Coronavirus disease 2019 (COVID-19) in humans is often a clinically mild illness, but some individuals develop severe pneumonia, respiratory failure and death1–4. Studies of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection in hamsters5–7 and nonhuman primates8–10 have generally reported mild clinical disease, and preclinical SARS-CoV-2 vaccine studies have demonstrated reduction of viral replication in the upper and lower respiratory tracts in nonhuman primates11–13. Here we show that high-dose intranasal SARS-CoV-2 infection in hamsters results in severe clinical disease, including high levels of virus replication in tissues, extensive pneumonia, weight loss and mortality in a subset of animals. A single immunization with an adenovirus serotype 26 vector-based vaccine expressing a stabilized SARS-CoV-2 spike protein elicited binding and neutralizing antibody responses and protected against SARS-CoV-2-induced weight loss, pneumonia and mortality. These data demonstrate vaccine protection against SARS-CoV-2 clinical disease. This model should prove useful for preclinical studies of SARS-CoV-2 vaccines, therapeutics and pathogenesis.
BackgroundHIV-1 integration is prone to a high rate of failure, resulting in the accumulation of unintegrated viral genomes (uDNA) in vivo and in vitro. uDNA can be transcriptionally active, and circularized uDNA genomes are biochemically stable in non-proliferating cells. Resting, non-proliferating CD4 T cells are prime targets of HIV-1 infection and latently infected resting CD4 T cells are the major barrier to HIV cure. Our prior studies demonstrated that uDNA generates infectious virions when T cell activation follows rather than precedes infection.ResultsHere, we characterize in primary resting CD4 T cells the dynamics of integrated and unintegrated virus expression, genome persistence and sensitivity to latency reversing agents. Unintegrated HIV-1 was abundant in directly infected resting CD4 T cells. Maximal gene expression from uDNA was delayed compared with integrated HIV-1 and was less toxic, resulting in uDNA enrichment over time relative to integrated proviruses. Inhibiting integration with raltegravir shunted the generation of durable latency from integrated to unintegrated genomes. Latent uDNA was activated to de novo virus production by latency reversing agents that also activated latent integrated proviruses, including PKC activators, histone deacetylase inhibitors and P-TEFb agonists. However, uDNA responses displayed a wider dynamic range, indicating differential regulation of expression relative to integrated proviruses. Similar to what has recently been demonstrated for latent integrated proviruses, one or two applications of latency reversing agents failed to activate all latent unintegrated genomes. Unlike integrated proviruses, uDNA gene expression did not down modulate expression of HLA Class I on resting CD4 T cells. uDNA did, however, efficiently prime infected cells for killing by HIV-1-specific cytotoxic T cells.ConclusionsThese studies demonstrate that contributions by unintegrated genomes to HIV-1 gene expression, virus production, latency and immune responses are inherent properties of the direct infection of resting CD4 T cells. Experimental models of HIV-1 latency employing directly infected resting CD4 T cells should calibrate the contribution of unintegrated HIV-1.Electronic supplementary materialThe online version of this article (doi:10.1186/s12977-015-0234-9) contains supplementary material, which is available to authorized users.
cells. We found that infection of cytokine-treated resting CD4؉ T cells in the presence of raltegravir or with integrase active-site mutant HIV-1 yielded de novo virus production following subsequent T cell activation. Infection with integration-competent HIV-1 naturally generated a population of cells generating virus from unintegrated DNA. Latent infection persisted for several weeks and could be activated to virus production by a combination of a histone deacetylase inhibitor and a protein kinase C activator or by T cell activation. HIV-1 Vpr was essential for unintegrated HIV-1 gene expression and de novo virus production in this system. Bypassing integration by this mechanism may allow the preservation of genetic information that otherwise would be lost.
Innate resistance to retroviral infection and replication is induced by interferons (IFNs). IFN-inducible factors restricting viral replication include the cytidine deaminase APOBEC3G (40, 60) and the E3 ubiquitin ligase TRIM5 (1), both of which target replication primarily during the process of viral entry. A third IFN-inducible activity, tetherin (BST-2/ CD317/HM1.24), acts to restrict viral release (13,35,36,41,62). The importance of these factors in controlling viral replication is underlined by the requirement for lentiviral genomes to encode trans-acting countermeasures; lentiviral Vif proteins (33,54,55) and spumaviral Bet proteins (28, 42, 51) counteract APOBECs whereas HIV-1 Vpu, HIV-2 Nef, and HIV-2 and simian immunodeficiency virus (SIV) Envs may counteract tetherins (15,18,26,35,36,62,65).Tetherin is a type II single-pass transmembrane protein. It is anchored to the cell membrane by both N-terminal transmembrane domain and C-terminal glycophosphatidylinositol (GPI) anchors that are linked by an extracellular coiled-coil domain that promotes dimerization of adjacent tetherin molecules. Accordingly, tetherin in both the cell membrane and the envelope of the budding virus can prevent virion release either by direct cross-linking or by the formation of dimers between adjacent coiled-coil domains (41). The primary role for tetherin remains unclear; however, it is likely that, by trapping enveloped viruses at the cell surface, tetherin prevents the further dissemination of nascent virions. However, given the constitutive high-level expression of tetherin on plasmacytoid dendritic cells (pDC [type I IFN-producing cells]) (5), tetherin may play a more fundamental role in the initiation and perpetuation of a virus-specific immune response (58).The domestic cat lineage has faced multiple invasions by viruses from the family Retroviridae. In addition to an exogenous gammaretrovirus (feline leukemia virus [FeLV]), a lentivirus (feline immunodeficiency virus [FIV]), and a spumavirus (feline foamy virus [FFV]), cats also harbor the endogenous RD114 gamma retrovirus (47, 48) and full-length endogenous FeLVs (50). While lentiviruses have spread throughout the Felidae, from lions in Africa to pumas in North America and Pallas cats in Mongolia (61), the gamma retroviruses are restricted solely to domestic cats (3,4,47,48), although occasional cross-species transmission events have been recorded in Florida panthers (37) and Iberian lynxes (30). The limited distribution of the gamma retroviruses among felids suggests that they entered the domestic cat population after the divergence of the Felis lineage from the other felids circa 6.2 million years ago (19). The presence of three exogenous members and one endogenous member of the Retroviridae in domestic cats offers an intriguing insight into the retrovirus-host interaction. As cats express a truncated TRIM5 lacking a capsid-binding B30.2/SPRY domain (29), their ability to suppress retroviral replication may be impaired. If tetherin is to have a major role in the contro...
The postgenomic era has revolutionized approaches to defining host-pathogen interactions and the investigation of the influence of genetic variation in either protagonist upon infection outcome. We analyzed pathology induced by infection with two genetically distinct Trypanosoma brucei strains and found that pathogenesis is partly strain specific, involving distinct host mechanisms. Infections of BALB/c mice with one strain (927) resulted in more severe anemia and greater erythropoietin production compared to infections with the second strain (247), which, contrastingly, produced greater splenomegaly and reticulocytosis. Plasma interleukin-10 (IL-10) and gamma interferon levels were significantly higher in strain 927-infected mice, whereas IL-12 was higher in strain 247-infected mice. To define mechanisms underlying these differences, expression microarray analysis of host genes in the spleen at day 10 postinfection was undertaken. Rank product analysis (RPA) showed that 40% of the significantly differentially expressed genes were specific to infection with one or the other trypanosome strain. RPA and pathway analysis identified LXR/RXR signaling, IL-10 signaling, and alternative macrophage activation as the most significantly differentially activated host processes. These data suggest that innate immune response modulation is a key determinant in trypanosome infections, the pattern of which can vary, dependent upon the trypanosome strain. This strongly suggests that a parasite genetic component is responsible for causing disease in the host. Our understanding of trypanosome infections is largely based on studies involving single parasite strains, and our results suggest that an integrated host-parasite approach is required for future studies on trypanosome pathogenesis. Furthermore, it is necessary to incorporate parasite variation into both experimental systems and models of pathogenesis.
Multiplex imaging technologies are now routinely capable of measuring more than 40 antibody-labeled parameters in single cells. However, lateral spillage of signals in densely packed tissues presents an obstacle to the assignment of high-dimensional spatial features to individual cells for accurate cell-type annotation. We devised a method to correct for lateral spillage of cell surface markers between adjacent cells termed REinforcement Dynamic Spillover EliminAtion (REDSEA). The use of REDSEA decreased contaminating signals from neighboring cells. It improved the recovery of marker signals across both isotopic (i.e., Multiplexed Ion Beam Imaging) and immunofluorescent (i.e., Cyclic Immunofluorescence) multiplexed images resulting in a marked improvement in cell-type classification.
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