Annual seasonal influenza epidemics of variable severity result in significant morbidity and mortality in the United States (U.S.) and worldwide. In temperate climate countries, including the U.S., influenza activity peaks during the winter months. Annual influenza vaccination is recommended for all persons in the U.S. aged 6 months and older, and among those at increased risk for influenza-related complications in other parts of the world (e.g. young children, elderly). Observational studies have reported effectiveness of influenza vaccination to reduce the risks of severe disease requiring hospitalization, intensive care unit admission, and death. A diagnosis of influenza should be considered in critically ill patients admitted with complications such as exacerbation of underlying chronic comorbidities, community-acquired pneumonia, and respiratory failure during influenza season. Molecular tests are recommended for influenza testing of respiratory specimens in hospitalized patients. Antigen detection assays are not recommended in critically ill patients because of lower sensitivity; negative results of these tests should not be used to make clinical decisions, and respiratory specimens should be tested for influenza by molecular assays. Because critically ill patients with lower respiratory tract disease may have cleared influenza virus in the upper respiratory tract, but have prolonged influenza viral replication in the lower respiratory tract, an endotracheal aspirate (preferentially) or bronchoalveolar lavage fluid specimen (if collected for other diagnostic purposes) should be tested by molecular assay for detection of influenza viruses. Observational studies have reported that antiviral treatment of critically ill adult influenza patients with a neuraminidase inhibitor is associated with survival benefit. Since earlier initiation of antiviral treatment is associated with the greatest clinical benefit, standard-dose oseltamivir (75 mg twice daily in adults) for enteric administration is recommended as soon as possible as it is well absorbed in critically ill patients. Based upon observational data that suggest harms, adjunctive corticosteroid treatment is currently not recommended for children or adults hospitalized with influenza, including critically ill patients, unless clinically indicated for another reason, such as treatment of asthma or COPD exacerbation, or septic shock. A number of pharmaceutical agents are in development for treatment of severe influenza.
Positive-strand RNA viruses induce modifications of cytoplasmic membranes to form replication complexes. For coronaviruses, replicase nonstructural protein 4 (nsp4) has been proposed to function in the formation and organization of replication complexes. Murine hepatitis virus (MHV) nsp4 is glycosylated at residues Asn176 (N176) and N237 during plasmid expression of nsp4 in cells. To test if MHV nsp4 residues N176 and N237 are glycosylated during virus replication and to determine the effects of N176 and N237 on nsp4 function and MHV replication, alanine substitutions of nsp4 N176, N237, or both were engineered into the MHV-A59 genome. The N176A, N237A, and N176A/N237A mutant viruses were viable, and N176 and N237 were glycosylated during infection of wild-type (wt) and mutant viruses. The nsp4 glycosylation mutants exhibited impaired virus growth and RNA synthesis, with the N237A and N176A/N237A mutant viruses demonstrating more profound defects in virus growth and RNA synthesis. Electron microscopic analysis of ultrastructure from infected cells demonstrated that the nsp4 mutants had aberrant morphology of virus-induced double-membrane vesicles (DMVs) compared to those infected with wt virus. The degree of altered DMV morphology directly correlated with the extent of impairment in viral RNA synthesis and virus growth of the nsp4 mutant viruses. The results indicate that nsp4 plays a critical role in the organization and stability of DMVs. The results also support the conclusion that the structure of DMVs is essential for efficient RNA synthesis and optimal replication of coronaviruses.
Most viral glycoproteins mediating membrane fusion adopt a metastable native conformation and undergo major conformational changes during fusion. We previously described a panel of compounds that specifically prevent fusion induced by measles virus ( The transport competence and activity of the mutants can be restored, however, by incubation at reduced temperature or in the presence of the inhibitory compounds, indicating that the F escape mutants have a reduced conformational stability and that the inhibitors stabilize a transport-competent conformation of the F trimer. The data support the conclusion that residues located in the head domain of the F trimer and the HR-B region contribute jointly to controlling F conformational stability.
Measles virus (MV) is one of the most infectious pathogens known. Despite the existence of a vaccine, over 500,000 deaths/year result from MV or associated complications. Anti-measles compounds could conceivably reverse these statistics. Previously, we described a homology model of the MV fusion protein trimer and a putative binding site near the head-neck region. The resulting model permitted the identification of two nonpeptidic entry inhibitors. Here, we present the design, synthesis, and bioevaluation of several series of fusion inhibitors and describe their structure-activity relationships (SAR). Five simply substituted anilides show low-microM blockade of the MV, one of which (AS-48) exhibits IC50 = 0.6-3.0 microM across a panel of wild-type MV strains found in the field. Molecular field topology analysis (MFTA), a 2D QSAR approach based on local molecular properties (atomic charges, hydrogen-bonding capacity and local lipophilicity), applied to the anilide series suggests structural modifications to improve potency.
The incidence of measles virus (MV) infection has been significantly reduced in many nations through extensive vaccination; however, the virus still causes significant morbidity and mortality in developing countries. Measles outbreaks also occur in some developed countries that have failed to maintain high vaccine coverage rates. While vaccination is essential in preventing the spread of measles, case management would greatly benefit from the use of therapeutic agents to lower morbidity. Thus, the development of new therapeutic strategies is desirable. We previously reported the generation of a panel of small-molecule MV entry inhibitors. Here we show that our initial lead compound, although providing proof of concept for our approach, has a short half-life (<16 h) under physiological conditions. In order to combine potent antiviral activity with increased compound stability, a targeted library of candidate molecules designed on the structural basis of the first lead has been synthesized and tested against MV. We have identified an improved lead with low toxicity and high stability (half-life Ͼ Ͼ 16 h) that prevents viral entry and hence infection. This compound shows high MV specificity and strong activity (50% inhibitory concentration ؍ 0.6 to 3.0 M, depending on the MV genotype) against a panel of wild-type MV strains representative of viruses that are currently endemic in the field.
Background:The reovirus outer capsid protein 3 acts as a substrate for intracellular proteases. Results: Two polymorphic amino acids in 3 act in opposition to determine protease sensitivity, disassembly kinetics, and biochemical stability. Conclusion: A regulatory network of residues maintains optimal reovirus outer capsid function. Significance: The balance between stability and instability of capsid structures is likely to be an important determinant of viral fitness.
Many viruses invade mucosal surfaces to establish infection in the host. Some viruses are restricted to mucosal surfaces, whereas others disseminate to sites of secondary replication. Studies of strain-specific differences in reovirus mucosal infection and systemic dissemination have enhanced an understanding of viral determinants and molecular mechanisms that regulate viral pathogenesis. After peroral inoculation, reovirus strain type 1 Lang replicates to high titers in the intestine and spreads systemically, whereas strain type 3 Dearing (T3D) does not. These differences segregate with the viral S1 gene segment, which encodes attachment protein 1 and nonstructural protein 1s. In this study, we define genetic determinants that regulate reovirus-induced pathology following intranasal inoculation and respiratory infection. We report that two laboratory isolates of T3D, T3D C and T3D F , differ in the capacity to replicate in the respiratory tract and spread systemically; the T3D C isolate replicates to higher titers in the lungs and disseminates, while T3D F does not. Two nucleotide polymorphisms in the S1 gene influence these differences, and both S1 gene products are involved. T3D C amino acid polymorphisms in the tail and head domains of 1 protein influence the sensitivity of virions to protease-mediated loss of infectivity. The T3D C polymorphism at nucleotide 77, which leads to coding changes in both S1 gene products, promotes systemic dissemination from the respiratory tract. A 1s-null virus produces lower titers in the lung after intranasal inoculation and disseminates less efficiently to sites of secondary replication. These findings provide new insights into mechanisms underlying reovirus replication in the respiratory tract and systemic spread from the lung. Many viruses enter host organisms by invading mucosal surfaces, including those that line the respiratory tract. Infection by some pneumotropic viruses is restricted to the respiratory tract, whereas others replicate in the lung and disseminate to sites of secondary replication. Mammalian orthoreoviruses (reoviruses) naturally infect both the respiratory and gastrointestinal tracts (1). Reovirus strains differ in the capacity to replicate at mucosal sites and disseminate systemically. Studies of strain-specific differences in reovirus mucosal infection and systemic spread have enhanced an understanding of viral determinants and molecular mechanisms that regulate reovirus pathogenesis. For example, after peroral or intratracheal inoculation, reovirus strain type 1 Lang (T1L) replicates to higher titers than does strain type 3 Dearing (T3D) (2). This difference in replication efficiency at the site of primary replication segregates with the reovirus S1 gene segment (2, 3). Like T1L, reassortant virus 3HA1, with nine gene segments from T3D and an S1 gene from T1L, replicates to high titers in mucosal tissues (2). In contrast, reassortant virus 1HA3, with nine gene segments from T1L and an S1 gene from T3D, fails to replicate to high titers at those sit...
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