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The Jenner Institute is based within the Nuffield Department of Medicine, University of Oxford, and operates out of the Old Road Campus Research Building, in Headington, Oxford.
Early mucosal responses following a randomised controlled human inhaled infection with attenuated Mycobacterium bovis BCG
Abstract The development of an effective vaccine against Mycobacterium tuberculosis is hampered by an incomplete understanding of immunoprotective mechanisms. We utilise an aerosol human challenge model using attenuated Mycobacterium bovis BCG, in BCG-naïve UK adults. The primary endpoint of this study (NCT03912207) was to characterise the early immune responses induced by aerosol BCG infection, the secondary endpoint was to identify immune markers associated with in-vitro protection. Blinded volunteers were randomised to inhale 1 × 107 CFU aerosolised BCG or 0.9% saline (20:6); and sequentially allocated to bronchoscopy at day 2 or 7 post-inhalation (10 BCG, 3 saline each timepoint). In the bronchoalveolar lavage post-aerosol BCG infection, there was an increase in frequency of eosinophils, neutrophils, NK cells and Donor-Unrestricted T cells at day 7, and the frequency of antigen presenting cells decreased at day 7 compared with day 2. The frequency of interferon-gamma+ BCG-specific CD4+ T cells increased in the BAL and peaked in the blood at day 7 post-BCG infection compared to day 2. BAL cells at day 2 and day 7 upregulated gene pathways related to phagocytosis, MHC-II antigen loading, T cell activation and proliferation. BCG’s lack of key virulence factors and its failure to induce granulomas, may mean the observed immune responses do not fully recapitulate Mycobacterium tuberculosis infection. However, human infection models can provide unique insights into early immune mechanisms, informing vaccine design for complex pathogens.
Nipah virus vaccines evaluated in pigs as a 'One Health' approach to protect public health.
Nipah virus (NiV) causes a severe neurological disease in humans. The first NiV outbreak, in Malaysia, involved pig-to-human transmission, that resulted in significant economic losses to the local pig industry. Despite the risk NiV poses to pig-dense regions, no licensed vaccines exist. This study therefore assessed three NiV vaccine candidates in pigs: (1) adjuvanted soluble NiV (s)G protein, (2) adjuvanted pre-fusion stabilised NiV (mcs)F protein, and (3) adenoviral vectored NiV G (ChAdOx1 NiV G). NiV sG induced the strongest neutralising antibody response, NiV mcsF induced antibodies best able to neutralise cell-cell fusion, whereas ChAdOx1 NiV G elicited CD8+ T-cell responses. Despite differences in immunogenicity, prime-boost immunisation with all candidates conferred a high degree of protection against NiV infection. Follow-up studies demonstrated longevity of immune responses and broadly comparable immune responses in Bangladeshi pigs under field conditions. These studies provide a platform for developing a NiV vaccine for pigs.
Repertoire, function, and structure of serological antibodies induced by the R21/Matrix-M malaria vaccine.
The World Health Organization (WHO) recently recommended the programmatic use of the R21/Matrix-M vaccine for Plasmodium falciparum malaria prevention in children living in malaria-endemic areas. To determine its effects on humoral immunity, we conducted a proteomic analysis of polyclonal IgG antibodies directed against the NANP tetrapeptide of the circumsporozoite protein (CSP), which comprises the vaccine's core immunogen. In 10 malaria-naïve adult volunteers, R21/Matrix-M induced polarized IgG anti-NANP repertoires, heavily skewed for IGHV3-30/3-33 genes bearing minimal somatic mutation, which remained static in composition following a controlled human malaria infection challenge. Notably, these vaccine-generated antibodies cross-reacted with another protective CSP epitope, the N-terminal junction region, despite its absence from the R21 construct. NANP-specific IGHV3-30/3-33 mAbs mined from polyclonal IgG repertoires blocked sporozoite invasion in vitro and prevented parasitemia in vivo. Overall, R21/Matrix-M elicits polarized, minimally mutated, polyclonal IgG responses that can target multiple protective CSP epitopes, offering molecular insight into the serological basis for its demonstrated efficacy against P. falciparum malaria.
Salmonella Typhi gut invasion drives hypoxic immune subsets associated with disease outcomes.
Salmonella Typhi (S. Typhi), the causative agent of typhoid disease, remains a major public health concern. Owing to the human-restricted nature of S. Typhi, studies of typhoid pathogenesis in animal models are limited to a murine non-typhoidal pathogen. More recently, human challenge models have been conducted, providing insight into immune correlates of infection outcomes, which are still incompletely understood. Here, we performed an integrated single-cell analysis of immune responses from the human S. Typhi challenge model and mouse model of typhoid disease, to associate biological mechanism with human infection outcome. Most prominent, we revealed immune subsets with a hypoxia-related signature in the blood of individuals who developed disease in the human challenge model. This signature was also evident in the mouse model in activated macrophages infiltrating into the Peyer's patches, but not during infection with a mutant strain impaired for gut invasion. We further identified hypoxia-related signature as a general immune correlate of disease outcome in other infection-and inflammatory-related diseases. Collectively, we identified a hypoxia-associated immune signature that correlates with disease outcomes in humans. Using a mouse model, we demonstrated that this signature is driven by bacterial invasion to the Peyer's patches, implicating a causal role in the pathogenesis of typhoid fever.
Adenoviral vaccines—Infectious disease
Since the early 2000s, adenoviral vectors have been extensively used for the development of infectious disease vaccines. The first clinical vectors were derived from species C human adenovirus type 5 (HAdV-C5) and induced robust T cell and antibody responses against the encoded antigen. However, with widespread prevalence of HAdV-C5 in the human population, pre-existing immunity against the vector often adversely impacts vaccine immunogenicity. To circumvent this, rare human types and nonhuman types have been evaluated as vaccine vectors. Impressively, over 50 adenoviral vectored vaccines have been clinically evaluated against a wide range of pathogens, exploring different dosing regimens and delivery routes. In 2014, the first adenovirus-based vaccine was licensed, utilizing a vector derived from HAdV-D26, a rare human species D adenovirus with low seroprevalence. This adenoviral vector is delivered in a heterologous prime-boost regimen with Modified Vaccinia Ankara vector for prophylaxis against Ebola virus disease. Multiple clinical adenoviral vectored vaccines have since been granted marketing authorization. This success and subsequent widespread administration of adenoviral vectored vaccines is an additional source of antivector immunity, alongside that generated through natural adenovirus infection. This further drives the necessity to understand the mechanisms and impacts of antivector immunity, in addition to developing approaches to negate these. This chapter outlines the breadth of clinical adenoviral vectored vaccines developed against viral, parasitic and bacterial pathogens of humans, defining the clinical needs and associated challenges of such vaccines. The highlights and limitations of these adenoviral vectored vaccines are summarized, alongside vector delivery routes and dosing regimens, populations included during clinical evaluation, vaccine immunogenicity and efficacy outcomes, and the efforts to identify correlates of vaccine-induced protection.
MetE: a promising protective antigen for tuberculosis vaccine development
IntroductionTuberculosis (TB), caused by Mycobacterium tuberculosis (MTB), remains a significant global health concern. The existing vaccine, Bacillus Calmette-Guérin (BCG), provides inconsistent protection, highlighting the pressing need for a more effective vaccine. We aimed to identify novel MTB antigens and assess their protective efficacy as TB vaccine candidates.MethodsUsing immunopeptidomics, we identified 64 and 80 unique mycobacterial antigens derived from BCG and MTB, respectively. We prioritised antigens based on HLA allele coverage through an immunoinformatics approach.ResultsThe candidates, hisD, metE, and mmpL12, delivered as DNA vaccines, were evaluated for efficacy in mice using the ex vivo Mycobacterial Growth Inhibition Assay (MGIA) and metE was identified as a promising candidate. In vivo murine MTB challenge experiments confirmed the protective efficacy conferred by metE when formulated as recombinant protein with AS01™ or AddaS03™ adjuvants, compared to the naïve group. The immunogenic profiles of metE formulated in the two different adjuvants differed, with metE-AS01™ inducing antigen-specific IFN-γ, TNF-α, IL-2, IL-17, IgG1 and IgG2a-c, while metE-AddaS03™ induced TNF-α, IL-2, IL-17, IL-4, IgM, IgG1, IgG2b.ConclusionOur findings highlight metE as a promising protective antigen for future TB vaccine development.
R21/Matrix-M malaria vaccine drives diverse immune responses in pre-exposed adults: insights from a phase IIb controlled human malaria infection trial.
INTRODUCTION: The recently licenced R21/Matrix-M vaccine induces a protective antibody response. In this study, we examined vaccine-induced responses in semi-immune adults in a controlled human malaria infection (CHMI) Phase IIb clinical trial. METHODS: Plasma and peripheral blood mononuclear cells from healthy adult volunteers living in coastal Kenya were analysed following vaccination with R21/Matrix-M (n = 19) and CHMI challenge with Plasmodium falciparum (PfSPZ NF54) sporozoites (n = 17). Humoral immunity was evaluated by quantifying antigen specific antibody subtypes and subclasses via ELISA, alongside functional antibody properties including avidity and complement fixation elicited by vaccination and challenge. Antigen-specific memory B cells were characterised using FluoroSpot assays to detect concurrent secretion of multiple antibody isotypes and the frequency and phenotypes of circulating Tfh (cTfh) cells were assessed using multiparametric flow cytometry. RESULTS: Vaccination increased antibody titres across IgA, IgM, and IgG isotypes and IgG1 and IgG3 subclasses but not IgG2 or IgG4 subclasses, targeting different vaccine antigens (full-length R21, NANP, and C-terminus), indicating a broad and heterogeneous response. The responses were maintained over time and, importantly, they demonstrated complement-fixing capabilities. IgG+ and IgA+ antigen-specific memory B cells were boosted but were short-lived for IgA. We observed an increase in total CXCR5+/PD1+ cTfh cells following vaccination and challenge with the predominant Th2/Th17 population. DISCUSSION: We provide insights into the diverse immune responses induced by R21/Matrix-M vaccination and their potential contribution to protection against malaria. These findings highlight the potential of the R21/Matrix-M vaccination and protection in adults with varying levels of prior malaria exposure.
Vaccine-induced responses to R21/Matrix-M - an analysis of samples from a phase 1b age de-escalation, dose-escalation trial.
IntroductionThe pre-erythrocytic malaria vaccine R21 vaccine adjuvanted with Matrix-M reported good efficacy (75%) in an ongoing phase 3 trial and was recommended World Health Organization for use in children 5-36 months. Vaccine-induced antibodies against NANP are associated with protection, however, various factors such as age, pre-existing immunity, and vaccine dose have been shown to influence vaccine responses.MethodsSamples from adults (n =18), children (n = 17), and infants (n = 51) vaccinated with R21/Matrix-M in a phase I trial were assayed for vaccine-specific antibody responses. We measured antibodies (quantity) by MSD and ELISA; and function (quality) by complement (C1q) fixation assay, inhibition of sporozoite invasion (ISI) assay, and avidity assay. Pre-existing malaria antibody exposure was assessed using an anti-3D7 Plasmodium falciparum crude parasite lysate ELISA.ResultsVaccine-induced CSP antibodies (against full-length R21, NANP, and C terminus), exhibited complement fixation and inhibition of sporozoites. These were significantly lower in adults compared to children and infants. Additionally, children had a higher rate of decay of vaccine-induced antibodies compared to adults 2 years post-vaccination. Furthermore, a higher Matrix-M adjuvant dose resulted in significantly higher C1q fixation, and ISI than the low adjuvant dose in infants. Importantly, functional measures ISI and C1q-fixation were positively associated with the vaccine-induced antibodies overall, but avidity was not. Interestingly, in adults, previous malaria exposure was negatively associated with ISI but positively correlated with avidity and C1q fixation. At baseline, all the study participants were seropositive for anti-HBsAg IgG above the WHO-required protective threshold of 10 mIU/mL, and titers significantly increased post-vaccination.DiscussionR21/Matrix-M was immunogenic across all age groups, with age and vaccine dose significantly affecting antibody magnitude and function. These findings emphasize the importance of evaluating the right adjuvant and vaccine dose for clinical development progression. This could thus inform the development of next-generation malaria vaccines. However, additional crucial factors need further exploration.
Validity of Clinical Severity Scores for Respiratory Syncytial Virus: A Systematic Review.
BackgroundRespiratory syncytial virus (RSV) is a widespread respiratory pathogen, and RSV-related acute lower respiratory tract infections are the most common cause of respiratory hospitalization in children <2 years of age. Over the last 2 decades, a number of severity scores have been proposed to quantify disease severity for RSV in children, yet there remains no overall consensus on the most clinically useful score.MethodsWe conducted a systematic review of English-language publications in peer-reviewed journals published since January 2000 assessing the validity of severity scores for children (≤24 months of age) with RSV and/or bronchiolitis, and identified the most promising scores. For included articles, (1) validity data were extracted, (2) quality of reporting was assessed using the Transparent Reporting of a multivariable prediction model for Individual Prognosis Or Diagnosis checklist (TRIPOD), and (3) quality was assessed using the Prediction Model Risk Of Bias Assessment Tool (PROBAST). To guide the assessment of the validity data, standardized cutoffs were employed, and an explicit definition of what we required to determine a score was sufficiently validated.ResultsOur searches identified 8541 results, of which 1779 were excluded as duplicates. After title and abstract screening, 6670 references were excluded. Following full-text screening and snowballing, 32 articles, including 31 scores, were included. The most frequently assessed scores were the modified Tal score and the Wang Bronchiolitis Severity Score; none of the scores were found to be sufficiently validated according to our definition. The reporting and/or design of all the included studies was poor. The best validated score was the Bronchiolitis Score of Sant Joan de Déu, and a number of other promising scores were identified.ConclusionsNo scores were found to be sufficiently validated. Further work is warranted to validate the existing scores, ideally in much larger datasets.
Underreporting and Misclassification of Respiratory Syncytial Virus-Coded Hospitalization Among Adults in Denmark Between 2015-2016 and 2017-2018.
BackgroundLow awareness and lack of routine testing for respiratory syncytial virus (RSV) infections among adults has led to underreporting in hospital records. This study aimed to assess the underreporting and misclassification of RSV infections among adults hospitalized with an respiratory tract infection (RTI)-coded hospitalization.MethodsThis study is an observational cohort study of RSV-associated hospitalizations among Danish adults (≥18 years old) conducted, between 2015 to 2018. Data were extracted from the Danish National Patient Registry (DNPR) and the Danish Microbiology Database. We identified RSV-positive hospitalizations by linking RTI-coded hospitalizations with a positive RSV test.ResultsUsing hospital admission registries, we identified 440 RSV-coded hospitalizations, of whom 420 (95%) had a positive RSV test registered. By linking patients with RTI-coded hospital admissions to RSV test result, we found 570 additional episodes of RSV-positive hospitalizations without an RSV-coded diagnosis.ConclusionsOur study of national register data showed that RSV is underreported among Danish adults. The study showed that the reliability of hospitalization data to estimate the burden of RSV among adults is questionable and are sensitive to changes in practice over time, even with complete nationwide healthcare data. Healthcare data can be useful to observe seasonality but to estimate the disease burden, prospective surveillance is recommended.
Airway and Blood Monocyte Transcriptomic Profiling Reveals an Antiviral Phenotype in Infants With Severe Respiratory Syncytial Virus Infection.
BackgroundRespiratory syncytial virus (RSV) infection is the primary cause of lower respiratory tract infections in children <5 years of age. Monocytes, especially in the respiratory tract, are suggested to contribute to RSV pathology, but their role is incompletely understood. With transcriptomic profiling of blood and airway monocytes, we describe the role of monocytes in severe RSV infection.MethodsTracheobronchial aspirates and blood samples were collected from control patients (n = 9) and those infected with RSV (n = 14) who were admitted to the pediatric intensive care unit. Monocytes (CD14+) were sorted and analyzed by RNA sequencing for transcriptomic profiling.ResultsPeripheral blood and airway monocytes of patients with RSV demonstrated increased expression of antiviral and interferon-responsive genes as compared with controls. Cytokine signaling showed a shared response between blood and airway monocytes while displaying responses that were more pronounced according to the tissue of origin. Airway monocytes upregulated additional genes related to migration and inflammation.ConclusionsWe found that the RSV-induced interferon response extends from the airways to the peripheral blood. Moreover, RSV induces a migration-promoting transcriptional program in monocytes. Unraveling the monocytic response and its role in the immune response to RSV infection could help the development of therapeutics to prevent severe disease.
Respiratory viral detection in children hospitalized with pneumonia during periods of major population disruptions in Nepal, 2014-2018.
BackgroundRespiratory viruses commonly cause pneumonia in children. We aimed to identify respiratory viral nucleic acids in the nasopharynx of children admitted with pneumonia from 2014 to 2018, a period including a major earthquake (April 2015), PCV10 introduction (August 2015), and a fuel shortage (October 2015 to March 2016).MethodsChildren 2 months to 14 years admitted to Patan Hospital between March 2014 and February 2018 with a clinical diagnosis of pneumonia had nasopharyngeal swabs collected and tested with a multiplex panel for the presence of genetic material from 23 respiratory pathogens.ResultsOf 1343 children with pneumonia, 974 (72.5%) had the nucleic acids of at least one respiratory virus in the nasopharynx. The median age of children with any viral genetic material detected was lower than those without (1.18, IQR: 0.59-2.39 years; versus 2.01 years, IQR: 0.81-4.34 years; p<0.001). Commonly detected viral nucleic acids included those of RSV (21.0%), rhino/enterovirus (30.8%), and parainfluenza (7.4%). The odds of detecting any respiratory viral genetic material in children with pneumonia increased by 1.88 (95% confidence interval: 1.15, 3.06) in the year after the earthquake, when there were several aftershocks and a fuel crisis, relative to other periods and accounting for other potential confounding factors.ConclusionsThese findings highlight the importance of viral diagnostics in pediatric pneumonia and suggest that public health measures addressing environmental conditions during disasters might help reduce respiratory infections.
Age differences in immunity to human seasonal coronaviruses and the immunogenicity of ChAdOx1 nCoV-19 (AZD1222).
BackgroundChAdOx1 nCoV-19 (AZD1222) vaccine was widely deployed to protect against severe COVID-19 in adults, but the relationship between pre-existing immunity to human seasonal coronaviruses (HCoVs) and vaccine-induced SARS-CoV-2 (SCoV2) response across age groups remains unclear.MethodsWe analysed SCoV2 and HCoVs antibody profiles in UK volunteers (aged 6-≥70), assessing antibody levels, avidity, and FcγR binding after receiving one or two doses of ChAdOx1 nCoV-19. Adult cohorts from trials in Brazil and Kenya were also included to evaluate geographical impacts on baseline HCoVs and SCoV2 induced response.FindingsIn the UK cohort, younger individuals had higher SCoV2 IgG, avidity, FcγR binding and cross-reactivity, particularly towards OC43 and HKU1. The greatest differences were seen after the first dose of ChAdOx1 nCoV-19, but these effects diminished after the second dose. Although baseline HCoVs IgG varied geographically, similar trends were observed across adult cohorts with younger adults showing higher SCoV2 IgG compared to older adults (UK and Brazil).InterpretationThese findings contribute to a better understanding of the immunogenicity of ChAdOx1-based vaccines in various age groups. Determining whether this applies across other vaccines using same platform is essential for evaluating the viability of one-dose regimens in outbreak responses.FundingThe clinical trials COV002, COV003, COV004, and COV006 were made possible by funding from Astra Zeneca, the NIHR and the University of Oxford, UK Department of Health and Social Care, through the UK National Institute for Health and Care Research, the Wellcome Trust (220991), and Innovate UK (project 971614).
Diagnosis of Plasmodium falciparum malaria at very low parasitaemias using a commercially available LAMP assay and RDT.
BackgroundMalaria is the most common tropical infection in the UK. Current guidelines suggest that testing on 3 consecutive days is required following an initial negative result. This study aimed to see whether newer diagnostics (loop-mediated amplification assay [LAMP]) had sufficient sensitivity to support a change in diagnostic practice.MethodsBlood samples from 11 participants who had undergone controlled human malaria infection (CHMI) with Plasmodium falciparum malaria were assessed from day 6 (C+6) for malaria positivity using the Carestart Malaria rapid diagnostic test (RDT) and from C+4 using the Alethia Malaria LAMP assay. Quantitative polymerase chain reaction had been performed twice daily during CHMI follow-up. A retrospective analysis of samples submitted to the Sheffield Teaching Hospitals for malaria testing over a 5-y period was conducted, evaluating the combination of the Carestart RDT alongside blood film analysis, as per UK guidelines.ResultsIn CHMI samples, LAMP was positive for all parasitaemias >1000 parasites/ml, whereas RDTs were less reliable (59% positive for parasitaemias >1000 parasites/ml). The combination of RDT and blood films for clinical samples diagnosed most infections, but only a minority of negative samples had subsequent tests.ConclusionsLAMP has higher sensitivity than current UK recommended methods, with a potential to review the requirement for additional days of testing in the majority of patients.