Release Of Adenovirus Research Articles

A Small Volume Procedure for Viral Concentration from Water

Small-scale concentration of viruses (sample volumes 1-10 L, here simulated with spiked 100 ml water samples) is an efficient, cost-effective way to identify optimal parameters for virus concentration. Viruses can be concentrated from water using filtration (electropositive, electronegative, glass wool or size exclusion), followed by secondary concentration with beef extract to release viruses from filter surfaces, and finally tertiary concentration resulting in a 5-30 ml volume virus concentrate. In order to identify optimal concentration procedures, two different electropositive filters were evaluated (a glass/cellulose filter [1MDS] and a nano-alumina/glass filter [NanoCeram]), as well as different secondary concentration techniques; the celite technique where three different celite particle sizes were evaluated (fine, medium and large) followed by comparing this technique with that of the established organic flocculation method. Various elution additives were also evaluated for their ability to enhance the release of adenovirus (AdV) particles from filter surfaces. Fine particle celite recovered similar levels of AdV40 and 41 to that of the established organic flocculation method when viral spikes were added during secondary concentration. The glass/cellulose filter recovered higher levels of both, AdV40 and 41, compared to that of a nano-alumina/glass fiber filter. Although not statistically significant, the addition of 0.1% sodium polyphosphate amended beef extract eluant recovered 10% more AdV particles compared to unamended beef extract.

A Small Volume Procedure for Viral Concentration from Water

Small-scale concentration of viruses (sample volumes 1-10 L, here simulated with spiked 100 ml water samples) is an efficient, cost-effective way to identify optimal parameters for virus concentration. Viruses can be concentrated from water using filtration (electropositive, electronegative, glass wool or size exclusion), followed by secondary concentration with beef extract to release viruses from filter surfaces, and finally tertiary concentration resulting in a 5-30 ml volume virus concentrate. In order to identify optimal concentration procedures, two different electropositive filters were evaluated (a glass/cellulose filter [1MDS] and a nano-alumina/glass filter [NanoCeram]), as well as different secondary concentration techniques; the celite technique where three different celite particle sizes were evaluated (fine, medium and large) followed by comparing this technique with that of the established organic flocculation method. Various elution additives were also evaluated for their ability to enhance the release of adenovirus (AdV) particles from filter surfaces. Fine particle celite recovered similar levels of AdV40 and 41 to that of the established organic flocculation method when viral spikes were added during secondary concentration. The glass/cellulose filter recovered higher levels of both, AdV40 and 41, compared to that of a nano-alumina/glass fiber filter. Although not statistically significant, the addition of 0.1% sodium polyphosphate amended beef extract eluant recovered 10% more AdV particles compared to unamended beef extract.

Adenovirus Release from the Infected Cell as a Key Factor for Adenovirus Oncolysis

Adenovirus release is not triggered until late times after viral infection, when the adenovirus death protein (ADP) accumulates to induce viral egress. Thus, the natural rate of adenovirus release may hinder the spread of oncolytic adenoviruses. Several experimental approaches have provided evidence indicating that promoting adenovirus release can be used to enhance their therapeutic potential. This review briefly summarizes what is known about the mechanism of adenovirus release and describes three different strategies, ADP overexpression, apoptosis induction, and bioselection, which can be used to enhance adenovirus release. Finally we will discuss some of the future perspectives that will contribute to the better use of progeny release for the improvement of the antitumor activity of oncolytic adenoviruses.

Adenovirus Release from the Infected Cell as a Key Factor for Adenovirus Oncolysis~!2009-10-09~!2010-02-25~!2010-05-26~!

Adenovirus Release from the Infected Cell as a Key Factor for Adenovirus Oncolysis~!2009-10-09~!2010-02-25~!2010-05-26~!

Verapamil Enhances the Antitumoral Efficacy of Oncolytic Adenoviruses

The therapeutic potential of oncolytic adenoviruses is limited by the rate of adenovirus release. Based on the observation that several viruses induce cell death and progeny release by disrupting intracellular calcium homeostasis, we hypothesized that the alteration in intracellular calcium concentration induced by verapamil could improve the rate of virus release and spread, eventually enhancing the antitumoral activity of oncolytic adenoviruses. Our results indicate that verapamil substantially enhanced the release of adenovirus from a variety of cell types resulting in an improved cell-to-cell spread and cytotoxicity. Furthermore, the combination of the systemic administration of an oncolytic adenovirus (ICOVIR-5) with verapamil in vivo greatly improved its antitumoral activity in two different tumor xenograft models without affecting the selectivity of this virus. Overall, our findings indicate that verapamil provides a new, safe, and versatile way to improve the antitumoral potency of oncolytic adenoviruses in the clinical setting.

Extended release of adenovirus from silica implants in vitro and in vivo

Despite promising preclinical results, the clinical benefits of cancer gene therapy have been modest heretofore. The main obstacle continues to be the level and persistence of gene delivery to sufficiently large areas of the tumor. One approach for overcoming this might entail extended local virus release. We studied the utility of silica gel monoliths for delivery of adenovirus to advanced orthotopic gastric and pancreatic cancer tumors. Initially, the biochemical properties of the silica-virus matrix were studied and nearly linear release as a function of time was detected. Virus stayed infective for weeks at +37 degrees C and months at +4 degrees C, which may facilitate storage and distribution. In vivo, extended release of functional replication deficient and also replication-competent, capsid-modified oncolytic viruses was seen. Treatment of mice with pancreatic cancer doubled their survival (P<0.001). Also, silica gel-based delivery slowed the development of antiadenovirus antibodies.

686. Extended Release of Adenovirus from Silica Implants In Vitro and In Vivo

686. Extended Release of Adenovirus from Silica Implants In Vitro and In Vivo

Replication-competent Adenovirus-mediated Suicide Gene Therapy with Radiation in a Preclinical Model of Pancreatic Cancer

In preparation for a Phase I trial, we evaluated the efficacy and toxicity of replication-competent adenovirus-mediated suicide gene therapy in combination with radiation in a preclinical model of pancreatic cancer. Human MiaPaCa-2 and PANC-1 pancreatic adenocarcinoma cells were found to be sensitive to the oncolytic effects of the Ad5-yCD/mutTK(SR39)rep-ADP adenovirus and also to the cytotoxic effects of the yeast cytosine deaminase (yCD) and herpes simplex virus thymidine kinase (HSV-1 TK(SR39)) genes in vitro. Combining Ad5-yCD/mutTK(SR39)rep-ADP-mediated suicide gene therapy with radiation significantly increased tumor control beyond that of either modality alone. Injection of Ad5-yCD/mutTK(SR39)rep-ADP in the dog pancreas at doses (10(12) virus particle (vp)) to be used in humans resulted in mild pancreatitis but not peritonitis or hepatotoxicity. Following administration of 9-(4-[(18)F]-fluoro-3-hydroxymethylbutyl)guanine ([(18)F]-FHBG), a positron-emitting substrate of HSV-1 TK, Ad5-yCD/mutTK(SR39)rep-ADP activity could be monitored non-invasively by positron emission tomography (PET). [(18)F]-FHBG uptake was readily detected in the pancreas but not in other major abdominal organs, indicating that little of the injected adenovirus disseminates to collateral tissues. These results demonstrate that Ad5-yCD/mutTK(SR39)rep-ADP-mediated suicide gene therapy has the potential to augment the effectiveness of pancreatic radiotherapy without resulting in excessive toxicity. Hence they provide the scientific basis for an ongoing Phase I trial in pancreatic cancer.

Phase I Trial of Replication-competent Adenovirus-mediated Suicide Gene Therapy Combined with IMRT for Prostate Cancer

Replication-competent adenovirus-mediated suicide gene therapy is an investigational cancer treatment in which an oncolytic adenovirus armed with chemo-radiosensitizing genes is used to destroy tumor cells. Previously, we evaluated the toxicity and efficacy of this approach in two clinical trials of prostate cancer using a first-generation adenovirus. Here, we report the toxicity and preliminary efficacy of this approach in combination with intensity-modulated radiotherapy (IMRT) in patients with newly diagnosed prostate cancer using an improved, second-generation adenovirus. The investigational therapy was associated with low toxicity, and there were no dose-limiting toxicities or treatment-related serious adverse events. Relative to a previous trial using a first-generation adenovirus, there was no increase in hematologic, hepatic, gastrointestinal (GI), or genitourinary (GU) toxicities. Post-treatment prostate biopsies yielded provocative preliminary results. When the results of two similar trials were combined, 22% of evaluable patients were positive for adenocarcinoma at their last biopsy, which is better than expected (>or=40%) for this cohort of patients (P=0.038). When the results were categorized by prognostic risk, most of the treatment effect was observed in the intermediate-risk group, with 0 of 12 patients (0%) being positive for cancer at their last biopsy (P<0.01). These results further demonstrate the safety of this investigational approach and raise the possibility that it may have the potential to improve the outcome of conformal radiotherapy in select patient groups.

Localized viral vector delivery to enhance in situ regenerative gene therapy

A lyophilization method was developed to locally release adenoviral vectors directly from biomaterials for in situ regenerative gene therapy. Adenovirus expressing a beta-galactosidase reporter gene (AdLacZ) was mixed with different excipient formulations and lyophilized on hydroxyapatite (HA) disks followed by fibroblasts culturing and 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-gal) staining, suggesting 1 M sucrose in phosphate-buffered saline had best viability. Adenovirus release studies showed that greater than 30% virus remained on the material surface up to 16 h. Lyophilized adenovirus could be precisely localized in defined patterns and the transduction efficiency was also improved. To determine if the lyophilization formulations could preserve viral bioactivity, the lyophilized AdLacZ was tested after being stored at varying temperatures. Bioactivity of adenovirus lyophilized on HA was maintained for greater than 6 months when stored at -80 degrees C. In vivo studies were performed using an adenovirus encoding BMP-2 (AdBMP-2). AdBMP-2 was lyophilized in gelatin sponges and placed into rat critical-size calvarial defects for 5 weeks. Micro-computed tomography (micro-CT) analysis demonstrated that free-form delivery of AdBMP-2 had only modest effects on bone formation. In contrast, AdBMP-2 lyophilized in gelatin sponges led to more than 80% regeneration of critical-size calvarial defects.

Novel therapeutic strategy for prevention of malignant tumor recurrence after surgery: Local delivery and prolonged release of adenovirus immobilized in photocured, tissue-adhesive gelatinous matrix.

We have been developing a new gene delivery method using a styrenated gelatin-based tissue-adhesive matrix that allows in situ adenovirus-immobilized gel formation on living tissue and sustained virus release to permeate carcinoma tissue. Styrenated gelatin was synthesized by the condensation reaction of gelatin with 4-vinylbenzoic acid. Aqueous styrenated gelatin solution premixed with AdLacZ, adenovirus encoding beta-galactosidase cDNA, and carboxylated camphorquinone (CQ) as a photoinitiator was irradiated with visible light to form a styrenated gelatin gel. The in vitro adenovirus release from the styrenated gelatin gel to a medium strongly depended not on styrenated gelatin concentration but on CQ concentration. Maximal beta-galactosidase expression was observed on day 1, followed by a rapid decrease that continued up to 1 month for a styrenated gelatin gel prepared with a low styrenated gelatin concentration and a low CQ concentration. Dose-dependent reduced expression of beta-galactosidase activity with increasing CQ under photoirradiation was observed. AdLacZ-immobilized styrenated gelatin gel was formed on a hybrid tissue, which is a cell traction-induced collagenous gel entrapped with fibroblasts, and lacZ gene expression of fibroblasts in the hybrid tissue was observed for more than one month. The result of this in vitro model experiment implies that the tissue-adhesive styrenated gelatin may be applicable for the delivery of adenovirus encoding cDNA for tumor dormancy therapy into malignant tissue to prevent tumor recurrence after surgery when cDNA is properly selected.

Adenovirus ADP protein (E3-11.6K), which is required for efficient cell lysis and virus release, interacts with human MAD2B

The human subgroup C adenovirus (Ad) protein named adenovirus death protein (ADP) (previously named E3-11.6K) is synthesized at very late stages of infection when it mediates efficient lysis of cells and release of adenovirus to infect other cells. ADP is an integral membrane N-linked, O-linked palmitoylated glycoprotein of 101 amino acids (aa) that localizes to the nuclear membrane, endoplasmic reticulum (ER), and Golgi. It has a single membrane spanning region (roughly aa 40–60) and is oriented with aa 1–40 in the lumen and aa 61–101 in the nucleoplasm and cytoplasm. Using aa 61–101 of Ad2 ADP as bait in a yeast two-hybrid screen, we isolated a cDNA for a 211-aa protein that initially was not in the database but has now been published by others with the names human MAD2B, MAD2L2, and REV7. ADP binds strongly to human MAD2B not only in yeast but also in GST pull-down experiments and in coimmunoprecipitations of ADP and MAD2B synthesized in vitro or in vivo. ADP mutants with deletions throughout the bait region do not interact with human MAD2B, whereas a Pro69Pro70 to Ala69Ala70 mutant in the “basic-proline” domain of ADP does interact. Northern blot analyses indicate that human MAD2B is expressed ubiquitously. Human MAD2B is about 25% identical to human MAD2, a spindle assembly checkpoint protein. Two human A549 cell lines were made that constitutively overexpress MAD2B. Wild-type adenovirus lyses these cells significantly more slowly than it lyses parental A549 cells, raising the possibility that ADP and MAD2B act in opposition and suggesting that the ADP–MAD2B interaction is biologically relevant.

Overexpression of the ADP (E3-11.6K) Protein Increases Cell Lysis and Spread of Adenovirus

Adenoviruses replicate in the nucleus and induce lytic cell death. We have shown previously that efficient cell lysis and release of adenovirus from infected cells requires an 11.6-kDa protein named Adenovirus Death Protein (ADP). The adp gene is located in the early E3 transcription unit, but the gene is expressed primarily at very late stages of infection. The putative function of ADP was discerned previously from the use of virus mutants that lack functional ADP. Here we describe two adenovirus mutants, named VRX-006 and VRX-007, that overexpress ADP. VRX-006 lacks all other genes in the E3 region, and VRX-007 lacks all other E3 genes except 12.5K. VRX-006 and VRX-007 display the phenotype predicted by the proposed function for ADP: they produce early cytopathic effect, early cell lysis, large plaques, and increased cell-to-cell spread. They grow as well in cultured cells as does adenovirus type 5. These results are consistent with the conclusion that ADP functions in adenovirus infections to promote virus release from cells at the culmination of infection.

Cell contact dependent extended release of adenovirus by microparticles in vitro

Adenoviral vectors remain one of the most promising methods of gene delivery but are plagued by several inherent problems including immune inactivation and transient expression. This paper reports a novel microparticle-based delivery system for adenovirus that allows high uptake of virus, stable complex formation and extended release. In addition, this microparticle/adenovirus complex has been demonstrated to only release virus upon cell contact. The significant clinical implications of this delivery system are discussed.

Tissue-specific, tumor-selective, replication-competent adenovirus vector for cancer gene therapy.

We have previously described two replication-competent adenovirus vectors, named KD1 and KD3, for potential use in cancer gene therapy. KD1 and KD3 have two small deletions in the E1A gene that restrict efficient replication of these vectors to human cancer cell lines. These vectors also have increased capacity to lyse cells and spread from cell to cell because they overexpress the adenovirus death protein, an adenovirus protein required for efficient cell lysis and release of adenovirus from the cell. We now describe a new vector, named KD1-SPB, which is the KD1 vector with the E4 promoter replaced by the promoter for surfactant protein B (SPB). SPB promoter activity is restricted in the adult to type II alveolar epithelial cells and bronchial epithelial cells. Because KD1-SPB has the E1A mutations, it should replicate within and destroy only alveolar and bronchial cancer cells. We show that KD1-SPB replicates, lyses cells, and spreads from cell to cell as well as does KD1 in H441 cells, a human cancer cell line where the SPB promoter is active. KD1-SPB replicates, lyses cells, and spreads only poorly in Hep3B liver cancer cells. Replication was determined by expression of the E4ORF3 protein, viral DNA accumulation, fiber synthesis, and virus yield. Cell lysis and vector spread were measured by lactate dehydrogenase release and a "vector spread" assay. In addition to Hep3B cells, KD1-SPB also did not express E4ORF3 in HT29.14S (colon), HeLa (cervix), KB (nasopharynx), or LNCaP (prostate) cancer cell lines, in which the SPB promoter is not expected to be active. Following injection into H441 or Hep3B tumors growing in nude mice, KD1-SPB caused a three- to fourfold suppression of growth of H441 tumors, similar to that seen with KD1. KD1-SPB had only a minimal effect on the growth of Hep3B tumors, whereas KD1 again caused a three- to fourfold suppression. These results establish that the adenovirus E4 promoter can be replaced by a tissue-specific promoter in a replication-competent vector. The vector has three engineered safety features: the tissue-specific promoter, the mutations in E1A that preclude efficient replication in nondividing cells, and a deletion of the E3 genes which shield the virus from attack by the immune system. KD1-SPB may have use in treating human lung cancers in which the SPB promoter is active.

Coacervate microspheres as carriers of recombinant adenoviruses.

The therapeutic utility of recombinant adenoviruses (rAds) is limited in part by difficulties in directing the viruses to specific sites and by the requirement for bolus administration, both of which limit the efficiency of target tissue infection. As a first step toward overcoming these limitations, rAds were encapsulated in coacervate microspheres comprised of gelatin and alginate followed by stabilization with calcium ions. Ultrastructural evaluation showed that the microspheres formed in this manner were 0.8-10 microM in diameter, with viruses evenly distributed. The microspheres achieved a sustained release of adenovirus with a nominal loss of bioactivity. The pattern of release and the total amount of virus released was modified by changes in microsphere formulation. Administration of the adenovirus-containing microspheres to human tumor nodules engrafted in mice showed that the viral transgene was transferred to the tumor cells. It is concluded that coacervate microspheres can be used to encapsulate bioactive rAd and release it in a time-dependent manner.

The adenovirus death protein (E3-11.6K) is required at very late stages of infection for efficient cell lysis and release of adenovirus from infected cells

Adenovirus (Ad) infection is concluded by assembly of virions in the cell nucleus followed by lysis of cells by an unknown mechanism. We have described an Ad nuclear membrane glycoprotein of 11,600 kDa (E3-11.6K) which is encoded by the E3 transcription unit and which is synthesized in small amounts from the E3 promoter at early stages of infection but in large amounts from the major late promoter at very late stages of infection. We now report that E3-11.6K is required for the efficient lysis (death) of Ad-infected cells, and we propose that the function of E3-11.6K is to mediate the release of Ad progeny from infected cells. We have renamed E3-11.6K the Ad death protein (ADP). Virus mutants that lack ADP replicated as well as adp+ Ad, but the cells lysed more slowly, virus release from the cell was retarded, and the plaques were small and developed slowly. Cells infected with adp+ viruses began to lyse at 2 or 3 days postinfection (p.i.) and were completely lysed by 5 or 6 days p.i. In contrast, cells infected with adp mutants did not begin significant lysis until 5 or 6 days p.i. Cell lysis and viability were determined by plaque size, extracellular virus, cell morphology, release of lactate dehydrogenase, trypan blue exclusion, the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-2H-tetrazolium bromide (MTT) assay for mitochondrial activity, RNA degradation, and DNA degradation as determined by agarose gel electrophoresis and the terminal deoxynucleotidyltransferase end labeling assay. Protein synthesis was almost nonexistent at 3 days p.i. in cells infected with adp+ Ads, but it was still increasing in cells infected with adp mutants. Host cell protein synthesis was undetectable at 1 day p.i. in cells infected with adp+ Ads or adp mutants. Cells infected with adp mutants showed Ad cytopathic effect at 1 or 2 days p.i. in that they rounded up and detached, but the cells remained metabolically active and intact for >5 days p.i. When examined by electron microscopy, the nuclei were extremely swollen and full of virus, and the nuclear membrane appeared to be intact. ADP is unrelated in sequence to other known cell death-promoting proteins.