Serial Passage through Human Glioma Xenografts Selects for a {Delta}{gamma}134.5 Herpes Simplex Virus Type 1 Mutant That Exhibits Decreased Neurotoxicity and Prolongs Survival of Mice with Experimental Brain Tumors

Previous studies have described in vitro serial passage of a ${Delta}$ ${gamma}$ ₁34.5 herpes simplex virus type 1 (HSV-1) strain in SK-N-SHneuroblastoma cells and selection of mutants that have acquiredthe ability to infect and replicate in this previously nonpermissivecell line. Here we describe the selection of a mutant HSV-1strain by in vivo serial passage, which prolongs survival intwo separate experimental murine brain tumor models. Two conditionallyreplication-competent ${Delta}$ ${gamma}$ ₁34.5 viruses, M002, which expresses murineinterleukin-12, and its parent virus, R3659, were serially passagedwithin human malignant glioma D54-MG cell lines in vitro orflank tumor xenografts in vivo. The major findings are (i) virusespassaged in vivo demonstrate decreased neurovirulence, whereasthose passaged in vitro demonstrate a partial recovery of theneurovirulence associated with HSV-1; and (ii) vvD54-M002, thevirus selected after in vivo serial passage of M002 in D54-MGtumors, improves survival in two independent murine brain tumormodels compared to the parent (unpassaged) M002. Additionally,in vitro-passaged, but not in vivo-passaged, M002 displayedchanges in the protein synthesis profile in previously nonpermissivecell lines, as well as early U_S11 transcription. Thus, a mutantHSV-1 strain expressing a foreign gene can be selected for enhancedantitumor efficacy via in vivo serial passage within flank D54-MGtumor xenografts. The enhanced antitumor efficacy of vvD54-M002is not due to restoration of protein synthesis or early U_S11expression. This finding emphasizes the contribution of thein vivo tumor environment for selecting novel oncolytic HSVspecifically adapted for tumor cell destruction in vivo.

INTRODUCTION

Top

Introduction

Oncolytic viruses have provided much promise as a novel treatmentmodality for brain tumors such as glioblastoma multiforme, themost frequently occurring primary brain tumor and one that isextremely recalcitrant to traditional therapies. Manipulationof the herpes simplex virus type 1 (HSV-1) genome has providedseveral agents demonstrating the ability to specifically targetand destroy tumor cells and spread their progeny to new tumorcell targets (24). The thymidine kinase (tk) dlsptk deletionmutant afforded an attenuated neurovirulence and promising efficacyprofile, but was not advanced to clinical trials because oftoxicity displayed at high titers and resistance to antiherpeticagents from its tk-negative status (16). A disabling lacZ insertionin the U_L39 locus, encoding the ribonucleotide reductase largesubunit, limited the hrR3 mutant HSV-1 to dividing cells, suchas malignant glioma tumor cells, which could provide cellularribonucleotide reductase in trans (9, 10, 17). Mapping of theneurovirulence phenotype of HSV-1 to the diploid ${gamma}$ ₁34.5 geneprovided a valuable tool in the production of antitumor HSV-1vectors; HSV-1 mutants with ${gamma}$ ₁34.5 deleted were avirulent inthe normal brain milieu but able to proliferate after infectionof actively cycling cells (7). HSV-1 strains with ${gamma}$ ₁34.5 deletedinclude G207 (double mutant possessing deletions of both ${gamma}$ ₁34.5genes and a lacZ insertion disrupting the U_L39 locus) (18) andHSV1716 ( ${gamma}$ ₁34.5-negative only) (26). These vectors kill tumorcells directly but are incapable of significant replicationin postmitotic cells such as neurons. Clinical studies haveproven the safety of these vectors for direct administrationin the brain (15, 22).

Whereas these viruses were engineered by design to possess particularmutations conferring beneficial phenotypes for use as antitumoragents, recent studies have described acquisition of mutationsthat overcome certain limitations of the ${gamma}$ ₁34.5-negative statusof attenuated HSV-1 via in vitro serial passage. Mohr and Gluzmanreported selection of the SUP-1 mutant after passage of ${Delta}$ ${gamma}$ ₁34.5SPBg5e (derived from the Patton HSV-1 strain) in the nonpermissiveSK-N-SH human neuroblastoma cell line in vitro (19). SUP-1 acquireda deletion in the U_S10-U_S12 region, resulting in earlier expressionof the U_S11 gene. This shift in U_S11 expression kinetics precludedphosphorylation of eukaryotic initiation factor-2 ${alpha}$ (eIF-2 ${alpha}$ ) topermit continued viral protein translation in infected SK-N-SHcells. SUP-1 thus exhibited a protein synthesis phenotype similarto that of ${gamma}$ ₁34.5-positive HSV-1 (5, 6, 11), but retained theneurovirulence profile of its ${Delta}$ ${gamma}$ ₁34.5 parent (20). Similarly, ${Delta}$ ${gamma}$ ₁34.5 R3616, derived from the parent HSV-1 (F) strain, was sequentiallypassaged in SK-N-SH cells and distinct variants were isolatedthat were also capable, like SUP-1, of blocking the proteinkinase R (PKR)-induced shutoff of protein synthesis (4). Thesemutations mapped outside of the U_S10-12 domain, and at leastone isolate had acquired a partially restored neurovirulenceprofile, though its 50% lethal dose (LD₅₀) was still over 3-log-foldhigher than that of the wild type. These studies demonstratethat though ${Delta}$ ${gamma}$ ₁34.5 viruses display a safe neurovirulence profileand valuable antitumor properties, their effectiveness as replication-competentoncolytic viruses is limited in certain human tumor cells, andin vitro serial passage can provide a means to acquire mutationsfacilitating their ability to kill tumor cells.

We extended this approach to select HSV mutants specificallycapable of enhanced antitumor activity, particularly againstmalignant gliomas. The recombinant ${Delta}$ ${gamma}$ ₁34.5 HSV strain M002 carriestwo copies of the murine interleukin-12 (IL-12) gene in the ${gamma}$ ₁34.5 loci and has demonstrated significant antitumor activityin both murine neuroblastoma and glioma brain tumor models (12,21). M002 and R3659, the parent virus to M002, were each sequentiallypassaged in the human malignant glioma cell line D54-MG, whichis more resistant to HSV infection than other malignant gliomacell lines (2). We compared serial passage, performed both invitro in tissue culture and in vivo in flank tumor xenografts,of M002 to that of R3659 since expression of the immunomodulatorycytokine IL-12 could potentially alter the nature and functionof the mutations acquired. We hypothesized passage in an invivo setting would provide selective pressures far differentfrom those encountered in vitro. We found passage of R3659 andM002 in vitro in tissue culture monolayers selected mutantsexhibiting slight to moderate neurotoxicity, as compared tothe parent viruses, but the viruses were still significantlyless neurotoxic than the wild-type HSV-1 (F). Additionally,U_S11 expression from in vitro-passaged M002 shifted from latein infection to much earlier in the replicative cycle. The invitro-passaged M002 exhibited a restored protein synthesis phenotypein SK-N-SH and D54-MG cells. These changes did not, however,translate to an improvement in survival of brain tumor-bearinganimals in the models tested relative to the parent nonpassagedviruses, which display late U_S11 expression and shutdown ofprotein synthesis following SK-N-SH infection. In contrast,the in vivo-passaged M002, which demonstrated decreased neurovirulencecompared to the M002 parent after selection in D54 flank tumors,significantly improved survival of tumor-bearing mice in twoseparate murine experimental brain tumor models: human D54-MGintracranial xenografts in SCID mice and murine Neuro-2a neuroblastomasyngeneic tumors in A/J mice. Thus, these studies emphasizethe importance of the in vivo tumor environment for selectingnovel oncolytic HSV strains that mediate improved survival invivo.

MATERIALS AND METHODS

Top

Materials and Methods

Cell lines and viruses. Vero, Neuro-2a murine neuroblastoma (derived from A/J mice),U87 human malignant glioma, and SK-N-SH human neuroblastomacells were obtained from the American Type Culture Collection(Manassas, VA). Human D54-MG cells were obtained from D. Bigner(Duke University, Durham, NC), and 4C8 murine glioma cells wereobtained from C. Dyer (E. K. Shriver, New York, NY). Cells werepropagated in antibiotic-free modified Eagle's medium (Vero)or Dulbecco's modified Eagle's medium (DMEM)-F12 in a 50:50mix (as were all other cell lines) supplemented with 7% fetalbovine serum (HyClone, Logan, UT) and 2.6 mM L-glutamine (LifeTechnologies, Carlsbad, CA). R5104 (6) and the parent recombinantviruses R3659 (14) and M002 (21) have been described elsewhere.HSV-1 (F), the prototypical wild-type virus used for these studies(8), and R3659 were generous gifts from Bernard Roizman (Universityof Chicago, Chicago, IL).

In vitro and in vivo serial passage of ${Delta}$ ${gamma}$ ₁34.5 HSV. In vitro-passaged viruses were selected by infecting D54-MGtissue culture monolayers (80 to 90% confluence) with 100 PFUof the parent viruses. Three to 4 days postinfection, when cellsreached approximately 100% cytopathic effect, cells and supernatantwere harvested and the titer of virus recovered was determined.One hundred PFU of the recovered virus was used to infect anew D54-MG culture. Nine such rounds of serial passage wereperformed on both R3659 and M002.

For in vivo serial passage, flank tumor xenografts were establishedin SCID mice by injecting 5 x 10⁶ D54-MG cells via 200 µl5% methylcellulose. Three tumors at least 100 mm³ were injectedwith 100 PFU of either parent virus for the first passage. Fourdays postinoculation, tumors were harvested and pooled and thenhomogenized into a mixture of sterile milk and DMEM-F12 medium(50:50) and the viral titer was determined on Vero cells. Forsubsequent passages, 100 µl of tumor homogenate from theprevious passage was used for inoculation into new flank tumorsfor harvest as before. Viruses were monitored during passagefor differences in both replication and IL-12 production (forM002-based viruses) in vitro. We noted initial changes in phenotypesfairly early (passages 4 to 6). Due to the probable complexityof selective pressures from the environmental factors associatedwith a flank tumor, we carried out two extra passages (11 total).Passage was continued for both mutants to ensure stability ofselected mutations and that we were working with a sufficientlypure population of viruses.

After passage, high-titer HSV virus stocks were obtained andpurified on OptiPrep gradients (AXIS-SHIELD PoC AS, Oslo, Norway).Briefly, Vero cells were infected at low multiplicity of infection(MOI; 0.01). When $~$ 100% CPE was reached, both culture supernatantsand cells were collected and harvested separately. Culture supernatantswere subjected to three centrifugation steps: step 1, 1,811x g (15 min); step 2, transfer of supernatants to Nalgene tubesand centrifugation at 3,568 x g (5 min, JA14 rotor); and step3, transfer of the final supernatants to Beckman Ultracleartubes and centrifugation at 53,000 x g (1 h, SW28 rotor). Viralpellets were resuspended in 1x phosphate-buffered saline (PBS)containing 10% glycerol. Cells were scraped, lysed in 0.4 MNaCl, and subjected to multiple centrifugations as describedabove prior to PBS-10% glycerol suspension. Virus pellets werepurified on OptiPrep gradients as follows. Equal volumes ofOptiPrep were added to NaCl-extracted or culture supernatantvirus pellets, mixed, and transferred to Quickseal polyallomertubes. Tubes were filled with 25% OptiPrep and centrifuged for3 h at 354,000 x g in an NVT90 rotor. After centrifugation,virus fractions were collected, diluted in PBS, and centrifuged.Virus pellets from supernatants and cell lysates were combined,and the titer was determined on Vero cells as described previously(1).

Replication assays. Viral replication was assessed in vitro as previously described(1). Studies were repeated at least three times, and resultswere analyzed by fitting a general linear model (analysis ofvariance) across groups and time points.

IL-12 ELISA. Cells were seeded in 24-well plates and mock-infected or infectedwith a low MOI (0.1) of virus as described above. Supernatantsfrom replicate wells (two to four wells) were harvested at multipletime points and tested for murine IL-12 (p70 heterodimer ofp40 and p35 IL-12 subunits) using a commercially available enzyme-linkedimmunosorbent assay (ELISA) kit (Quantikine; R&D Systems,Minneapolis, MN). Statistical analysis was performed by t testacross groups for each time point.

In vitro protein synthesis profiles. Replicate cultures of D54-MG or SK-N-SH cells were mock infectedor infected with a virus at a high MOI (40 to 50). Twelve hourspostinfection (hpi), cultures were incubated in methionine-freeDMEM (199V) supplemented for 1 h with 50 µCi ³⁵S-labeledL-methionine (Amersham Bioscience, Piscataway, NJ). Cells wereharvested, solubilized, run through a denaturing 15% (vol/vol)polyacrylamide gel cross-linked with N, N'-diallyltartardiamideto electrophoretically separate bands, and analyzed by autoradiographyafter transfer to nitrocellulose membranes.

U_S11 expression studies. Vero monolayers in 12-well plates were infected at a high MOI(MOI of 50) and incubated with 300 µg/ml phosphonoaceticacid (PAA). U_S11 expression was examined at both 12 and 24 hpi.Culture medium was removed, and cells were lysed in disruptionbuffer (8 ml 20% sodium dodecyl sulfate, 4 ml ß-mercaptoethanol,4 ml 55% sucrose, 4 ml 1 M Tris HCl, pH 7.0, bromophenol blue).Cell lysates were transferred to microcentrifuge tubes, boiled,and loaded in a denaturing 12% (vol/vol) polyacrylamide gelto electrophoretically separate bands. Bands were transferredto nitrocellulose membranes and incubated in Tris-buffered saline-Tween20 with a U_S11-specific mouse monoclonal antibody (*28S; a giftfrom B. Roizman, University of Chicago) overnight at 4°C.Membrane was washed and incubated with alkaline phosphatase-conjugatedgoat anti-mouse secondary antibody (1:3,000) (catalog no.170-6520;Bio-Rad Laboratories, Hercules, CA) for 1 h. U_S11 bands werevisualized with 200 µl nitroblue tetrazolium (NBT; ICNBiomedical, Pasadena, CA) plus 200 µl 5-bromo-4-chloro-3-indolylphosphate(BCIP; Sigma, St. Louis, MO) in 20 ml alkaline phosphatase buffer.

Animal studies. All mouse strains (CBA/J, SCID, and A/J) were obtained fromthe Frederick Cancer Research and Development Center, NationalCancer Institute. All animal studies were conducted in accordancewith guidelines for animal use and care established by the Universityof Alabama at Birmingham Animal Resource Program and the InstitutionalAnimal Care and Use Committee (protocol no. 050607062).

(i) Survival studies. Mice were injected intracerebrally with cells (via 5 µlof 5% methylcellulose) by drilling a small hole 2 mm anteriorand 2 mm lateral to the bregma. A 30-gauge needle was insertedto a depth of 2.5 mm using a Kopf stereotaxic frame to implantcells in the caudate nucleus. SCID mice were injected with 1x 10⁶ D54-MG cells and inoculated stereotactically with virus7 days later using the same coordinates. A/J mice were injectedwith 2 x 10⁴ Neuro-2a cells intracranially and treated after5 days. Virus treatments were administered (via 10 µlPBS) through the same burr hole. Incisions were closed withTissueMend II (Veterinary Product Laboratories, Phoenix, AZ),and all mice were maintained on a Tylenol-water mixture 2 daysprior to and after surgery. Kaplan-Meier statistical analysiswas used to determine any differences between survival curvesof various cohorts.

(ii) Neurotoxicity studies. The highly HSV-sensitive CBA/J mice (4 weeks old, female) wereinjected intracerebrally with graded doses of viruses in cohortsof 10 mice as described above, and deaths occurring within 30days were recorded. HSV-1 (F) was injected for comparison. LD₅₀was determined by Spearman-Karber analysis.

RESULTS

Top

Results

Selection of novel ${Delta}$ ${gamma}$ ₁34.5 HSV by in vivo and in vitro serial passage. Parent recombinant viruses R3659 and M002 are strains with ${gamma}$ ₁34.5deleted but capable of replication in human glioma cells. Eachvirus was injected intratumorally into D54-MG flank tumor xenograftsin SCID mice to generate in vivo-passaged viruses as describedabove (Fig. 1A). A total of 11 passage cycles were performedfor both R3659 and M002 in D54-MG tumors. In parallel, in vitro-passagedR3659 and M002 viruses were selected by sequential passage inD54-MG cells in tissue culture, as described above (Fig. 1B).Throughout the subsequent text, passaged viruses are referredto as follows: vtD54-R3659 and vtD54-M002 refer to parent virusesselected in D54-MG glioma cells in culture (within an in vitroenvironment). Viruses vvD54-R3659 and vvD54-M002 refer to thosepassaged in D54-MG flank tumor xenografts (within an in vivoenvironment). Viruses recovered from final passages were grownto high titers, purified, and used for characterization studies.

View larger version (24K):
[in this window]
[in a new window]
FIG. 1. Schematic of selection of novel ${Delta}$ ${gamma}$ ₁34.5 HSV-1 by serial passage. (A) Selection by in vivo serial passage. (B) Selection by in vitro serial passage.

Replication of vtD54-M002 is 1 to 3 logs higher than that of the parent, nonpassaged M002, but replication of vvD54-M002 is no different from that of M002. To determine whether mutants with differences in viral replicationwere selected and whether these mutations were cell line specificor generalized across different cell types, both multi- andsingle-step replication assays were performed. Multistep replicationassays after D54-MG infection in vitro at low MOI with vvD54-M002showed only slightly higher replication than M002 (P > 0.05)(Fig. 2A). A similar trend was observed after infection of adifferent human glioma cell line, U87-MG, but no change wasseen in Neuro-2A cells or the highly permissive Vero or 4C8murine glioma cells (not shown). In contrast, vtD54-M002 exhibitedincreased replication (approximately 2 logs higher) after infectionof D54-MG cells compared to M002, though this difference didnot reach statistical significance. The serially passaged R3659viruses showed no difference in replication compared to theunpassaged parent virus in any of these cell lines (not shown).For the single-step replication assay, D54-MG cells were infectedusing a high MOI (20) and samples were harvested at multipletime points to determine viral recovery. Findings were similarto the multistep replication assays in that recovery of vvD54-M002was no different from that of M002, whereas recovery of vtD54-M002was higher and to wild-type levels but did not reach statisticalsignificance (data not shown). Viral recovery was also measuredafter in vivo infection of D54-MG intracranial tumor xenograftsin SCID mice with 1 x 10⁷ PFU of each virus. Brain tumors wereharvested every 2 days and homogenized, and viral titer wasdetermined. At all time points, vtD54-M002 titers recoveredfrom homogenates were 1 to 2 logs higher than M002 titers (Fig.2B), but again did not reach statistical significance. By day12, no titers were recovered from any of the homogenates. Lastly,we determined viral recovery after intratumoral injection of1 x 10⁷ PFU of each virus at various time points (2, 4, 7, 10,14, and 21 days) from both D54-MG and Neuro-2A flank tumors.Recovery of vtD54-M002 was at most 1 log higher than that ofthe other viruses and was not statistically significant (notshown).

View larger version (21K):
[in this window]
[in a new window]
FIG. 2. In vitro and in vivo replication of parent and passaged viruses. (A) D54-MG cells were cultured in 24-well plates in vitro, and replicate wells were infected (MOI = 0.1) with either HSV-1 (F), parent viruses (R3659 or M002), or a serially passaged virus. Samples were harvested 12, 24, 36, 48, and 72 hpi. (B) Replication time course after intratumoral injection of viruses in D54-MG brain tumors established intracranially in SCID mice.

IL-12 production differs from vvD54-M002- versus M002-infected cells. Since M002 was engineered to express murine IL-12, we testedwhether serial passage selected a mutant with altered IL-12gene expression. After infection of D54-MG, U87-MG, 4C8, Neuro-2a,and Vero cells, supernatants were harvested at multiple timepoints to determine levels of murine IL-12 by ELISA, with controlwells infected with R3659. As seen in Fig. 3A, a modest increasein IL-12 production was noted when D54-MG cells were infectedwith vvD54-M002 (late time points; P < 0.05). Conversely,IL-12 production was decreased after vvD54-M002 infection ofNeuro-2a cells relative to M002 (late time points; P < 0.05)(Fig. 3B). However, no increase in recombinant IL-12 expressionwas noted from vvD54-M002-infected tissue culture monolayersof U87-MG, 4C8, or Vero cells (not shown). The vtD54-M002 virusdid not exhibit statistically significant changes in IL-12 expressionrelative to M002 (not shown).

View larger version (25K):
[in this window]
[in a new window]
FIG. 3. Recombinant IL-12 production after M002 and vvD54-M002 infection. IL-12 production after infection with viruses was determined using an ELISA kit (R&D Systems) specific for murine IL-12 p70 heterodimer. Shown are the levels of IL-12 detected after vvD54-M002 or M002 infection of (A) D54-MG cells (72 hpi, P = 0.0124; 84 hpi, P = 0.0093) and (B) Neuro-2a cells (48 hpi, P = 0.0152; 72 hpi, P = 0.0008).

The protein synthesis phenotype is restored by in vitro-passaged (vtD54-M002), but not in vivo-passaged (vvD54-M002) virus following infection of D54-MG and SK-N-SH cells. ${Delta}$ ${gamma}$ ₁34.5 HSV R3659 and M002, unlike HSV-1 (F), are unable to synthesizelate viral proteins after infection of either D54-MG or SK-N-SHcells. To determine if the passaged viruses were able to overcomehost translation shutoff, protein synthesis was assessed. Thein vitro-passaged virus vtD54-M002 demonstrated the capacityto produce viral proteins after infection of the ${Delta}$ ${gamma}$ ₁34.5 nonpermissiveSK-N-SH cell line (Fig. 4A). The same was true for vtD54-M002infection of D54-MG cells (Fig. 4B) and the heterologous humanglioma U87 cells (not shown). In contrast, restoration of theprotein synthesis phenotype was not observed in these cell linesfollowing infection with vvD54-M002 (Fig. 4A and B) or within vitro- or in vivo-passaged R3659 viruses (not shown). Relativeto HSV (F)-infected cells, vtD54-M002 displays less robust productionof viral proteins, suggesting an acquired mechanism of PKR evasionthat is not as powerful as that seen with ICP34.5 expression,but which is still sufficient to continue viral protein productionin even nonpermissive SK-N-SH cells.

View larger version (38K):
[in this window]
[in a new window]
FIG. 4. Protein synthesis profiles from infected D54-MG human glioma cells and SK-N-SH human neuroblastoma cells. An autoradiographic image of protein production from cells pulse-labeled with ³⁵S-labeled L-methionine 12 hpi (MOI = 50) with either HSV-1 (F), parent viruses (M002 or R3659), or viruses serially passaged in vivo or in vitro in (A) SK-N-SH cells or (B) D54-MG cells.

Serial passage of R3659 and M002 selects mutants with altered neurotoxic potential depending on the environment (in vitro or in vivo) in which passage was performed. To determine differences in neurotoxic potential, each passagedvirus and its respective parent were administered in escalatingdoses by direct intracranial injection into HSV-sensitive CBA/Jmice. Wild-type virus was injected at 50 and 100 PFU into fivemice each as a positive control: HSV-1 (F), LD₅₀ = 75 PFU. Aswith HSV-1 (F) inoculation, deaths consistent with HSV encephalitisafter injection of other viruses generally occurred within 10to 12 days. LD₅₀ values (Spearman-Karber analysis) for the invitro-passaged viruses vtD54-M002 and vtD54-R3659 were calculatedto be approximately 5.1 x 10⁵ PFU and 1.67 x 10⁶ PFU, respectively,which were lower than the LD₅₀ values of the nonpassaged parentviruses (M002 LD₅₀ = 2 x 10⁷ PFU and R3659 LD₅₀ = 1.54 x 10⁷[and see Table 1 ]). Whereas the viruses passaged in D54-MGcells in vitro show lower LD₅₀ values (i.e., more neurotoxicity)than the parent viruses, passage within flank tumor xenograftsselected mutants with higher LD₅₀ values (i.e., less neurotoxicity).At the highest dose tested (3 x 10⁷ PFU), an LD₅₀ value couldnot be calculated for either vvD54-R3659 or vvD54-M002 (Table1). Thus, passage of these viruses in D54-MG flank tumor xenograftsresulted in selection of mutants with a much safer neurovirulenceprofile.

View this table:
[in this window]
[in a new window]
TABLE 1. Determination of neurovirulence of passaged viruses compared to parental viruses R3659 and M002

Kinetics of U_S11 expression from vtD54-M002 is altered. The increase in neurotoxic potential as well as the positiveprotein synthesis phenotype of the in vitro-passaged virus,vtD54-M002, raised the question of whether its phenotype wasdue to changes in U_S11 gene expression, as reported previouslyfor an in vitro-selected ${Delta}$ ${gamma}$ ₁34.5 HSV mutant in SK-N-SH cells (4).U_S11 expression kinetics was examined in vtD54-M002-infectedcells in the presence or absence of phosphonoacetic acid, andlysates were analyzed by Western blotting using the U_S11-specific*28S monoclonal antibody. PAA inhibits HSV DNA synthesis andthe activity of viral DNA polymerase and, thereby, halts viralreplication such that transcription of the ${alpha}$ (immediate-early),ß (early), and ${gamma}$ ₁ (early-late) genes is permitted,but ${gamma}$ ₂ (true late) proteins will not be produced (13). As shownin Fig. 5, at 12 hpi, U_S11 expression kinetics has shifted toan earlier time point with vtD54-M002 infection compared toM002 infection. Recombinant HSV-1 R5104, engineered to expressU_S11 as an early gene, was used as a positive control (6). Sincethe U_S11 gene product is virion associated (23), small amountswere detected from lysates of HSV-1 (F)-, R3659-, and M002-infectedcells. In contrast, kinetics of U_S11 expression appeared unalteredin lysates from vvD54-M002-infected cells (Fig. 5). NeithervtD54-R3659 nor vvD54-R3659 exhibited altered U_S11 expressionkinetics (not shown).

View larger version (20K):
[in this window]
[in a new window]
FIG. 5. Expression kinetics of U_S11 from infected Vero cells. Shown is U_S11 expression 12 hpi from Vero cells in the absence (–) or presence (+) of 300 µg/ml PAA infected. Cells were infected with R5104 (early U_S11 expression), HSV-1 (F), M002, or the in vivo- and in vitro-passaged M002 viruses. The arrow indicates U_S11.

The vvD54-M002 virus improves survival of tumor-bearing animals in two experimental murine brain tumor models. In vivo-passaged viruses were evaluated relative to the nonpassagedparent viruses as treatments for brain tumors in mice. IntracranialD54-MG tumor xenografts in SCID mice were treated with 1 x 10⁷PFU of virus or saline control. The study was repeated twice,and combined results are presented in Fig. 6. Median survivalfor control mice (saline treated) was 28 days and was improvedminimally by treatment with R3659 (32 days; P = 0.0518). Asdemonstrated previously (21), intratumoral administration ofM002 significantly improved survival (median = 41 days) as comparedto saline- or R3659-treated controls (P $≤$ <0.0001 versus saline;P = 0.0020 versus R3659). However, vvD54-M002 dramatically improvedsurvival of mice compared to treatment with M002, with a mediansurvival of 57 days (P = 0.0030). Additionally, there were nolong-term survivors in the M002-treated cohort from either experiment,whereas the vvD54-M002-treated cohort had three apparent cures150 days following tumor implantation, the experiment endpoint.

View larger version (30K):
[in this window]
[in a new window]
FIG. 6. Survival of mice bearing human D54-MG brain tumors after vvD54-M002 treatment. Immunocompromised SCID mice bearing D54-MG brain tumors were treated with either saline (closed circles) as a control or 1 x 10⁷ PFU of either R3659 (closed diamonds), M002 (closed squares), or vvD54-M002 (open squares) after 7 days. The survival graph shows two separate studies combined. Cohorts were compared using Kaplan-Meier statistical analysis.

The other passaged viruses did not demonstrate enhanced antitumor activity in the D54-MG xenograft brain tumor model. Given that vtD54-M002 had regained the wild-type protein synthesisphenotype and increased replication in vitro, we predicted thatthis would translate to improved tumor killing and survivalof tumor-bearing mice. However, when tested at equivalent doses,neither the in vitro-passaged vtD54-M002, nor either in vitro-or in vivo-passaged R3659 viruses (vtD54-R3659 and vvD54-R3659),conferred increased survival to SCID mice bearing intracranialD54-MG tumors relative to the parent viruses (not shown).

The vvD54-M002 virus demonstrated therapeutic efficacy in A/J mice bearing syngeneic Neuro-2a neuroblastoma brain tumors. We next determined whether prolonged survival following vvD54-M002treatment of tumors was applicable to other, nonhuman and nongliomamodels of malignant brain tumors. For these studies, the murineNeuro-2a neuroblastoma cell line was used to establish intracranialtumors in the syngeneic A/J strain mice. Five days after implantation,either R3659, M002, or vvD54-M002 (at equivalent doses to thosegiven above) was directly injected into the tumors. The resultsof two separate experiments were combined, and the data areshown in Fig. 7. In this model, untreated mice succumb muchmore quickly to the implanted tumors, with a median survivalof only 10 days for the saline cohort. Mice treated with vvD54-M002had a median survival of 14 days, which was significantly improvedover treatment with M002 (P = 0.0193). Moreover, the vvD54-M002treatment cohort produced two apparent cures (surviving >155days post-tumor implantation), whereas the M002 cohort had nolong-term survivors.

View larger version (28K):
[in this window]
[in a new window]
FIG. 7. Survival of mice bearing Neuro-2a brain tumors after vvD54-M002 treatment. Immunocompetent A/J mice bearing Neuro-2a brain tumors were treated with either saline (closed circles) as a control or 1 x 10⁷ PFU of either R3659 (closed diamonds), M002 (closed squares), or vvD54-M002 (open squares) after 5 days. The survival graph shows two separate studies combined. Cohorts were compared using Kaplan-Meier statistical analysis.

Treatment of SCID mice bearing D54 human glioma brain tumorswith vvD54-M002 significantly enhanced survival and resultedin a 5% apparent cure rate, with mice showing no signs of tumorburden. There were no long-term survivors after M002 treatment.Importantly, the improvement in survival time was translatableto other nonhuman and nonglioma-derived tumor types. In themurine Neuro-2a neuroblastoma model, 7% of vvD54-M002-treatedmice were long-term survivors. In contrast, all M002-treatedanimals eventually succumbed to their tumors. These resultsconfirm that serial passage of a cytokine-expressing ${Delta}$ ${gamma}$ ₁34.5 HSVstrain, like M002, through xenografted human glioma-derivedtumors selects for mutants that mediate improved survival inmurine brain tumor models.

DISCUSSION

Top

Discussion

The antitumor benefits of ${Delta}$ ${gamma}$ ₁34.5 HSV-1, demonstrated throughnumerous preclinical studies (2, 3, 12, 16), and their favorablesafety profiles, demonstrated in separate clinical trials oftwo different constructs (15, 22), have validated the promiseof oncolytic HSV-1 vectors for the treatment of malignant glioma.The focus of new generation viruses has now shifted towardsaugmenting the intrinsic oncolytic abilities of a ${Delta}$ ${gamma}$ ₁34.5 HSV-1virus, while maintaining its safety profile, to enhance deliveryand expression of therapeutic genes. To this end, we hypothesizedthat serial passage of a virus through human glioma cells, eitherin vitro or in vivo, would select mutants with an enhanced therapeuticprofile. Previous studies have shown in vitro passage can increasethe oncolytic potential of HSV (19). Greater glioma cell tropismhas also been reported for vesicular stomatitis virus afterpassage in vitro (27). Here we report for the first time thatin vivo intratumoral passage can augment the efficacy of anoncolytic virus engineered to express a foreign gene. An unanticipatedresult of these studies is that previously defined mechanisms(restoration of the wild-type protein synthesis phenotype andimproved replication) that have mediated antitumor efficacyin other tumor models did not improve survival of tumor-bearinganimals in the models evaluated here.

To maximize opportunities for selecting mutants and to determinethe potential impact of foreign gene expression on the selectionprocess, both R3659 and M002 were passaged in D54-MG cells invitro and flank tumors in vivo. D54-MG is capable of type Iinterferon secretion and would be expected to exert selectivepressures involving interferon antiviral responses. We hypothesizedpassage of these viruses through in vivo-xenografted human gliomatumors would subject the viruses to intratumoral pressures notencountered in cell culture, including viral spread throughthe three-dimensional tumor stroma and the host's innate immuneresponses to viral infection. Additionally, the in vivo tumormicroenvironment imposes selective pressures related to regionalheterogeneities, including hypoxia, necrosis, angiogenesis,and variable tumor cell mitotic rates. Thus, in vivo passageusing a human tumor type provides the more relevant environmentin which to select tumor-adapted mutants. Finally, to avoidselection of mutants adapted to replication in normal brain,we passaged the viruses in flank xenografts.

Selectivity for neoplastic cells alone and minimal toxicityto the adjacent normal brain are of paramount importance foroncolytic HSV therapy of malignant glioma. In vitro passagerestored some of the neurotoxic potential initially eliminatedwith deletion of the ${gamma}$ ₁34.5 genes, but to levels still well belowthat of HSV-1 (F). Similarly, Cassady et al. found at leastone of the in vitro SK-N-SH-passaged ${Delta}$ ${gamma}$ ₁34.5 R3616 variants hadpartially reacquired neurovirulence, but was still significantlyreduced compared to HSV-1 (F) (4). The increased neurotoxicityof vtD54-M002 suggests it is able to replicate in normal brain,although not to the same level of efficiency as HSV-1 (F). Thisphenotype may account in part for the greater viral recoveryfrom SCID mice bearing D54-MG tumors. Interestingly, we foundthat vvD54-R3659 and vvD54-M002 were less neurovirulent thanM002; indeed, an LD₅₀ was not achieved at the highest dose testedfor both in vivo-passaged viruses. The benefit of this differenceis twofold: increased safety at a particular dose and the abilityto administer higher doses if required to attain maximum tumorcell killing without increasing the risk of HSV-induced encephalitis.

A potential concern was that the in vivo-passaged variant withan attenuated neurovirulence profile may show a correspondingloss of efficient tumor killing. Conversely, an increase inefficacy may be seen at the expense of safety with the in vitro-passagedviruses. In contrast, treatment with the safer vvD54-M002 virusdemonstrated a greater improvement in survival. Importantly,we have demonstrated that a lack of (i) restoration of viralprotein synthesis, (ii) early U_S11 expression, and (iii) significantimprovement in replicative abilities in vitro and in vivo didnot preclude the ability of vvD54-M002 from improving survivalof brain tumor-bearing mice. Moreover, though we note both earlyU_S11 expression and slightly greater viral recovery of vtD54-M002from infected cells in vitro—similar to wild-type HSV-1(F) replication levels—and brain tumors in vivo, thisdid not translate to greater antiglioma effects. Previous studiesshow a shift in U_S11 expression from late in infection (undercontrol of its native ${gamma}$ 2 promoter) to much earlier (under controlof the immediate-early ${alpha}$ 47 promoter), permitting it to precludePKR activation and eIF-2 ${alpha}$ phosphorylation, resulting in continuedviral protein synthesis in U373-MG cells (5, 11, 19). Late viralprotein synthesis after infection of prostate carcinoma PC3cells and subsequent efficacy in treatment of the PC3 murinemodel of prostate carcinoma are attributed to the new kineticsof U_S11 expression (25). However, our results are not necessarilyat odds with these data; improvement of SUP-1 tumor killingin vivo is demonstrated in PC3 tumors, whereas we have demonstratedimproved survival rates with vvD54-M002 in two brain tumor models,a human malignant glioma and a murine neuroblastoma. Just aswe have seen the selective pressures between in vitro and invivo serial passage differ, the properties considered beneficialof ${Delta}$ ${gamma}$ ₁34.5 mutant HSV-1 oncolytic vectors may differ between brainand prostate tumors. Indeed, since early U_S11 expression anda resultant ability to produce late viral proteins may in partaccount for the increased neurotoxicity of vtD54-M002, testingthese viruses in tumors outside the central nervous system mayshow benefit since the risk of HSV-induced encephalitis wouldbe greatly reduced. Conversely, it is unclear whether SUP-1demonstrated greater antiglioma activity, since the virus wastested in a human glioma cell line in vitro but not in an invivo model of human glioma.

While the modest increases in vvD54-M002 replication in D54-MGcells as compared to the parent M002 may be responsible forthe slightly increased IL-12 production observed in these cells,there are at least two other possibilities. First, these differencesmay be due to a global change in viral protein production fromthe serially passaged virus. This is unlikely in that proteinsynthesis profiles were not different between the parent M002and vvD54-M002 viruses. A more likely explanation is that mutationswere selected which affected foreign gene expression, specifically,expression of the murine IL-12 gene. Such mutants would includethose with mutations in the promoter or enhancer regions thatdirectly affected mRNA synthesis or those which affected mRNAor protein stability. By passage in human D54-MG tumors, whichare somewhat resistant to HSV infection, more optimal foreigngene expression may have been achieved. The relative IL-12 levelsfrom vvD54-M002- versus M002-infected cells depended on thecell lines infected (human D54-MG versus murine Neuro-2A). Itis difficult to predict how the changes seen in vitro mightaffect the antitumor activity of the viruses within the in vivoenvironment; a tumor treated with these oncolytic viruses wouldbe expected to have a complex set of interactions between infectiousvirions, actively growing, infected and lysed tumor cells, ongoingangiogenesis, recruited immune cells, and the host cellularresponses to all these factors. Studies are in progress to examinepromoter regions for mutations, which may be cell line specific,that account for enhanced IL-12 expression in D54-MG cells butreduced expression in Neuro-2a cells and their significanceto the antitumor benefits demonstrated in vivo. Since in vivopassage of M002, but not R3659, selected a mutant demonstratinggreater improvements in survival, it is unlikely mutations insurface glycoproteins improving viral entry account for thechange, and this makes involvement of the foreign IL-12 geneinsert important to delineate. Studies are under way to assesschanges in viral spread or secondary effects of virus-host interaction,such as innate immune responses and angiogenesis induction,which may account for the change in phenotype.

Finally, the fact that a more effective mutant was selectedfrom our virus encoding IL-12, and not in a virus expressingonly native viral proteins, suggests in vivo passage may beparticularly relevant for oncolytic viruses engineered to expressforeign genes. While viruses have evolved towards optimal efficiencyover the course of their existence, subtle changes in viralgenotype may improve the efficacy of oncolytic viruses expressingforeign gene products, contributing to a new equilibrium betweenthe engineered virus and its replication milieu. In vivo passageallows the virus and its milieu to select these changes andcould represent a new paradigm for development of optimizedoncolytic vectors expressing foreign proteins prior to use inclinical trials. Studies are under way to elucidate the mutation(s)responsible for the acquired phenotype of vvD54-M002, whichwill be vital for construction of future generations of therapeuticHSVs.

ACKNOWLEDGMENTS

We thank Bernard Roizman, University of Chicago, for helpfuldiscussions throughout the course of this work and for providingviruses and the U_S11 antibody. We thank Huey Nguyen and JenniferColeman for excellent technical assistance.

These studies were initiated and supported by NCI P01 CA 71933(R.J.W., J.N.P., G.Y.G., and J.M.M.), the Brain Tumor Society'sNeal P. Levitan Leadership Chair of Research Award (J.N.P.),and the Ruth L. Kirschstein NRSA Fellowship 1 F31 NS050924-01(A.C.S.). We acknowledge the Medical Scientist Training Programand Department of Physiology and Biophysics, University of Alabama,for their support of A.C.S.

FOOTNOTES

* Corresponding author. Mailing address: University of Alabama at Birmingham, Division of Neurosurgery, FOT 1050, 510 20th Street South, Birmingham, AL 35294-3410. Phone: (205) 975-6985. Fax: (205) 975-3203. E-mail: jmarkert{at}uabmc.edu.

REFERENCES

Top