Viral Membrane Fusion: A Dance Between Proteins and Lipids.

There are at least 21 families of enveloped viruses that infect mammals, and many contain members of high concern for global human health. All enveloped viruses have a dedicated fusion protein or fusion complex that enacts the critical genome-releasing membrane fusion event that is essential before viral replication within the host cell interior can begin. Because all enveloped viruses enter cells by fusion, it behooves us to know how viral fusion proteins function. Viral fusion proteins are also major targets of neutralizing antibodies, and hence they serve as key vaccine immunogens. Here we review current concepts about viral membrane fusion proteins focusing on how they are triggered, structural intermediates between pre- and postfusion forms, and their interplay with the lipid bilayers they engage. We also discuss cellular and therapeutic interventions that thwart virus-cell membrane fusion.

Serinc5 Restricts HIV Membrane Fusion by Altering Lipid Order and Heterogeneity in the Viral Membrane.

The host restriction factor, Serinc5, incorporates into budding HIV particles and inhibits their infection by an incompletely understood mechanism. We have previously reported that Serinc5 but not its paralogue, Serinc2, blocks HIV cell entry by membrane fusion, specifically by inhibiting fusion pore formation and dilation. A body of work suggests that Serinc5 may alter the conformation and clustering of the HIV fusion protein, Env. To contribute an additional perspective to the developing model of Serinc5 restriction, we assessed Serinc2 and Serinc5's effects on HIV pseudoviral membranes. By measuring pseudoviral membrane thickness via cryo-electron microscopy and order via the fluorescent dye, FLIPPER-TR, Serinc5 was found to increase membrane heterogeneity, skewing the distribution toward a larger fraction of the viral membrane in an ordered phase. We also directly observed for the first time the coexistence of membrane domains within individual viral membrane envelopes. Using a total internal reflection fluorescence-based single particle fusion assay, we found that treatment of HIV pseudoviral particles with phosphatidylethanolamine (PE) rescued HIV pseudovirus fusion from restriction by Serinc5, which was accompanied by decreased membrane heterogeneity and order. This effect was specific for PE and did not depend on acyl chain length or saturation. Together, these data suggest that Serinc5 alters multiple interrelated properties of the viral membrane─lipid chain order, rigidity, line tension, and lateral pressure─which decrease the accessibility of fusion intermediates and disfavor completion of fusion. These biophysical insights into Serinc5 restriction of HIV infectivity could contribute to the development of novel antivirals that exploit the same weaknesses.

Disparate Regions of the Human Chemokine CXCL10 Exhibit Broad-Spectrum Antimicrobial Activity against Biodefense and Antibiotic-Resistant Bacterial Pathogens.

CXCL10 is a pro-inflammatory chemokine produced by the host in response to microbial infection. In addition to canonical, receptor-dependent actions affecting immune-cell migration and activation, CXCL10 has also been found to directly kill a broad range of pathogenic bacteria. Prior investigations suggest that the bactericidal effects of CXCL10 occur through two distinct pathways that compromise the cell envelope. These observations raise the intriguing notion that CXCL10 features a separable pair of antimicrobial domains. Herein, we affirm this possibility through peptide-based mapping and structure/function analyses, which demonstrate that discrete peptides derived from the N- and C-terminal regions of CXCL10 mediate bacterial killing. The N-terminal derivative, peptide P1, exhibited marked antimicrobial activity against Bacillus anthracis vegetative bacilli and spores, as well as antibiotic-resistant clinical isolates of Klebsiella pneumoniae, Acinetobacter baumannii, Enterococcus faecium, and Staphylococcus aureus, among others. At bactericidal concentrations, peptide P1 had a minimal degree of chemotactic activity, but did not cause red blood cell hemolysis or cytotoxic effects against primary human cells. The C-terminal derivative, peptide P9, exhibited antimicrobial effects, but only against Gram-negative bacteria in low-salt medium─conditions under which the peptide can adopt an α-helical conformation. The introduction of a hydrocarbon staple induced and stabilized α-helicity; accordingly, stapled peptide P9 displayed significantly improved bactericidal effects against both Gram-positive and Gram-negative bacteria in media containing physiologic levels of salt. Together, our findings identify and characterize the antimicrobial regions of CXCL10 and functionalize these novel determinants as discrete peptides with potential therapeutic utility against difficult-to-treat pathogens.

Distinct insulin granule subpopulations implicated in the secretory pathology of diabetes types 1 and 2.

Insulin secretion from ß-cells is reduced at the onset of type-1 and during type-2 diabetes. Although inflammation and metabolic dysfunction of ß-cells elicit secretory defects associated with type-1 or type-2 diabetes, accompanying changes to insulin granules have not been established. To address this, we performed detailed functional analyses of insulin granules purified from cells subjected to model treatments that mimic type-1 and type-2 diabetic conditions and discovered striking shifts in calcium affinities and fusion characteristics. We show that this behavior is correlated with two subpopulations of insulin granules whose relative abundance is differentially shifted depending on diabetic model condition. The two types of granules have different release characteristics, distinct lipid and protein compositions, and package different secretory contents alongside insulin. This complexity of ß-cell secretory physiology establishes a direct link between granule subpopulation and type of diabetes and leads to a revised model of secretory changes in the diabetogenic process.

Diabetes is a disease that occurs when sugar levels in the blood can no longer be controlled by a hormone called insulin. People with type 1 diabetes lose the ability to produce insulin after their immune system attacks the ß-cells in their pancreas that make this hormone. People with type 2 diabetes develop the disease when ß-cells become exhausted from increased insulin demand and stop producing insulin. ß-cells store insulin in small compartments called granules. When blood sugar levels rise, these granules fuse with the cell membrane allowing ß-cells to release large quantities of insulin at once. This fusion is disrupted early in type 1 diabetes, but later in type 2: the underlying causes of these disruptions are unclear. In the laboratory, signals that trigger inflammation and molecules called fatty acids can mimic type 1 or type 2 diabetes respectively when applied to insulin-producing cells. Kreutzberger, Kiessling et al. wanted to know whether pro-inflammatory molecules and fatty acids affect insulin granules differently at the molecular level. To do this, insulin-producing cells were grown in the lab and treated with either fatty acids or pro-inflammatory molecules. The insulin granules of these cells were then isolated. Next, the composition of the granules and how they fused to lab-made membranes that mimic the cell membrane was examined. The experiments revealed that healthy ß-cells have two types of granules, each with a different version of a protein called synaptotagmin. Cells treated with molecules mimicking type 1 diabetes lost granules with synaptotagmin-7, while granules with synaptotagmin-9 were lost in cells treated with fatty acids to imitate type 2 diabetes. Each type of granule responded differently to calcium levels in the cell and secreted different molecules, indicating that each elicits a different diabetic response in the body. These findings suggest that understanding how insulin granules are formed and regulated may help find treatments for type 1 and 2 diabetes, possibly leading to therapies that reverse the loss of different types of granules. Additionally, the molecules of these granules may also be used as markers to determine the stage of diabetes. More broadly, these results show how understanding how molecule release changes with disease in different cell types may help diagnose or stage a disease.

HIV-cell membrane fusion intermediates are restricted by Serincs as revealed by cryo-electron and TIRF microscopy.

To enter a cell and establish infection, HIV must first fuse its lipid envelope with the host cell plasma membrane. Whereas the process of HIV membrane fusion can be tracked by fluorescence microscopy, the 3D configuration of proteins and lipids at intermediate steps can only be resolved with cryo-electron tomography (cryoET). However, cryoET of whole cells is technically difficult. To overcome this problem, we have adapted giant plasma membrane vesicles (or blebs) from native cell membranes expressing appropriate receptors as targets for fusion with HIV envelope glycoprotein-expressing pseudovirus particles with and without Serinc host restriction factors. The fusion behavior of these particles was probed by TIRF microscopy on bleb-derived supported membranes. Timed snapshots of fusion of the same particles with blebs were examined by cryo-ET. The combination of these methods allowed us to characterize the structures of various intermediates on the fusion pathway and showed that when Serinc3 or Serinc5 (but not Serinc2) were present, later fusion products were more prevalent, suggesting that Serinc3/5 act at multiple steps to prevent progression to full fusion. In addition, the antifungal amphotericin B reversed Serinc restriction, presumably by intercalation into the fusing membranes. Our results provide a highly detailed view of Serinc restriction of HIV-cell membrane fusion and thus extend current structural and functional information on Serinc as a lipid-binding protein.

Formalising the precepting process: A concept analysis of preceptorship.

AIMS AND OBJECTIVES: To elucidate the terminology associated with preceptorships, articulate an operational description of preceptorship that may be useful in formalising the precepting process and provide guidance for constructing a clinical environment where precepting can thrive. BACKGROUND: Precepting facilitates the transition of nurses into new roles. Precepting may improve patient outcomes and safety, as well as enhance nursing satisfaction. Most research focuses on preceptor preparation and perceptions. A comprehensive operational description of what is required to formalise the precepting process is missing from the literature. DESIGN: This concept analysis was completed using a combination of Walker and Avant's and Rodger's methods. METHODS: Existing literature relating to preceptorship was reviewed. Critical attributes, antecedents, consequences and empirical referents were identified. Model, contrary, related and borderline cases were developed. RESULTS: Preceptorships have the specific attributes of being (i) one-on-one relationships, (ii) embedded within formalised programmes, (iii) that evolve over set amounts of time, (iv) to systematically facilitate practical experiences. Antecedents include how precepting is triggered and organisational supporting activities that may facilitate effective precepting. Consequences include new hire preparedness, confidence and increased retention. Empirical referents are provided for assessing hands-on clinical expertise, individualisation of precepting programmes and the preceptor-preceptee relationship. CONCLUSIONS: This concept analysis provides a holistic view of the precepting process that shifts the focus from the people or checklist to formalised preceptorships. RELEVANCE TO CLINICAL PRACTICE: Continuity throughout an organisation's system streamlines the process of hiring new employees and transitioning nursing students to practice. Organisational policies, dedicated resources and engagement in systematically improving the precepting process are critical. Nurse managers must promote and support formalised preceptorships by providing preceptors and preceptees the time and space needed and fostering a culture that supports preceptorships.

Evolutionary responses of innate immunity to adaptive immunity.

Innate immunity is present in all metazoans, whereas the evolutionarily more novel adaptive immunity is limited to jawed fishes and their descendants (gnathostomes). We observe that the organisms that possess adaptive immunity lack diversity in their innate pattern recognition receptors (PRRs), raising the question: did gnathostomes lose the diversity of their ancestors? Or might innate receptors have diversified in the lineage lacking adaptive immunity? We address this question by contextualizing PRRs in their distinct functional roles in organisms possessing or lacking adaptive immunity. In particular, limited PRR diversity in gnathostomes is accompanied by an expansion of the JAK/STAT signaling pathway, which would suggest that the development of adaptive immunity shifted the role of PRRs from the entirety of pathogen recognition to regulators of subsequent immune responses. As PRRs became essential upstream components of the increasingly complex JAK/STAT signaling cascade in organisms possessing adaptive immunity, it may have limited their freedom to diversify. By contrast, PRR diversity continues to confer an advantage for organisms lacking the means to generate non-self recognition receptors via somatic mutation. Extensive deuterostome PRR diversity may have been driven by gnathostome adaptive immunity inducing diversification of shared pathogens, which exerted strong diversifying selection on deuterostome PRRs. Thus, the development of adaptive immunity changed the role of PRRs in immunity as well as the selective forces on host receptors, deuterostomes, and pathogens.