Influenza viruses replicate within the nucleus of the host cell. This uncommon RNA virus trait provides influenza with the advantage of access to the nuclear machinery during replication. However, it also increases the complexity of the intracellular trafficking that is required for the viral components to establish a productive infection. The segmentation of the influenza genome makes these additional trafficking requirements especially challenging, as each viral RNA (vRNA) gene segment must navigate the network of cellular membrane barriers during the processes of entry and assembly. To accomplish this goal, influenza A viruses (IAVs) utilize a combination of viral and cellular mechanisms to coordinate the transport of their proteins and the eight vRNA gene segments in and out of the cell. The aim of this review is to present the current mechanistic understanding for how IAVs facilitate cell entry, replication, virion assembly, and intercellular movement, in an effort to highlight some of the unanswered questions regarding the coordination of the IAV infection process.
Eukaryotic
cells possess a dynamic network of membranes that vary
in lipid composition. To perform numerous biological functions, cells
modulate their shape and the lateral organization of proteins associated
with membranes. The modulation is generally facilitated by physical
cues that recruit proteins to specific regions of the membrane. Analyzing
these cues is difficult due to the complexity of the membrane conformations
that exist in cells. Here, we examine how different types of membrane
proteins respond to changes in curvature and to lipid phases found
in the plasma membrane. By using giant plasma membrane vesicles derived
from transfected cells, the proteins were positioned in the correct
orientation and the analysis was performed in plasma membranes with
a biological composition. Nanoscale membrane curvatures were generated
by extracting nanotubes from these vesicles with an optical trap.
The viral membrane protein neuraminidase was not sensitive to curvature,
but it did exhibit strong partitioning (coefficient of K = 0.16) disordered membrane regions. In contrast, the membrane repair
protein annexin 5 showed a preference for nanotubes with a density
up to 10–15 times higher than that on the more flat vesicle
membrane. The investigation of nanoscale effects in isolated plasma
membranes provides a quantitative platform for studying peripheral
and integral membrane proteins in their natural environment.
Genome delivery to the proper cellular compartment for transcription and replication is a primary goal of viruses. However, methods for analyzing viral genome localization and differentiating genomes with high identity are lacking, making it difficult to investigate entry-related processes and co-examine heterogeneous RNA viral populations. Here, we present an RNA labeling approach for single-cell analysis of RNA viral replication and co-infection dynamics in situ, which uses the versatility of padlock probes. We applied this method to identify influenza A virus (IAV) infections in cells and lung tissue with single-nucleotide specificity and to classify entry and replication stages by gene segment localization. Extending the classification strategy to co-infections of IAVs with single-nucleotide variations, we found that the dependence on intracellular trafficking places a time restriction on secondary co-infections necessary for genome reassortment. Altogether, these data demonstrate how RNA viral genome labeling can help dissect entry and co-infections.
We used the amphipathic styrene maleic acid (SMA) co-polymer to extract cytochrome c oxidase (CytcO) in its native lipid environment from S. cerevisiae mitochondria. Native nanodiscs containing one CytcO per disc were purified using affinity chromatography. The longest cross-sections of the native nanodiscs were 11 nm x 14 nm. Based on this size we estimated that each CytcO was surrounded by ~100 phospholipids. The native nanodiscs contained the same major phospholipids as those found in the mitochondrial inner membrane.Even though CytcO forms a supercomplex with cytochrome bc 1 in the mitochondrial membrane, cyt. bc 1 was not found in the native nanodiscs. Yet, the loosely-bound Respiratory
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