ICAMs Are Not Obligatory for Functional Immune Synapses between Naive CD4 T Cells and Lymph Node DCs

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Assessing the effectiveness of a community intervention for monkeypox prevention in the Congo basin

Background

In areas where health resources are limited, community participation in the recognition and reporting of disease hazards is critical for the identification of outbreaks. This is particularly true for zoonotic diseases such as monkeypox that principally affect people living in remote areas with few health services. Here we report the findings of an evaluation measuring the effectiveness of a film-based community outreach program designed to improve the understanding of monkeypox symptoms, transmission and prevention, by residents of the Republic of the Congo (ROC) who are at risk for disease acquisition.

Methodology/Principal Findings

During 90 days, monkeypox outreach was conducted for ∼23,860 people in northern ROC. Two hundred seventy-one attendees (selected via a structured sample) were interviewed before and after participating in a small-group outreach session. The proportion of interviewees demonstrating monkeypox-specific knowledge before and after was compared. Significant gains were measured in areas of disease recognition, transmission, and mitigation of risk. The ability to recognize at least one disease symptom and a willingness to take a family member with monkeypox to the hospital increased from 49 and 45% to 95 and 87%, respectively (p<0.001, both). Willingness to deter behaviors associated with zoonotic risk, such as eating the carcass of a primate found dead in the forest, remained fundamentally unchanged however, suggesting additional messaging may be needed.

Conclusions/Significance

These results suggest that our current program of film-based educational activities is effective in improving disease-specific knowledge and may encourage individuals to seek out the advice of health workers when monkeypox is suspected.     

Expression Profiling of a Genetic Animal Model of Depression Reveals Novel Molecular Pathways Underlying Depressive-Like Behaviours

Background

The Flinders model is a validated genetic rat model of depression that exhibits a number of behavioural, neurochemical and pharmacological features consistent with those observed in human depression.

Principal Findings

In this study we have used genome-wide microarray expression profiling of the hippocampus and prefrontal/frontal cortex of Flinders Depression Sensitive (FSL) and control Flinders Depression Resistant (FRL) lines to understand molecular basis for the differences between the two lines. We profiled two independent cohorts of Flinders animals derived from the same colony six months apart, each cohort statistically powered to allow independent as well as combined analysis. Using this approach, we were able to validate using real-time-PCR a core set of gene expression differences that showed statistical significance in each of the temporally distinct cohorts, representing consistently maintained features of the model. Small but statistically significant increases were confirmed for cholinergic (chrm2, chrna7) and serotonergic receptors (Htr1a, Htr2a) in FSL rats consistent with known neurochemical changes in the model. Much larger gene changes were validated in a number of novel genes as exemplified by TMEM176A, which showed 35-fold enrichment in the cortex and 30-fold enrichment in hippocampus of FRL animals relative to FSL.

Conclusions

These data provide significant insights into the molecular differences underlying the Flinders model, and have potential relevance to broader depression research.     

The influence of spatial pulsed magnetic field application on neuropathic pain after tibial nerve transection in rat

The purpose of the study was to examine the influence of the spatial variable magnetic field (induction: 150–300?µT, 80–150?µT, 20–80?µT; frequency 40?Hz) on neuropathic pain after tibial nerve transection. The experiments were carried out on 64 male Wistar C rats. The exposure of animals to magnetic field was performed 1?d/20?min., 5?d/week, for 28?d. Behavioural tests assessing the intensity of allodynia and sensitivity to mechanical and thermal stimuli were conducted 1?d prior to surgery and 3, 7, 14, 21 and 28?d after the surgery. The extent of autotomy was examined. Histological and immunohistochemical analysis was performed. The use of extremely low-frequency magnetic fields of minimal induction values (20–80?µT/40?Hz) decreased pain in rats after nerve transection. The nociceptive sensitivity of healthy rats was not changed following the exposition to the spatial magnetic field of the low frequency. The results of histological and immunohistochemical investigations confirm those findings. Our results indicate that extremely low-frequency magnetic field may be useful in the neuropathic pain therapy.     

The devil in the details of life-history evolution: Instability and reversal of genetic correlations during selection on<Emphasis Type="Italic">Drosophila</Emphasis> development

The evolutionary relationships between three major components of Darwinian fitness, development rate, growth rate and preadult survival, were estimated using a comparison of 55 distinct populations ofDrosophila melanogaster variously selected for age-specific fertility, environmental-stress tolerance and accelerated development. Development rate displayed a strong net negative evolutionary correlation with weight at eclosion across all selection treatments, consistent with the existence of a size-versus-time tradeoff between these characters. However, within the data set, the magnitude of the evolutionary correlation depended upon the particular selection treatments contrasted. A previously proposed tradeoff between preadult viability and growth rate was apparent only under weak selection for juvenile fitness components. Direct selection for rapid development led to sharp reductions in both growth rates and viability. These data add to the mounting results from experimental evolution that illustrate the sensitivity of evolutionary correlations to (i) genotype-by-environment (G X E) interaction, (ii) complex functional-trait interactions, and (iii) character definition. Instability, disappearance and reversal of patterns of genetic covariation often occur over short evolutionary time frames and as the direct product of selection, rather than some stochastic process. We suggest that the functional architecture of fitness is a rapidly evolving matrix with reticulate properties, a matrix that we understand only poorly.     

Synthesis of Dideoxymycobactin Antigens Presented by CD1a Reveals T Cell Fine Specificity for Natural Lipopeptide Structures

Mycobacterium tuberculosis survival in cells requires mycobactin siderophores. Recently, the search for lipid antigens presented by the CD1a antigen-presenting protein led to the discovery of a mycobactin-like compound, dideoxymycobactin (DDM). Here we synthesize DDMs using solution phase and solid phase peptide synthesis chemistry. Comparison of synthetic standards to natural mycobacterial mycobactins by nuclear magnetic resonance and mass spectrometry allowed identification of an unexpected α-methyl serine unit in natural DDM. This finding further distinguishes these pre-siderophores as foreign compounds distinct from conventional peptides, and we provide evidence that this chemical variation influences the T cell response. One synthetic DDM recapitulated natural structures and potently stimulated T cells, making it suitable for patient studies of CD1a in infectious disease. DDM analogs differing in the stereochemistry of their butyrate or oxazoline moieties were not recognized by human T cells. Therefore, we conclude that T cells show precise specificity for both arms of the peptide, which are predicted to lie at the CD1a-T cell receptor interface.Pathogens are detected by the host when antigenic molecules directly contact immune receptors during the early stages of infection. The strategy of intracellular infection allows viruses, certain bacteria and protozoa to partially cloak themselves from the immune response by physically encapsulating their antigens within host cells. Intracellular residence also takes advantage of immune tolerance mechanisms that prevent autoimmune destruction of self. T cells play a central role in immunity to intracellular pathogens because they can respond to antigens that are generated inside cells and then transported to the surface of infected cells after binding to antigen-presenting molecules. The antigen-presenting molecules encoded in the major histocompatibility complex are widely known for presenting peptide fragments of proteins (1). More recently, human and mouse members of the CD1 (cluster of differentiation 1) system have been shown to present small amphipathic molecules, including a variety of membrane lipids, glycolipids, and lipopeptides, greatly expanding the molecular structures recognized by the cellular immune system (2, 3).Among human CD1 proteins (CD1a, CD1b, CD1c, CD1d, and CD1e), each CD1 isoform is expressed on a different spectrum of antigen-presenting cells. Human CD1a proteins are distinguished from other CD1 proteins by high expression levels on the surface of intradermal Langerhans cells, which play a role in barrier immune function (4). Human T cell clones have been shown to directly recognize CD1a proteins in the presence of exogenous foreign antigens (5) or in the presence of sulfatide and other self lipids (6, 7), suggesting a role for CD1a in T cell activation. In addition, mycobacteria and other intracellular pathogens have been shown to increase CD1a expression in lesions found in leprosy and tuberculosis patients, implying a possible role for CD1a in the response to infection, especially at mucosal or skin sites (8–10). Analysis of the molecular target recognized by CD1a-restricted T cell clone (CD8-2) allowed the identification of a foreign antigen presented by CD1a as dideoxymycobactin (DDM) (11).²Mycobactin binds iron to promote Mycobacterium tuberculosis survival. DDM was initially isolated (11) from antigenic lipid extracts of M. tuberculosis, a pathogen that kills ∼1.7 million humans annually on a worldwide basis (12). The determination of DDM structure was based on mass spectrometric and NMR studies of limiting amounts of natural material derived from the pathogenic organisms, so that not all elements of its chemical structure could be formally determined. Instead, its assigned structure was facilitated by obvious parallels of dideoxymycobactin with mycobactin, a lipopeptide siderophore (13, 14). Iron is required for reduction-oxidation reactions involving respiration and other basic metabolic pathways in bacterial pathogens (13). Environmental mycobacteria have at least two iron uptake pathways, but mycobactin and the related molecule carboxymycobactin represent the only known dedicated iron uptake pathway for pathogenic species like M. tuberculosis (15, 16). Highlighting the physiological importance of the mycobactin pathway, deletion of mycobactin synthase B limits M. tuberculosis survival in cells (13, 14). Also, mammalian innate immune systems produce siderocalin, a 20-kDa lipocalin that binds both ferric and apo siderophores, preventing their uptake and subsequent iron delivery to microbes (17–20). The small available yields of natural material highlighted the need for a straightforward method to synthesize DDM for studies of its role in mycobacterial iron acquisition and testing T cell responses in human populations, as well as to provide authentic standards to investigate unknown aspects of natural DDM stereochemistry. Here we report two syntheses for production of DDM in solution phase and solid phase. Comparison of synthetic and natural DDMs gives unexpected insight into the stereochemical structures of the methylserine, oxazoline, and butyrate moieties of DDM and provides direct evidence that the T cell response is highly specific for a unique aspect of DDM structure that protrudes from the surface of the CD1a-DDM complexes.     

Toward rational design of bacterial genomes

The advent of genetic engineering-the ability to edit and insert DNA into living organisms-in the latter half of the 20th century created visions of a new era of synthetic biology, where novel biological functions could be designed and implemented for useful purposes. We are witnessing an exciting revolution of scale, wherein technical progresses allow for the manipulation of genetic material at the whole genome level. This will enable the manufacture of increasingly complex genetic designs to solve pressing challenges in health, energy and the environment-if and when such designs can be specified. We argue that the organized development of key common application organisms, engineered for engineerability, and attendant libraries of parts, pathways and standardized manufacturing are necessary for this genome-scale technology to realize its promise.     

Chlamydia pneumoniae infection acts as an endothelial stressor with the potential to initiate the earliest heat shock protein 60-dependent inflammatory stage of atherosclerosis

We identified increased expression and redistribution of the intracellular protein 60-kDa human heat shock protein (hHSP60) (HSPD1) to the cell surface in human endothelial cells subjected to classical atherosclerosis risk factors and subsequent immunologic cross-reactivity against this highly conserved molecule, as key events occurring early in the process of atherosclerosis. The present study aimed at investigating the role of infectious pathogens as stress factors for vascular endothelial cells and, as such, contributors to early atherosclerotic lesion formation. Using primary donor-matched arterial and venous human endothelial cells, we show that infection with Chlamydia pneumoniae leads to marked upregulation and surface expression of hHSP60 and adhesion molecules. Moreover, we provide evidence for an increased susceptibility of arterial endothelial cells for redistribution of hHSP60 to the cellular membrane in response to C. pneumoniae infection as compared to autologous venous endothelial cells. We also show that oxidative stress has a central role to play in endothelial cell activation in response to chlamydial infection. These data provide evidence for a role of C. pneumoniae as a potent primary endothelial stressor for arterial endothelial cells leading to enrichment of hHSP60 on the cellular membrane and, as such, a potential initiator of atherosclerosis.