Abstract
Despite displaying broad tropism in vivo, human cytomegalovirus (CMV) contained in bodily fluids replicates inefficiently in most cultured cell types except fibroblasts. As propagation in fibroblasts leads to the accumulation of genomic changes, a number of strains were generated by serial passaging on endothelial cells. One of these, TB40/E, was shown to contain a mixture of genetically distinct virus variants, and to retain tropism for fibroblasts, endothelial and epithelial cells. Cloning of an endotheliotropic subpopulation produced the TB40-BAC4 variant, extensively used in CMV tropism studies. Because TB40-BAC4 represents only one of the different variants comprising TB40/E, we generated a series of epithelial-cell adapted stocks derived from a TB40/E mixed stock, rather than from TB40-BAC4. Within two passages on ARPE-19 cells, virus populations were produced with the ability to enter and initiate replication with similar efficiencies in both epithelial cells and fibroblasts. Although the ability to release progeny also increased, cell-free virus yields from ARPE-19 cells remained consistently two to three-logs lower than from fibroblasts, hinting at the existence of a post-entry and post-genome synthesis block in epithelial cells. Multinucleated syncytia also rapidly appeared exclusively in ARPE-19 cell cultures, where their numbers and dimensions increased with virus passage. Irrespective of the number of infected nuclei comprising each syncytium, however, only one cytoplasmic virion assembly compartment was consistently observed, leading us to speculate that improvements in entry efficiency associated with ARPE-19 cell adaptation lead to the development of syncytia, which may negatively affect progeny release by limiting the amount of resources available to maturing virions.
Highlights
The broad tropism characteristic of human cytomegalovirus (CMV) is at the source of the severe disease caused by this virus in immunocompromised individuals
Similar data were obtained after fibroblast infection with a GFP-expressing TB40-BAC4 derivative TB40/Ewt-GFP [29] reconstituted and passaged once in fibroblasts [30], while virions released by fibroblasts infected with TB40/Ewt-GFP reconstituted and passaged once in epithelial cells contained higher levels of pentameric complex (PC) than of trimeric complex (TC) [30]
As the PC is thought to be required for cell–cell fusion and syncytium formation in epithelial cells [2,36], we speculate that the substantial improvements in entry efficiency that accompany the selection of PC-rich variants are counterbalanced by the advent of complications in the process of progeny release, possibly due to the lack of sufficient cellular resources, or of plasma membrane surface, in the large infection-induced syncytia
Summary
The broad tropism characteristic of human cytomegalovirus (CMV) is at the source of the severe disease caused by this virus in immunocompromised individuals. Similar data were obtained after fibroblast infection with a GFP-expressing TB40-BAC4 derivative TB40/Ewt-GFP [29] reconstituted and passaged once in fibroblasts [30], while virions released by fibroblasts infected with TB40/Ewt-GFP reconstituted and passaged once in epithelial cells contained higher levels of PC than of TC [30] These findings suggest that growth in epithelial cells may be associated with the selection of genetic variants capable of producing PC-rich(er) virions, but the mechanisms supporting these cell-dependent differences in gH/gL partitioning into each complex remain obscure. The US16 protein was found to promote pentamer incorporation on the envelope, potentially by interacting with UL130 in the cytoplasmic virion assembly compartment (VAC) at late times post-infection [34] Whether these mechanisms are differentially regulated in a cell type-specific manner, has not been investigated, so their contributions to explaining the differences in TC/PC content of virions produced by fibroblasts vs epithelial cells remain unknown. As the PC is thought to be required for cell–cell fusion and syncytium formation in epithelial cells [2,36], we speculate that the substantial improvements in entry efficiency that accompany the selection of PC-rich variants are counterbalanced by the advent of complications in the process of progeny release, possibly due to the lack of sufficient cellular resources, or of plasma membrane surface, in the large infection-induced syncytia
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