Genomic location dictates lytic promoter activity during herpes simplex virus latency

Abstract

AbstractHerpes simplex virus 1 (HSV-1) is a significant pathogen that establishes life-long latent infections with intermittent episodes of resumed disease. In mouse models of HSV infection, persistent low-level lytic gene expression has been detected during latency in the absence of spontaneous reactivation events leading to new virus production. This viral activity during latency has been reported using a sensitive Cre-marking model for several lytic gene promoters placed in one location in the HSV-1 genome. Here we extend these findings in the same model by examining first, the activity of an ectopic lytic gene promoter in other places in the genome and second, whether native promoter activity might be detectable. We found that both for ectopic and native lytic gene promoters,Creexpression during latency was detected in our model, but only when the promoter was located near the ends of the unique long genome segment. This location is significant because it is in close proximity to the region from which latency associated transcripts (LAT) are derived. These results show for the first time that native HSV-1 lytic gene promoters can produce protein products during latency, but that this activity is only detectable when they are located close to the LAT locus.Author summaryHSV is a significant human pathogen and the best studied model of mammalian virus latency. Traditionally the active (lytic) and inactive (latent) phases of infection were considered to be distinct, but the notion of latency being entirely quiescent is evolving due to the detection of some lytic gene expression during latency. Here we add to this literature by finding that activity can be found for native lytic gene promotors as well as for constructs placed ectopically in the HSV genome. However, this activity was only detectable when these promoters were located close by a region known to be transcriptionally active during latency. These data have implications for our understanding of HSV gene regulation during latency and the extent to which transcriptionally active regions are insulated from adjacent parts of the viral genome.