Ivan King

Use of preferentially replicating bacteria for the treatment of cancer

The past several years have seen renewed interest in the treatment of cancer with live microorganisms, based on the observation that some microorganisms display selective replication or preferential accumulation in the tumor microenvironment. Preferential replication offers great potential to amplify the therapeutic effect of the microorganism while sparing normal tissues from toxicity. Much of the current research intended to achieve selective replication within, and lysis of, tumor cells has focused on viruses, but recent observations in murine models with facultative anaerobic bacteria (1), as well as data generated more than 30 years ago with obligate anaerobic bacteria (2), indicate that some bacterial species can also preferentially replicate and accumulate within tumors. In contrast to viruses, the bacteria reside primarily in the extracellular tumor microenvironment (3) and possess certain features that may be advantageous in the treatment of cancer. Thus, bacteria are motile, which facilitates their spread throughout the tumor and can help target systemic disease. Because of their large genome size, bacteria can readily express multiple therapeutic transgenes, such as cytokines or pro–drug-converting enzymes, and their spread can be controlled with antibiotics if necessary.

Tumor-Targeted Salmonella Expressing Cytosine Deaminase as an Anticancer Agent

The study was designed to evaluate whether TAPET-CD, an attenuated strain of Salmonella typhimurium expressing Escherichia coli cytosine deaminase (CD), was capable of converting nontoxic 5-fluorocytosine (5-FC) to the active antitumor agent 5-fluorouracil (5-FU). The antitumor effect of TAPET-CD plus 5-FC against subcutaneously implanted colon tumors was also evaluated. TAPET-CD was given to tumor-bearing mice by a single bolus intravenous administration followed with 5-FC by intraperitoneal administration. TAPET-CD accumulated in tumors at levels 1000-fold higher than that in normal tissues and high levels of 5-FU were detected in tumors in mice treated with both TAPET-CD and 5-FC. No 5-FU could be detected in normal tissues. Inhibition of tumor growth was observed in mice treated with either TAPET-CD alone or TAPET-CD in combination with 5-FC (TAPET-CD/5-FC), but not with 5-FC alone. TAPET-CD/5-FC inhibited tumor growth by 88%-96%, compared to TAPET-CD alone, which inhibited tumor growth by 38%-79%. These data suggest that tumor-targeting Salmonella could be used to deliver prodrug-converting enzyme selectively to tumors and produced anti-tumor effects when the corresponding prodrug was also given.

Systemic Administration of an Attenuated, Tumor-Targeting Salmonella typhimurium to Dogs with Spontaneous Neoplasia: Phase I Evaluation

Purpose: Genetically modified bacteria are a potentially powerful anticancer therapy due to their tumor targeting capacity, inherent antitumor activity, and ability to serve as efficient vectors for gene delivery. This study sought to characterize the acute and short-term toxicities and tumor colonization rates of a genetically modified Salmonella typhimurium (VNP20009) in dogs with spontaneous tumors, in the context of a phase I dose escalation trial. Experimental Design: Forty-one pet dogs with a variety of malignant tumors received weekly or biweekly i.v. infusions of VNP20009, at doses ranging from 1.5 × 105 to 1 × 108 cfu/kg. Vital signs and clinicopathologic variables were monitored regularly. Incisional biopsies were obtained before and 1 week following the first infusion for histopathology and bacterial culture. Results: The nominal maximum tolerated dose was 3 × 107 cfu/kg, with refractory fever and vomiting being the dose-limiting toxicities. One treatment-related acute death occurred. Bacteria were cultured from tumor tissue in 42% of cases. Thirty-five patients were evaluable for antitumor response. Major antitumor responses were seen in 15% (4 complete response and 2 partial response), and disease stabilization for at least 6 weeks in 10%. Conclusions: Administration of VNP20009 at doses with acceptable toxicity results in detectable bacterial colonization of tumor tissue and significant antitumor activity in tumor-bearing dogs.

Characterization of the Antiviral Effect of 2′,3′-Dideoxy-2′, 3′-Didehydro-β-l-5-Fluorocytidine in the Duck Hepatitis B Virus Infection Model

ABSTRACT A novel l-nucleoside analog of deoxycytidine, 2′,3′-dideoxy-2′,3′-didehydro-β-l-5-fluorocytidine (β-l-Fd4C), was recently shown to strongly inhibit hepatitis B virus (HBV) replication in the 2.2.15 cell line. Therefore, its antiviral activity was evaluated in the duck HBV (DHBV) infection model. Using a cell-free system for the expression of the DHBV polymerase, β-l-Fd4C-TP exhibited a concentration-dependent inhibition of dCTP incorporation into viral minus-strand DNA with a 50% inhibitory concentration of 0.2 μM which was lower than that of other tested deoxycytidine analogs, i.e., lamivudine-TP, ddC-TP, and β-l-FddC-TP. Further analysis showed that β-l-Fd4C-TP is likely to be a competitive inhibitor of dCTP incorporation and to cause premature DNA chain termination. In primary duck hepatocyte cultures infected in vitro, β-l-Fd4C administration exhibited a long-lasting inhibitory effect on viral DNA synthesis but could not clear viral covalently closed circular DNA (CCC DNA). Results of short-term antiviral treatment in experimentally infected ducklings showed that β-l-Fd4C exhibited the most potent antiviral effect, followed by β-l-FddC, lamivudine, and ddC. Longer administration of β-l-Fd4C induced a sustained suppression of viremia (>95% of controls) and of viral DNA synthesis within the liver. However, the persistence of trace amounts of viral CCC DNA detected only by PCR was associated with a recurrence of viral replication after drug withdrawal. In parallel, β-l-Fd4C treatment suppressed viral antigen expression within the liver and decreased intrahepatic inflammation and was not associated with any sign of toxicity. Our data, therefore, demonstrate that in the duck model of HBV infection, β-l-Fd4C is a potent inhibitor of DHBV reverse transcriptase activity in vitro and suppresses viral replication in the liver in vivo.

Syntheses and Antitumor Activities of Potent Inhibitors of Ribonucleotide Reductase: 3-Amino-4-Methylpyridine-2-Carboxaldehyde-Thiosemicarbazone (3-Amp), 3-Amino-Pyridine-2-Carboxaldehyde-Thiosemicarbazone (3-Ap) and its Water-Soluble Prodrugs

The reductive conversion of ribonucleotides to deoxyribonucleotides by ribonucleotide reductase (RR) is a crucial and rate-controlling step in the pathway leading to the biosynthesis of DNA, since deoxyribonucleotides are present in extremely low levels in mammalian cells. Mammalian ribonucleotide reductase (RR) is composed of two dissimilar proteins, often referred to as R(1), which contains polythiols and R(2), which contains non-heme iron and a free tyrosyl radical. Both the R(1) and R(2) subunits contribute to the active site of the enzyme. Currently, there are two broad classes of RR inhibitors. The first class includes nucleoside analogs which bind to the R1 subunit of the enzyme, several of which are in development. Among those, Gemcitabine and MDL 101,731 have demonstrated impressive efficacy against various solid tumors. Gemcitabine has now been approved for the treatment of pancreatic cancer and non-small cell lung cancer. The most promising second class of inhibitors of RR includes HCTs [alpha--(N)-heterocyclic carboxaldehyde thiosemicarbazones, e.g., 3-AP and 3-AMP], which exert enzyme inhibitory effect through high affinity binding with non-heme iron. Based on the clinical success achieved by Gemcitabine, it seems reasonable that a strong inhibitor of RR, which is essential for cellular replication, would be a useful addition to the existing therapeutic agents against cancer. In this chapter, we wish to report several highly efficient syntheses for both 3-AP and 3-AMP based upon palladium mediated Stille/Suzuki/Heck coupling reactions. Based upon the in vivo efficacy profile observed with these two agents, 3-AP was chosen over 3-AMP as the candidate for further optimization with the intention to improve its biological and pharmaceutical properties. In this vein, we have completed the synthesis of two water soluble phosphate containing prodrugs and one disulfide-linked prodrug of 3-AP. As expected, bioconversion study using either alkaline phosphatase or glutathione showed that these prodrugs were indeed converted to the parent 3-AP. When evaluated against the murine M-109 lung carcinoma as well as the B16-F10 murine melanoma xenograft models, the newly prepared phosphate prodrugs displayed improved efficacy and safety profiles than that found with the parent. More significantly, the ortho-phosphate prodrug 21 demonstrated impressive antitumor effect using once-a-day dosing regimen. In summary, the results disclosed herein demonstrated that some of 3-AP prodrugs prepared indeed demonstrated improved pharmaceutical, biological and toxicity profiles over the parent 3-AP. Efforts directed towards further optimization of 3-AP prodrugs as novel anticancer agents is clearly warranted.

Antitumor effect of VNP20009, an attenuated Salmonella, in murine tumor models.

VNP20009, a genetically modified strain of Salmonella typhimurium with deletions in the msbB and purI loci, exhibited antitumor activities when given systemically to tumor-bearing mice. VNP20009 inhibited the growth of subcutaneously implanted B16F10 murine melanoma, and the human tumor xenografts Lox, DLD-1, A549, WiDr, HTB177, and MDA-MB-231. A single intravenous injection of VNP20009, at doses ranging from 1 x 10(4) to 3 x 10(6) cfu/mouse, produced tumor growth inhibitions of 57-95%. Tumor volume doubling time, another indicator for tumor growth inhibition, also significantly increased in mice treated with VNP20009. Using mice with immune system deficiencies, we also demonstrated that the antitumor effects of VNP20009 did not depend on the presence of T and B cells. In addition, VNP20009, given intravenously, inhibited the growth of lung metastases in mice. Only live bacteria showed the antitumor effect.

Tumor amplified protein expression therapy : Salmonella as a tumor-selective protein delivery vector

Attenuated strains of Salmonella typhimurium, VNP20009 and YS7212, when injected systemically to tumor-bearing mice, accumulated preferentially in tumors at levels at least 200-fold and, more commonly, 1000-fold greater than in other normal tissues. This selectivity occurred in subcutaneously implanted murine tumors, including B16F10 melanoma, M27 lung carcinoma, and colon 38 carcinoma. The preferential accumulation was also manifested in animals bearing human tumor xenografts, including Lox, C8186, DLD1, SW620, HCT116, HTB177, DU145, MDA-MB-231, and Caki. Four to five days after a single IV injection of 1 x 10(6) colony-forming unit (cfu)/mouse, we routinely detected VNP20009 proliferation and accumulation at levels ranging from 1 x 10(8) to 2 x 10(9) cfu/g tumor. The amount of VNP20009 accumulated in the liver ranged from 3 x 10(4) to 2 x 10(6) cfu/g. The distribution of Salmonella in tumors was homogenous; YS7212 could be detected from the periphery to the interior portion of the tumors. Using mice with various immunodeficiencies, we also discovered the same preferential accumulation of Salmonella in tumors implanted in these mice. The use of Salmonella as a protein delivery vector was shown by IV administration of the bacteria expressing either green fluorescent protein (GFP) or cytosine deaminase (CD) into tumor-bearing mice. GFP and CD were detected in tumors, but not in livers, taken from mice inoculated with Salmonella carrying these genes. Bacteria accumulation and CD expression persisted in the tumors for up to 14 days after a single bolus IV administration of bacteria to tumor-bearing mice.

Salmonella-based tumor-targeted cancer therapy: tumor amplified protein expression therapy (TAPET™) for diagnostic imaging

In preclinical studies, genetically engineered Salmonella have the ability to localize, selectively accumulate, and persist within transplantable murine tumors, spontaneous murine tumors and human tumor xenographs, and can express therapeutic proteins at high levels. These strains of engineered non-virulent Salmonella typhimurium display the capacity to accumulate and grow selectively in a variety of tumor types and to inhibit the growth of primary and metastatic tumors following intravenous injection into tumor-bearing mice. One strain of the bacteria (VNP20009) which has endogenous antitumor activity is currently in Phase I clinical trials. The bacteria are highly attenuated and genetically stable. The combination of the lipid mutation and the purine auxotrophy attenuate the virulence of the bacteria by greater than 10000-fold and enhance the specificity of the bacteria for tumor tissue. These bacteria have been found to be safe in mice, pigs and monkeys when administered intravenously. Second-generation Salmonella vectors will be developed to include transgenes that will express therapeutic agents and reporter transgenes for non-invasive imaging. We have performed a preliminary study to demonstrate localization of [(14)C]FIAU in tumored mice pretreated with Salmonella expressing HSV1-TK. The [(14)C]FIAU radioactivity and bacterial count data strongly support a Salmonella(TK)-dependent [(14)C]FIAU accumulation of at least 30-fold higher in tumor tissue compared to muscle tissue. These data warrant further investigation on the use of genetically engineered Salmonella as a systemically administered tumor-specific agents for tumor therapy and delivery of diagnostic imaging markers.

Attenuated Salmonella targets prodrug activating enzyme carboxypeptidase G2 to mouse melanoma and human breast and colon carcinomas for effective suicide gene therapy.

Purpose: We engineered the oncolytic Salmonella typhimurium–derived bacterium VNP20009 as a vector to target delivery to tumors of the prodrug-activating enzyme carboxypeptidase G2 (CPG2) and to show enhanced antitumor efficacy on administration of different prodrugs. Experimental Design: We characterized CPG2 expression in vectors by immunoblotting, immunofluorescence, and enzyme activity. We assessed prodrug activation by high-performance liquid chromatography. Target human tumor cell and bacterial vector cell cytotoxicity was measured by flow cytometry and colony-forming assays. Therapy was shown in two human tumor xenografts and one mouse allograft with postmortem analysis of bacterial and CPG2 concentration in the tumors. Results: CPG2 is expressed within the bacterial periplasm. It activates prodrugs and induces cytotoxicity in human tumor cells but not in host bacteria. Following systemic administration, bacteria multiply within xenografts reaching 2 × 107/g to 2 × 108/g at 40 days postinoculation. The concentration of CPG2 in these tumors increases steadily to therapeutic levels of 1 to 6 units/g. The bacteria alone reduce the growth of the tumors. Subsequent administration of prodrugs further reduces significantly the growth of the xenografts. Conclusions: The bacteria multiply within tumors, resulting in a selective expression of CPG2. The CPG2-expressing bacteria alone reduce the growth of tumors. However, in the presence of prodrugs activated by CPG2, this oncolytic effect is greatly increased. We conclude that bacterial oncolytic therapy, combined with CPG2-mediated prodrug activation, has great potential in the treatment of a range of cancers.

Antiviral Activity of β-l-2′,3′-Dideoxy-2′,3′-Didehydro-5-Fluorocytidine in Woodchucks Chronically Infected with Woodchuck Hepatitis Virus

ABSTRACT The l-nucleoside analog β-l-2′,3′-dideoxy-2′,3′-didehydro-5-fluorocytidine (β-l-Fd4C) was first shown to exhibit potent activity against hepatitis B virus (HBV) in tissue culture and then to significantly inhibit viral spread during acute infection in the duck HBV model (F. Le Guerhier et al., Antimicrob. Agents Chemother. 44:111–122, 2000). We have therefore examined its antiviral activity in a mammalian model of chronic HBV infection, the woodchuck chronically infected with woodchuck hepatitis virus (WHV). Side-by-side comparison of β-l-Fd4C and lamivudine administered intraperitoneally during short-term and long-term protocols demonstrated a more profound inhibition of viremia in β-l-Fd4C-treated groups. Moreover, β-l-Fd4C induced a marked inhibition of intrahepatic viral DNA synthesis compared with that induced by lamivudine. Nevertheless, covalently closed circular (CCC) DNA persistence explained the lack of clearance of infected hepatocytes expressing viral antigens and the relapse of WHV replication after drug withdrawal. Liver histology showed a decrease in the inflammatory activity of chronic hepatitis in woodchucks receiving β-l-Fd4C. An electron microscopy study showed the absence of ultrastructural changes of hepatic mitochondria, biliary canaliculi, and bile ducts. However, a loss of weight was observed in all animals, whatever the treatment, as was a transient skin pigmentation in all woodchucks during β-l-Fd4C treatment. There was no evidence that lamivudine or β-l-Fd4C could prevent the development of hepatocellular carcinoma with the protocols used. These results indicate that β-l-Fd4C exhibits a more potent antiviral effect than lamivudine in the WHV model but was not able to eradicate CCC DNA and infected cells from the liver at the dosage and with the protocol used.