Herpes Simplex Virus 1 Manipulates Host Cell Antiviral and Proviral DNA Damage Responses

Distinct DNA damage response kinase activation to input and replicating viral DNA.The life cycle of HSV-1 can be divided into two stages: pre- and post-viral DNA replication. To characterize the response to input viral DNA, we infected primary human foreskin fibroblasts (HFFs) with HSV-1 d109. This virus expresses low levels of all genes in normal cells, and nuclear viral DNA persists in a quiescent state for at least 28 days in cell culture (45), so it is a good model for the study of input viral DNA delivered by infection. We investigated the responses at 2 and 8 h postinfection, the times of the onset of initial viral gene expression and of viral genome replication and robust gene expression, respectively (46). By 2 h after d109 virus infection, we observed robust Chk2 and H2AX phosphorylation, along with a substantial upregulation of total H2AX, low levels of p53 phosphorylation at serine 15, and low levels of ATM phosphorylation (Fig. 1A, lane 5). This argued that Chk2 was activated by incoming viral DNA. Upregulation of H2AX in response to an activated DDR has been described previously (47), and our results argued that d109 infection was sufficient to trigger this response. By 8 h postinfection (hpi), phosphorylation of these proteins was decreased (Fig. 1A, lane 6), presumably due to resolution of the DDR.

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FIG 1

Biphasic DDR kinase response to incoming and replicating viral DNA. Primary HFFs were either mock infected or infected with HSV-1 d109 or WT virus at a multiplicity of infection (MOI) of 5 in either the presence or absence of 200 μM ACV added 1 hpi in the case of WT virus. Lysates were harvested for immunoblot analysis at 2 and 8 hpi (A). HFFs were also infected with 7134 or 7134R virus at an MOI of 5 with and without 200 μM ACV treatment 1 hpi, and lysates were harvested at 2, 8, and 24 hpi (B). Immunoblots presented are representative of two independent experiments. “Mock” indicates infection medium alone (no virus).

To investigate the responses to replicating and replicated viral DNA, we infected HFFs with HSV-1 wild type (WT) virus in either the presence or absence of the viral DNA replication inhibitor acyclovir (ACV). In infected cells undergoing viral DNA synthesis (i.e., without ACV), we observed strong Chk2 phosphorylation by 2 hpi (Fig. 1A, lane 7), like d109 infection, that decreased by 8 hpi (lane 8). Interestingly, treatment with ACV to block viral DNA synthesis abrogated this reduction (Fig. 1A, lanes 9 and 10), arguing that viral DNA replication or a viral late gene product suppressed Chk2. We observed ATM, H2AX, and p53 serine 15 and 20 phosphorylation by 8 hpi (Fig. 1A, lane 8), and all but serine 15 phosphorylation were sensitive to ACV treatment (Fig. 1A, lane 10), arguing that viral DNA replication increased levels of phosphorylated forms of these proteins. The phosphorylation of serine 15 with ACV treatment (lane 10) suggested that phosphorylation occurred between 2 hpi and the onset of genome replication, perhaps by the prolonged presence of the parental genome or IE and E gene expression. We did not observe H2AX phosphorylation at 2 hpi following WT infection (Fig. 1A, lane 7), as we did with d109. We believe that while d109 is an accurate model for input viral DNA, the virus prep of d109 likely contained a higher number of viral particles per PFU than the WT virus prep, evidenced by the abundance of gB glycoproteins (Fig. 1A, lanes 5 and 7). This could have led to a stronger H2AX response than WT virus infection as a result of a higher abundance of input genomes when we used the same multiplicity of infection (MOI). Together, these observations indicated a biphasic DDR to input and replicating viral DNA, with Chk2 being activated primarily by incoming viral genomes and ATM being activated by replicating/progeny DNA.

Effect of the HSV-1 ICP0 protein on the DDR.Prior studies had observed that the viral ICP0 E3 ubiquitin ligase can promote ATM and Chk2 phosphorylation (48), inhibit ATRIP/ATR function (39), and inhibit downstream repair processes by promoting the degradation of the RNF8 and RNF168 E3 ubiquitin ligases (33). To investigate the effects of ICP0 in our experimental system, we infected HFFs with the ICP0-null 7134 virus and the repaired 7134R virus (49). Similar to WT virus, Chk2 was phosphorylated by 2 hpi (Fig. 1B, lanes 5 and 11), independently of ICP0, and decreased over the course of infection (Fig. 1B, lanes 6 and 12). The decrease was not as rapid with 7134 infection as with 7134R, and we attributed this to the overall slower replication kinetics of the virus without ICP0. We observed ATM phosphorylation by 8 hpi with both 7134 and 7134R (Fig. 1B, lanes 6 and 12), with the 8 h time point being sensitive to ACV treatment (lanes 9 and 15). Interestingly, by 24 hpi in the presence of ACV, ATM was phosphorylated for both viruses (Fig. 1B, lanes 10 and 16), suggesting that, despite replication being inhibited, prolonged presence of the viral genome and/or prolonged expression of viral IE and E genes led to ATM activation. H2AX phosphorylation followed a similar profile (Fig. 1B, lanes 10 and 16). H2AX phosphorylation was reduced at 8 hpi with ACV treatment for both viruses (Fig. 1B, lanes 9 and 15) but was independent of viral DNA replication and viral late gene expression by 24 hpi (Fig. 1B, lanes 10 and 16). Together, our results argued that the DDR kinase responses to 7134 and 7134R were largely similar, with minor differences attributed to the slower replication kinetics of the ICP0⁻ virus.

We also observed phosphorylation of p53 serine 15 with both viruses (Fig. 1B, lanes 7 and 13). However, phosphorylation in the absence of ICP0 occurred much more slowly, occurring primarily at 24 hpi. We also attributed this, as with Chk2 phosphorylation, to the decreased replication kinetics of the 7134 virus. Similar to WT infection, p53 serine 15 phosphorylation was not sensitive to ACV treatment for both viruses (Fig. 1B, lanes 10 and 16), arguing that phosphorylation of this residue was independent of viral DNA replication and L gene expression. Interestingly, we observed very little phosphorylation of p53 on serine 20 following infection with 7134 (Fig. 1B, lanes 5 to 10). Because we observed that phosphorylation of this residue was dependent on viral DNA replication following WT infection, we hypothesized that 7134 did not undergo sufficient levels of DNA replication to stimulate phosphorylation. In agreement with WT infection, 7134R infection stimulated phosphorylation of p53 serine 20 by 8 hpi (Fig. 1B, lane 12) that was reduced by ACV treatment (lane 15). Interestingly, we observed serine 20 phosphorylation of p53 in 7134 virus-infected cells by 24 hpi in the presence of ACV (Fig. 1B, lane 10), arguing that, as in the case of ATM phosphorylation, prolonged presence of viral DNA and/or viral gene expression can stimulate p53 phosphorylation.

Thus, we did not observe any significant qualitative differences between ICP0-null and ICP0-expressing viruses. We observed only minor differences in the kinetics of phosphorylation of DDR proteins, most likely due to the decreased replication kinetics of the ICP0-null 7134 virus.

ATM promotes the DDR to viral infection.Having characterized the kinase pathway responses to input and replicating viral DNA, we further sought to determine the kinase(s) responsible for p53, H2AX, ATM, and Chk2 phosphorylation and whether the kinase(s) responsible is different between input and replicating DNA. We generated gene knockouts of ATM and CHEK2 in primary HFFs using clustered regularly interspaced palindromic repeats (CRISPR)-Cas9 (Fig. 2A). We also generated a knockout cell line for MDC1. MDC1 has been observed to localize adjacent to incoming viral genomes (33), but its role during HSV-1 replication has not been investigated. To determine the kinases responsible for the response to input DNA, we infected the knockout HFFs with d109 for 2 h. Knockout of ATM ablated Chk2 and p53 serine 15 phosphorylation (Fig. 2B, lane 8) compared to both normal and Cas9 control HFFs (Fig. 2B, lanes 6 and 7), arguing that ATM was required for the phosphorylation of both of these proteins. Knockout of MDC1 had no effect on the phosphorylation of any of the proteins investigated (Fig. 2B, line 10), suggesting that Mdc1 did not have a role in promoting the DDR in the first 2 hpi. Surprisingly, knockout of ATM had no effect on H2AX phosphorylation (Fig. 2B, lane 8). DNA-PK also phosphorylates H2AX in response to DNA damage (50, 51), and we hypothesized that this kinase may be responsible for the H2AX phosphorylation response to input DNA. To test this, we knocked down PRKDC, encoding DNA-PKcs, and infected the knockdown cells with d109 virus for 2 h. Compared to nontargeting small interfering RNA (siRNA), γH2AX was only partially reduced with knockdown (see Fig. S1A, lanes 3 and 4, in the supplemental material), arguing that DNA-PK functioned redundantly with another kinase. HSV-1 infection also activates the ATR kinase known to also phosphorylate H2AX (38, 52). Therefore, DNA-PK may function redundantly with ATR and ATM.

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FIG 2

ATM promotes the DDR to both cellular DNA damage and HSV-1 infection. Primary HFFs were transduced with lentiviruses that express Cas9, a guide RNA against ATM, CHEK2, or MDC1, and puromycin resistance as specified in Materials and Methods. Blot images are representative of three passages of cells (A). Normal HFFs, Cas9 control, and knockout HFFs were mock infected or infected with d109 at an MOI of 5, and lysates were harvested for immunoblotting at 2 hpi (B). Control and knockout cells were either mock infected or infected with WT virus at an MOI of 5, and lysates were harvested at the indicated times (C). Control and knockout HFFs were treated with either DMSO or 20 μM etoposide, and lysates were harvested at the indicated times posttreatment (D). Cas9 was FLAG tagged. Blots are representative of two independent experiments (B to D).

To determine if ATM, Chk2, and Mdc1 play any role following viral DNA replication, we infected the control and knockout HFFs with WT virus. By 2 hpi, the results mirrored d109 infection, where knockout of ATM strongly reduced the phosphorylation of Chk2 (Fig. 2C, lane 8). By 8 hpi, knockout of ATM ablated the phosphorylation of Chk2 and p53 at both serine residues (Fig. 2C, lane 13), arguing that ATM was largely responsible for progression of the DDR in response to DNA replication. Interestingly, knockout of Chk2 had no effect on the phosphorylation of p53 on serine 20 (Fig. 2C, lane 14). Because a previous publication reported that Chk2 promoted p53 phosphorylation in response to cellular DNA damage (16), this may be an HSV-specific effect. In addition, ATM knockout abolished H2AX phosphorylation by 8 hpi (Fig. 2C, lane 13), arguing that ATM phosphorylated H2AX stimulated by replicating viral DNA, not incoming DNA. Knockout of MDC1 had no effect on any of the proteins investigated (Fig. 2C, lanes 10 and 15), indicating a dispensable role for Mdc1 in propagating the DDR.

Having established the effects on wild-type virus, we wanted to determine whether similar results would be observed in the absence of ICP0. To test this, we infected control and knockout HFFs with 7134 and 7134R. For both viruses, ATM was still responsible for the phosphorylation of Chk2, H2AX, and both serine residues of p53 (Fig. S1B and C, lanes 12 to 14), arguing that the ATM dependency on propagating the DNA damage signal was independent of ICP0.

Etoposide induces a robust DDR in HFFs, distinct from HSV-1 infection.To investigate whether the response to cellular DNA damage was similar to or different from the response to viral infection, we treated control and knockout HFFs with etoposide to induce double-stranded DNA breaks for 2 and 8 h. By 2 h, we observed phosphorylation of ATM, Chk2, H2AX, and p53 on both serine residues (Fig. 2D, lanes 6 and 7). Interestingly, unlike HSV-1 infection, Chk2 phosphorylation was minimally dependent on ATM, as ATM knockout had only a small effect on Chk2 phosphorylation compared to Cas9 control cells (Fig. 2D, lane 8). γH2AX accumulation was also only partially dependent on ATM (Fig. 2D, lanes 8 and 13), indicating that, as with d109 infection, ATM may function redundantly with other DDR kinases to phosphorylate this histone variant. p53 phosphorylation on serines 15 and 20 was also dependent on ATM. Interestingly, we observed serine 20 phosphorylation at 2 h (Fig. 2D, lane 7), whereas for HSV-1, it was not observed until later times during infection, primarily stimulated by viral DNA replication. ATM, H2AX, and p53 phosphorylation persisted through 8 h posttreatment (Fig. 2D, lanes 11 and 12). Chk2 phosphorylation mirrored what was observed for HSV-1 infection. Its phosphorylation was observed beginning at 2 h (Fig. 2D, lanes 6 and 7) but was reduced by 8 h (lane 11 and 12). We attributed this to a resolution in the Chk2 arm of the DDR. These observations also argued that this Chk2 arm of the response was independent of ATM activity as initial Chk2 phosphorylation was not dependent on ATM, and Chk2 phosphorylation decreased over time whereas ATM phosphorylation levels remained constant (Fig. 2D, lanes 6, 7, 11, and 12). Phosphorylation of both p53 serine residues remained dependent on ATM at 8 h posttreatment (Fig. 2D, lane 13).

Together, our results argued that the cellular DNA damage response, at least with respect to damage caused by etoposide, was distinct from the response to HSV-1 infection. Etoposide treatment led to robust phosphorylation of all of the proteins investigated by 2 h, whereas for HSV-1 infection, protein phosphorylation was temporally separated, with the bulk of Chk2 and ATM phosphorylation occurring by 2 and 8 h postinfection, respectively. Chk2 phosphorylation also displayed various requirements for ATM depending on whether the response was triggered by cellular DNA damage or viral infection, indicating that viral gene products were manipulating the host DDR or that cellular and viral DNA were treated differently by cellular surveillance pathways.

Mre11 promotes distinct DDRs to cellular DNA damage and HSV-1 infection.Having observed the requirement of ATM for a robust DDR, we hypothesized that the MRN complex may have facilitated this phenotype by activating ATM in response to infection. Additionally, we sought to determine whether the H2AX histone variant has a role in regulating replication. One study reported that γH2AX has no impact on replication (36), but another study reported that H2AX enhanced replication (33). To test the roles of these proteins, we generated knockout HFFs for the genes MRE11A and H2AFX, encoding Mre11 and H2AX, respectively. MRE11A 3 (Fig. 3A, lane 2) gave a robust knockout, whereas MRE11A 4 (lane 3) gave an intermediate knockout, between those of Cas9 control and MRE11A 3 cells. H2AX levels were not detectable in H2AFX 3 cells (Fig. 3A, lane 4).

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FIG 3

Mre11 influences the response to incoming and replicating viral DNA. Primary HFFs were transduced with lentiviruses that express Cas9 only or Cas9 along with one of two guide RNAs against MRE11A or a guide RNA against H2AFX, as outlined in Materials and Methods. Blots are representative of three passages of cells (A). Cas9 control and MRE11A #3 cells were either mock infected or infected with d109 at an MOI of 5, and lysates were harvested at 2 hpi (B). Cas9 control and MRE11A #3 cells were mock infected or infected with 7134 or 7134R at an MOI of 5 and lysates harvested at 2, 8, and 24 hpi (C). Cas9, MRE11A #3, and MRE11A #4 cells were treated with either DMSO or 20 μM etoposide, and lysates were harvested at the indicated times posttreatment (D). Blots are representative of two independent experiments (B to D).

First, to determine whether the MRN complex facilitates the DDR to input viral DNA, we infected control and MRE11A 3 cells with d109 for 2 h. Loss of Mre11 reduced both ATM and Chk2, but not H2AX, phosphorylation (Fig. 3B, lane 4). This agreed with our ATM knockout results, where H2AX phosphorylation was also unaffected (Fig. 2B). Our results argued that the MRN complex was responsible for inducing an H2AX-independent DDR to incoming viral DNA.

Second, to determine whether the MRN complex promotes the DDR to replicating viral DNA, and also whether ICP0 has any role in this response, we infected control and MRE11A 3 knockout HFFs with the 7134 and 7134R viruses. Mre11 promoted Chk2 phosphorylation in response to both viruses by 2 h (Fig. 3C, lanes 8 and 14), indicating that, as with d109 infection, Mre11 and presumably the MRN complex were required for early recognition of incoming viral DNA. By 8 hpi with both 7134 and 7134R infection, ATM and H2AX phosphorylation were only weakly affected by MRE11A knockout (Fig. 3C, lanes 9 and 15), arguing that there were redundant pathways for their activation. p53 serine 15 phosphorylation was strongly reduced by 8 hpi with both viruses with MRE11A knockout (Fig. 3C, lanes 9 and 15), arguing that Mre11 primarily facilitated phosphorylation of this residue, most likely through ATM. p53 serine 20 phosphorylation following 7134R infection was also sensitive to Mre11 depletion at 8 hpi (Fig. 3C, lane 15), also arguing that Mre11 controlled phosphorylation of this residue of p53 as well. We also observed increased ICP4 and ICP0 protein levels with MRE11A knockout by 2 hpi for both ICP0⁻ and ICP0⁺ viruses (Fig. 3C, lanes 8 and 14), compared to the Cas9 control (lanes 5 and 11), providing evidence for a role for Mre11 in repression of IE gene expression.

To determine if Mre11 promoted a similar DDR to cellular damage, we treated control and MRE11A #3 and #4 cells with etoposide for 2 and 8 h. The results were very similar to those observed for ATM knockout. MRE11 #3 cells displayed reduced ATM and p53 serine 15 and 20 phosphorylation at both 2 and 8 h posttreatment (Fig. 3D, lanes 5 and 8). In agreement with our ATM knockout results, Chk2 phosphorylation was not reduced by the loss of Mre11 (Fig. 3D, lane 5), in fact Chk2 phosphorylation appeared to be increased relative to the Cas9 control cell line, arguing that Mre11 repressed Chk2 activation with etoposide treatment but promoted its activation following HSV-1 infection. γH2AX accumulation appeared to be independent of Mre11 (Fig. 3D, lane 5), again arguing for a redundancy in the kinases responsible, similar to our observations for HSV-1 infection. MRE11 #4 gave phenotypes similar to those seen in MRE11A #3 cells (Fig. 3D, lanes 6 and 9), but not as drastic. We attributed this to the incomplete knockout of MRE11A compared to MRE11A 3 cells. Together, our results indicated that Mre11 promoted the activation of ATM following both etoposide treatment and HSV-1 infection but were divergent with regard to Chk2 phosphorylation; ATM promoted its phosphorylation following HSV-1 infection but not etoposide treatment. p53 phosphorylation was promoted by both Mre11 and ATM, indicating that this arm of the DDR pathway was conserved between chemical treatment and infection.

ATM and Mre11 have opposing effects on HSV-1 replication.Prior studies have reported conflicting results as to whether various DDR proteins regulate the replication of HSV-1. To address these differences, we infected our ATM, CHEK2, and MDC1 knockout HFFs with WT, 7134R, and 7134 viruses and measured viral yields by plaque assay. Replication of both WT and 7134R viruses was unaffected by all of the gene knockouts (Fig. 4A). However, knockout of ATM demonstrated a trend toward reduction of replication of the 7134 virus, indicating that ATM had proviral functions, but only in the absence of ICP0. Interestingly, knockout of CHEK2 did not have an effect on any of the viruses. A prior study observed that loss of Chk2 decreased viral replication, but only in the presence of ICP0 (48). Our results argued that although ATM promoted the activation of Chk2, the latter was ultimately dispensable for HSV-1 replication, independent of ICP0 expression. Similarly, knockout of MDC1 affected the replication of the 7134 virus (Fig. 4A) only marginally.

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FIG 4

ATM and Mre11 have different roles in regulating the replication of HSV-1. Normal HFFs, Cas9 control, ATM 2, CHEK2 1, and MDC1 1 knockout cells were infected with WT, 7134R, and 7134 viruses at an MOI of 0.1, and total virus was collected 48 h later and titrated on U2OS cells (A). Cas9, MRE11A #3, MRE11A #4, and H2AFX #3 were also infected with WT, 7134R, and 7134 viruses at an MOI of 0.1 for 48 h, and total virus was quantified via plaque assay on U2OS cells (B). Data are expressed as the log₁₀ values of the plaque counts normalized to the number of initially infected knockout cells (A and B). Primary HFFs were transfected with either a nontargeting siRNA pool or a pool targeting TP53BP1. Knockdown cells were infected with 7134 and 7134R at an MOI of 0.1 for 48 h, and total virus was quantified by plaque assays on U2OS cells. Protein lysates for knockdown verification were taken at the time of infection (C). Data are averages from three independent experiments, with error bars representing the standard errors of the means (SEM). Statistical analysis was performed using an unpaired t test.

Having observed that DNA-PKcs partially promoted H2AX phosphorylation in response to incoming viral genomes, we next sought to determine its effect on replication. DNA-PKcs is known to be a target of ICP0 and is degraded during infection (53). However, we previously observed coprecipitation of DNA-PKcs with the viral DNA replication protein ICP8 during infection with wild-type virus, suggesting that degradation may not occur in all cell types (34). To test this in our primary fibroblast model system, we infected HFFs with 7134 and 7134R. Over time, DNA-PKcs was degraded with 7134R, but not 7134, infection, indicating that DNA-PKcs is a target of ICP0 in HFFs (Fig. S2A). Depletion of DNA-PKcs had no effect on the replication of 7134 and 7134R (Fig. S2B), indicating that DNA-PKcs did not regulate replication in primary fibroblasts. This was surprising, as a previous study observed that human gliomal cells deficient in DNA-PK function supported higher levels of viral replication than a control cell line (54). Additionally, we observed previously that murine cells lacking Ku70, a protein necessary for DNA-PKcs localization, also exhibited enhanced replication of the virus (34). Our results may argue that the different subunits of the DNA-PK complex may have different roles in the HSV-1 life cycle in different cell types, the extent of which remains to be determined.

To investigate the effects of Mre11 and H2AX loss on replication, we infected our knockout HFFs with WT, 7134R, and 7134 viruses and quantified progeny virus by plaque assay. Surprisingly, loss of Mre11 significantly enhanced replication of 7134 and did not affect 7134R or KOS (Fig. 4B), arguing that Mre11 restricted HSV-1 replication in the absence of ICP0. Mre11 has been reported to be lost over the course of infection in a manner independent of ICP0 (37). We observed a slight reduction in Mre11 levels at later times during 7134 but not 7134R infection (Fig. 3C), indicating that ICP0 may target some other protein in the restriction pathway of which Mre11 is a component. Loss of H2AX had no effect on replication of the three viruses (Fig. 4B), consistent with a previous report (36).

In the absence of ICP0, the downstream DDR protein 53BP1 localizes to incoming viral genomes (33). However, it is unknown whether this has any role in the regulation of viral replication. To test this, we depleted 53BP1 in primary HFFs using siRNAs and measured the replication of 7134 and 7134R by plaque assay. Despite successful knockdown, replication of both viruses was not affected (Fig. 4C), arguing that 53BP1 was dispensable for replication. Recruitment of 53BP1 to viral genomes is dependent on H2AX (33). Our results thus far have argued that this H2AX arm of the ATM pathway did not impact the replication cycle of HSV-1 and the actions of ATM were through some other mechanism. Our observations also revealed a novel function of Mre11 in primary fibroblasts for restriction of replication of an ICP0⁻ virus. Furthermore, these contrasting phenotypes between ATM and Mre11 suggested that while Mre11 promoted the partial activation of ATM, these proteins had separate functions in regulating the replication of the virus outside their roles in propagating the DDR.

p53 promotes the replication of ICP0-null HSV-1.ATM is required for p53 phosphorylation on serines 15 and 20 (55), and our observations were consistent with that study. Despite its being known to promote replication, it is unknown precisely where p53 acts in the viral replication cycle. To determine whether p53 regulates replication in primary HFFs, we knocked it down with siRNA and measured the replication of 7134 and 7134R. Knockdown of p53 reduced replication of 7134 by roughly 10-fold (Fig. 5A), but 7134R replication was unaffected. These findings indicated that p53 promoted replication of an ICP0-null virus in primary fibroblasts. Next, using CRISPR-Cas9, we generated a gene knockout of TP53 in HFFs (Fig. 5B). In agreement with our siRNA results, knockout of TP53 significantly reduced the replication of 7134 but not 7134R. Furthermore, WT virus was also unaffected by the knockout (Fig. 5C). Together, our results argued that p53 is proviral, but its absence can be compensated for by ICP0. In contrast, we observed that an increased abundance of p53 did not enhance replication. We treated HFFs with increasing concentrations of nutlin-3a to increase the levels of p53 (56), and despite heightened levels of p53 (Fig. S3A), replication of all three viruses was not affected (Fig. S3B). This indicated that only a loss, and not an overabundance, of p53 has an effect on replication, indicating that p53 was required but not limiting for HSV-1 infection.

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FIG 5

p53 positively regulates the replication of ICP0-null HSV-1. Primary HFFs were transfected with a nontargeting siRNA pool or a pool targeting TP53 and infected with 7134 and 7134R 3 days later at an MOI of 0.1 for 48 h, and total virus was quantified on U2OS cells via plaque assay. Protein lysates were also collected at the time of infection to verify the knockdown (A). Primary HFFs were transduced with lentiviruses expressing Cas9 only or Cas9 along with a guide RNA against TP53. The extent of the knockout was verified via immunoblotting after roughly 2 weeks of puromycin selection (B). Blots are representative of three passages of cells. Normal HFFs, Cas9 control, and TP53 5 cells were infected with 7134, 7134R, and WT viruses at an MOI of 0.1 for 48 h, and total virus was quantified via plaque assay on U2OS cells (C). Graphed data are the averages of three independent experiments (A and C). Statistical significance was determined, compared to the Cas9 control cell line, using unpaired t tests. *, P < 0.05; ns, not significant. Errors bars represent the SEM.

p53 promotes the transcription of an essential viral gene encoding a DNA replication protein.Having demonstrated that p53 promoted progeny virus production, we next sought to determine at which step in the virus replication cycle p53 acted. First, we measured viral DNA replication. Knockout of TP53 significantly reduced DNA replication of 7134 (Fig. 6A), while DNA replication of 7134R and WT viruses was marginally affected (Fig. S4A and C, respectively). This indicated that at least part of the defect in progeny virus production in 7134 virus-infected cells was due to reduced replication of the genome. However, before the initiation of DNA replication, HSV-1 must first express the IE genes, which are required to initiate transcription of the E genes, encoding the DNA replication machinery. Therefore, the reduction in viral DNA replication could have been due to a defect in either IE or E gene expression. To determine which gene set was regulated by p53, we treated 7134 virus-infected cells with acyclovir (diagrammed in Fig. 6B). We chose representative genes of each class: ICP4 and ICP27 for the IE class, ICP8 (an essential DNA replication gene) for the E class, and the glycoprotein gene gC for the L class. Using acyclovir allowed us to differentiate pre-DNA replication from post-DNA replication gene expression. Without ACV treatment, mRNA levels of the ICP4, ICP27, ICP8, and gC genes were reduced significantly in the knockout cells compared to the control line following infection with 7134 (Fig. 6C). This most likely reflected the transcriptional levels of viral mRNA both before and after DNA replication. However, with acyclovir treatment, we observed a significant reduction in ICP8 gene transcript levels but not ICP4 and ICP27 transcripts, arguing that p53 promoted ICP8, but not IE, gene transcription, which then led to decreased DNA replication and progeny virus production. In line with our DNA replication results, viral gene transcript levels were comparable between the control and knockout lines with and without acyclovir treatment for 7134R and WT viruses (Fig. S4B and D, respectively). Together, our results indicated that p53 played a pivotal role in promoting the transcription of at least one essential viral DNA replication protein gene, that encoding ICP8.

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FIG 6

p53 promotes prereplication ICP8, but not ICP4 or ICP27, gene transcription. Cas9 and TP53 #5 cells were infected with 7134 at an MOI of 1, and nucleic acids were collected 24 h later. Purified DNA was amplified and quantified via real-time PCR with primer pairs for the UL29 locus of the viral genome and cellular GAPDH. The values for UL29 were normalized to the GAPDH values (A). cDNAs of viral genes representative of each viral gene class were quantified. ICP4 and ICP27 represented the IE class, ICP8 the E class, and gC the L class. Cells were treated with ACV to allow the quantification of IE and E transcripts before the onset of viral DNA replication (B). Total RNA from the same samples collected for panel A was isolated and reverse transcribed, and the indicated viral transcripts were quantified via real-time PCR and normalized to cellular 18S rRNA transcripts (C). Data are averages with SEM from three independent experiments (A and C). Statistical significance was determined, compared to the Cas9 control cells, via unpaired t tests. *, P < 0.05; **, P < 0.01; ***, P < 0.001; ****, P < 0.0001; ns, not significant.

IFI16 is a cellular protein known to restrict ICP0-null HSV-1 replication (57). Additionally, IFI16 has been shown to bind to p53 (58, 59) and reported to negatively regulate its function (60), although the latter is still a point of contention (58, 59, 61). To determine whether IFI16 had any role with respect to p53, we knocked down p53 in IFI16 knockout HFFs and measured 7134 yields. Knockdown of p53 resulted in elevated IFI16 protein levels in the Cas9 control cells (Fig. S5A), indicating that p53 negatively regulated the expression of IFI16. Depletion of p53 in both Cas9 control and IFI16 1 cells dramatically reduced 7134 replication compared to nontargeting treatment (Fig. S5B), arguing that IFI16 was not required for p53 function during infection.