures and MHC class II peptide-binding affinities can elicit T helper cytokine and proliferative responses to PsaA peptides.

New treatments against severe bacterial infections are needed because the response to antibiotic treatment is slow in acute settings and is becoming less effective owing to the emergence of antibiotic-resistant pathogens. P4-mediated antibody therapy offers a unique treatment strategy that combines exogenous immunoglobulin with the immunoactivating peptide P4. In an acute model of pneumococcal disease, mice were infected with Streptococcus pneumoniae and treated intravenously or intranasally with P4 and intravenous immunoglobulin (IVIG). Survival of P4-IVIG-treated mice increased from 0% to 60% among those that received intravenous treatment and from 0% to 100% among those that received intranasal treatment. Importantly, intranasal administration of P4 at an early stage of infection prevented the onset of bacteremia and sepsis. Increased survival was associated with reduced bacterial burden in affected tissues and with recruitment and activation of professional phagocytes, as manifested by increased expression of Fc-gamma receptors. In vitro studies involving P4-stimulated alveolar, peritoneal, and J774.2 murine macrophages showed an increased ability of these immune cells to phagocytose pneumococci independent of capsule. The use of adjunct antibody therapies to treat infectious diseases shows promise.

During the 2009 influenza pandemic, the Centers for Disease Control and Prevention provided antiviral susceptibility testing for patients infected with suspected drug-resistant viruses. Specimens from 72 patients admitted to an intensive care unit or with a severe immunocompromising condition, who failed to clinically improve after oseltamivir treatment, were accepted for testing. Respiratory specimens were tested for the presence of the oseltamivir resistance-conferring H275Y substitution in the neuraminidase (NA) by pyrosequencing. Virus isolates propagated in MDCK cells were tested in phenotypic NA inhibition (NI) assays using licensed NA inhibitors (NAIs), zanamivir and oseltamivir, and investigational NAIs, peramivir and laninamivir. Conventional sequencing and plaque purification were conducted on a subset of viruses. Pyrosequencing data were obtained for 87 specimens collected from 58 of the 72 (81%) patients. Of all patients, 27 (38%) had at least one specimen in which H275Y was detected. Analysis of sequential samples from nine patients revealed intra-treatment emergence of H275Y variant and a shift from wildtype-to-H275Y in quasispecies during oseltamivir therapy. A shift in the H275Y proportion was observed as a result of virus propagation in MDCK cells. Overall, the NI method was less sensitive than pyrosequencing in detecting the presence of H275Y variants in virus isolates. Using the NI method, isolates containing H275Y variant at 50% exhibited resistance to oseltamivir and peramivir, but retained full susceptibility to zanamivir. H275Y viruses recovered from two patients had an additional substitution I223K or I223R that conferred a 38-52- and 33-97-fold enhancement in oseltamivir- and peramivir-resistance, respectively. These viruses also showed decreased susceptibility to zanamivir and laninamivir. These data suggest that pyrosequencing is a powerful tool for timely detection of NAI resistant viruses and that NI assays are needed for comprehensive testing to detect novel resistance substitutions.

Mass spectrometry (MS) coupled with 1-D and 2-D electrophoresis can be utilized to detect and identify immunogenic proteins, but these methods are laborious and time-consuming. We describe an alternative, simple, rapid gel-free strategy to identify multiple immunogenic proteins from Bordetella pertussis (Bp). It couples immunoprecipitation to nano liquid chromatography- tandem mass spectrometry (IP-nLC-MS/MS) and is significantly both time- and labor-saving. We developed a gel-free magnetic bead-based immunoprecipitation (IP) method using different NP-40/PBS concentrations in which solubilized proteins of Bp Tohama I membrane fractions were precipitated with polyclonal rabbit anti-Bp whole cell immune sera. Immune complexes were analyzed by MS and Scaffold analysis (>95% protein identification probability). Total immunoproteins identified were 50, 63 and 49 for 0.90%, 0.45% and 0.22% NP-40/PBS buffer concentrations respectively. Known Bp proteins identified included pertactin, serotype 2 fimbrial subunit and filamentous hemagglutinin. As proof of concept that this gel-free protein immunoprecipitation method enabled the capture of multiple immunogenic proteins, IP samples were also analyzed by SDS-PAGE and immunoblotting. Bypassing gels and subjecting immunoprecipitated proteins directly to MS is a simple and rapid antigen identification method with relatively high throughput. IP-nLC-MS/MS provides a novel alternative approach for current methods used for the identification of immunogenic proteins.

Alternate therapies are needed for treatment of secondary bacterial pneumonia following influenza. The immunomodulatory peptide P4 has shown promise in mouse models of primary pneumococcal infection. Mice infected with influenza virus then challenged with Streptococcus pneumoniae were treated with a combination of P4 peptide and intravenous immune globulin. Survival was improved from 20% to 80% in treated mice relative to controls. Clinical cure correlated with increased clearance of bacteria and decreased lung consolidation. Greater trafficking of professional phagocytic cells to the site of pneumococcal infection coupled with enhanced opsonophagocytosis as manifest by decreased surface display of Fcgamma receptors on neutrophils and macrophages were associated with P4 peptide treatment. This suggests that the mechanism of action for improved clearance of bacteria engendered by P4 is through improved uptake by phagocytes mediated by IgG Fc - Fcgamma receptor interactions following antibody mediated opsonophagocytosis of bacteria. Antibody-based therapies, when coupled with immune modulators such as P4 peptide, may be an effective tool together with antibiotics in our armamentarium against severe pneumonia.

Many studies suggest that with aging, immune capabilities gradually diminish, leading to a decrease in antibody production, cytokines, and various effector cells (1-4). In this study, we examined the effects of an immune-enhancing peptide on aged mice. P4, a 28-amino-acid cationic peptide derived from pneumococcal surface adhesin A (PsaA), is a eukaryotic cellular activator (10). Previously, we demonstrated that the cellular activation properties of P4 can be utilized to rescue severely ill young mice from fatal pneumococcal infection in the presence of pathogen-specific antibodies and active complement (8, 12). While P4 therapy was used to rescue young Swiss Webster mice (6 to 10 weeks old), we questioned its effectiveness in aged mice (11 and 15 months old). | Intranasal inoculation of mice with Streptococcus pneumoniae WU2 (serotype 3) and P4 therapy were done using protocols previously described, with minor modifications (12). Eleven-month-old BALB/c (n = 20) and 15-month-old Swiss Webster mice (n = 20) were infected intranasally with S. pneumoniae WU2 (∼2.1 × 107 cells/mouse). Mice were monitored and visually scored twice daily for moribund characteristics as previously described (12). At 48 h postchallenge, 80% (16/20) were moribund. Moribund mice were divided into a control (n = 8) and a treatment group (n = 8). Two doses of P4 therapy with pathogen-specific antibody (intravenous immunoglobulin [IVIG]; Gamunex, Telecris, NC) and P4 were administered intravenously (postinfection) in the treatment group. Treated and untreated animals were monitored for 166 h, and the data computed for significant differences among various groups using a t test for paired samples for the means (MS Excel 2007).

In the early 1900s, passive immunization/antibody therapy was used to treat a variety of human ailments such as hypoimmunoglobulinemia, cancer and infectious disease. The advent of antibiotic therapy had relegated this type of therapy obsolete for treatment of infectious diseases. Emergence of multi-drug resistant pathogens along with novel monoclonal antibody production techniques has rekindled the interest in passive immunization (PI). An increase in the number of monoclonal antibody patent applications in the recent past suggests a renewed commercial interest in PI. Despite these developments, antibody therapy for infectious diseases has limitations including the need for large or frequent dosages. P4, a 28-amino acid peptide is a multi-lineage cellular activator. P4, along with infectious disease (i.e. Pathogen) specific immunoglobulin, has been shown in vitro and in vivo in mice to potentiate innate immunity. This review will discuss the progress made in passive antibody therapy, the challenges still to be surmounted, and the potential expanded role of an immune-potentiating peptide (bio-molecule) in the quest to utilize and revitalize passive immunization.

A murine colonization model was used to determine the effect of co-administering 7-valent polysaccharide-protein conjugate vaccine and pneumococcal surface adhesin A. Mice were challenged intranasally with either PCV7 serotypes, 4 or 14, or a non-PCV7 serotype, 19A. Post-challenge samples were evaluated for IgG antibody levels, opsonophagocytic activity, and nasopharyngeal colonization. No interference was observed between immune responses from the concomitant and individual immunizations. Concomitant immunizations reduced carriage for tested serotypes; largest reduction was observed for 19A. From these mouse studies, co-administering pneumococcal antigens appear to expand coverage and reduce colonization against a non-PCV7 serotype without inhibiting immunogenicity to other serotypes.