Evidence That the ATR/Chk1 Pathway Maintains Normal Replication Fork Progression during Unperturbed S Phase

If cells are treated with DNA damaging agents or inhibitors that interfere with ongoing DNA replication, the intra-S and S/M checkpoints delay progression through S phase and mitotic entry, respectively, to allow time for DNA repair and replication restart. In vertebrates, these checkpoint responses to replication blocks are largely mediated by the sensor kinase ATR and its major downstream effector kinase Chk1. Increasing evidence suggests that the ATR pathway is also vital in the absence of exogenous stresses, i.e. during “unperturbed” replication. Both ATR and Chk1 are essential proteins in vertebrates, and lack of components of the ATR/Chk1 pathway can result in impaired replication and spontaneous DNA damage. Here we give an overview of how the ATR/Chk1 pathway responds to exogenously blocked replication and then describe evidence for roles of this pathway during replication in an unperturbed S phase.     

A Cell-Intrinsic Inhibitor of HIV-1 Reverse Transcription in CD4+ T Cells from Elite Controllers

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Single-Cell and Single-Cycle Analysis of HIV-1 Replication

The dynamics of the late stages of the HIV-1 life cycle are poorly documented. Viral replication dynamics are typically measured in populations of infected cells, but asynchrony that is introduced during the early steps of HIV-1 replication complicates the measurement of the progression of subsequent steps and can mask replication dynamics and their variation in individual infected cells. We established microscopy-based methods to dynamically measure HIV-1-encoded reporter gene and antiviral gene expression in individual infected cells. We coupled these measurements with conventional analyses to quantify delays in the HIV-1 replication cycle imposed by the biphasic nature of HIV-1 gene expression and by the assembly-inhibiting property of the matrix domain of Gag. We further related the dynamics of restriction factor (APOBEC3G) removal to the dynamics of HIV-1 replication in individual cells. These studies provide a timeline for key events in the HIV-1 replication cycle, and reveal that the interval between the onset of early and late HIV-1 gene expression is only ~3h, but matrix causes a ~6–12h delay in the generation of extracellular virions. Interestingly, matrix delays particle assembly to a time at which APOBEC3G has largely been removed from the cell. Thus, a need to prepare infected cells to be efficient producers of infectious HIV-1 may provide an impetus for programmed delays in HIV-1 virion genesis. Our findings also emphasize the significant heterogeneity in the length of the HIV-1 replication cycle in homogenous cell populations and suggest that a typical infected cell generates new virions for only a few hours at the end of a 48h lifespan. Therefore, small changes in the lifespan of infected cells might have a large effect on viral yield in a single cycle and the overall clinical course in infected individuals.