Reduction of nontarget infection and systemic toxicity by targeted delivery of conditionally replicating viruses transported in mesenchymal stem cells.

The fiber-modified adenoviral vector Delta-24-RGD (D24RGD) offers vast therapeutic potential. Direct injection of D24RGD has been used to successfully target ovarian tumors in mice. However, systemic toxicity, especially in the liver, profoundly limits the efficacy of direct viral vector delivery. Mesenchymal stem cells (MSC) have the ability to function as a vector for targeted gene therapy because of their preferential engraftment into solid tumors and participation in tumor stroma formation. We show that MSC-guided delivery of D24RGD is specific and efficient and reduces the overall systemic toxicity in mice to negligible levels compared with D24RGD alone. In our model, we found efficient targeted delivery of MSC-D24RGD to both breast and ovarian cell lines. Furthermore, immunohistochemical staining for adenoviral hexon protein confirmed negligible levels of systemic toxicity in mice that were administered MSC-D24RGD compared with those that were administered D24RGD. These data suggest that delivery of D24RGD through MSC not only increases the targeted delivery efficiency, but also reduces the systemic exposure of the virus, thereby reducing overall systemic toxicity to the host and ultimately enhancing its value as an anti-tumor therapeutic candidate.

Oncolytic adenovirus retargeted to Delta-EGFR induces selective antiglioma activity.

The fact that glioblastomas, which are one of the most devastating cancers, frequently express the Delta-EGFR (epithelial growth factor receptor) also called mutant variant III of EGFR (EGFRvIII) suggests that this cancer cell-specific receptor might serve as an ideal target for cancer therapy. To assess its potential as such a target, we constructed an oncolytic adenovirus with Retargeted Infectivity Via EGFR (Delta-24-RIVER) on the backbone of Delta-24. This new oncolytic adenovirus targets, as Delta-24 does, the disrupted Rb pathway in cancer cells; in addition, this adenovirus has also been retargeted through the abrogation of CAR binding (Y477A mutation in adenoviral fiber protein) and insertion of an EGFRvIII-specific binding peptide in the HI loop of the fiber protein. As compared with Delta-24, Delta-24-RIVER induced EGFRvIII-selective cytotoxicity in U-87 MG isogenic cell lines and in tetracycline-inducible EGFRVIII expressing U-251 MG cells. Accordingly, by tittering the viral progeny and examining fiber protein expression in the above cells, we showed that the replication of this new construct also correlated with EGFRvIII expression. Consistently, immunohistochemistry staining of the adenoviral capsid protein hexon in the virus-treated tumors revealed that the virus replicated more efficiently in EGFRvIII-expressing U-87 MG.DeltaEGFR xenografts than in the tumors grown from U-87 MG cells. Importantly, treatment with Delta-24-RIVER prolonged the survival of animals with intracranial xenografts derived from U-87 MG.DeltaEGFR cells. Therefore, our results constitute the first proof of the direct targeting of a cancer-specific receptor using an oncolytic adenovirus.

The (in) auspicious role of mesenchymal stromal cells in cancer: be it friend or foe.

Recent progress in the research of mesenchymal stromal cells/multipotent stromal cells (MSC) has revealed numerous beneficial innate characteristics, suggesting potential value in an array of cellular therapies. MSC are easily isolated from bone marrow (BM), fat and other tissues, and are readily propagated in vitro. Transplanted/injected MSC have been shown to migrate to a variety of organs and tissues; however, sites of inflammation and pathology elicit enhanced MSC homing for tissue remodeling and repair. Tumors utilize many of the same inflammatory mediators uncovered in wound healing and likewise provide a site for preferential MSC homing. Although incorporation into the tumor microenvironment is apparent, the role of recruited MSC in the tumor microenvironment remains unclear. Some published studies have shown enhancement of tumor growth and development, perhaps through immunomodulatory and pro-angiogenic properties, while others have shown no apparent effect or have demonstrated inhibition of tumor growth and extended survival. This controversy remains at the forefront as clinical applications of MSC commence in anti-tumor therapies as well as as adjuncts to stem cell transplantation and in ameliorating graft-versus-host disease. Careful analysis of past studies and thoughtful design of future experiments will help to resolve the discrepancies in the field and lead to clinical utility of MSC in disease treatment. This review highlights the current theories of the role of MSC in tumors and explores current controversies.

Clarification of the nomenclature for MSC: The International Society for Cellular Therapy position statement.

The plastic-adherent cells isolated from BM and other sources have come to be widely known as mesenchymal stem cells (MSC). However, the recognized biologic properties of the unfractionated population of cells do not seem to meet generally accepted criteria for stem cell activity, rendering the name scientifically inaccurate and potentially misleading to the lay public. Nonetheless, a bona fide MSC most certainly exists. To address this inconsistency between nomenclature and biologic properties, and to clarify the terminology, we suggest that the fibroblast-like plastic-adherent cells, regardless of the tissue from which they are isolated, be termed multipotent mesenchymal stromal cells, while the term mesenchymal stem cells is used only for cells that meet specified stem cell criteria. The widely recognized acronym, MSC, may be used for both cell populations, as is the current practice; thus, investigators must clearly define the more scientifically correct designation in their reports. The International Society for Cellular Therapy (ISCT) encourages the scientific community to adopt this uniform nomenclature in all written and oral communications.

Preemptive control of graft-versus-host disease in a murine allogeneic transplant model using retrovirally transduced murine suicidal lymphocytes.

Suicidal lymphocytes could greatly expand the role of allogeneic transplantation by reducing graft-versus-host disease (GVHD) as a barrier to transplantation, but optimization of their use is hindered by the lack of adequate animal models. To develop an animal model that used retrovirally transduced suicidal lymphocytes in a GVHD setting, a well-characterized MHC-matched murine transplant model (B10.BR-->AKR/J) was adapted. B10.BR splenic lymphocytes stimulated with concanavalin A and interleukin 2 were infected with a retrovirus containing the low-affinity nerve growth factor receptor (LNGFR) and the HSV-TK gene and immunomagnetically selected; these LNGFR+/TK+ allogeneic lymphocytes were then cotransplanted with 1 x 10(7) bone marrow cells into lethally irradiated AKR/J recipients. The LNGFR+/TK+ donor lymphocytes persisted in the peripheral circulation for 6 months in both syngeneic and allogeneic settings. Doses of 2 x 10(6) TK+ allogeneic lymphocytes produced GVHD with a severity and time course similar to that induced by naive lymphocytes. Survival of TK+ allogeneic lymphocyte-bearing mice was significantly improved (P = 0.01) when ganciclovir (GCV; 2 mg/day) was administered on days 7-13 post transplant by i.p. injection, demonstrating that GVHD could be prevented. Fluorescence-activated cell sorting analysis demonstrated 4-fold reduction but persistent circulation of LNGFR+ lymphocytes in mice treated with GCV at various time points 1-3 months after transplantation, demonstrating selective killing of GVHD-reactive cells. We conclude that retrovirally transduced LNGFR+/TK+ murine lymphocytes can be produced, persist after transplant, remain alloreactive, and can be killed by GCV administration, resulting in reduced GVHD.

The use of adenoviral vectors for genetic manipulation and analysis of primitive hematopoietic cells.

Gene transfer into stem cells has long been studied as a means by which primitive hematopoietic cells could be characterized and manipulated. While a variety of strategies have been attempted, it still remains relatively difficult to perform direct stem cell analysis. In this review, we examine recent studies using adenovirus-based vectors as a means to achieve high-level gene transfer into primitive hematopoietic cell types.

Adenovirus as a gene therapy vector for hematopoietic cells.

Adenovirus (Adv)-mediated gene transfer has recently gained new attention as a means to deliver genes for hematopoietic stem cell (HSC) or progenitor cell gene therapy. In the past, HSCs have been regarded as poor Adv targets, mainly because they lack the specific Adv receptors required for efficient and productive Adv infection. In addition, the nonintegrating nature of Adv has prevented its application to HSC and bone marrow transduction protocols where long-term expression is required. There is even controversy as to whether Adv can infect hematopoietic cells at all. In fact, the ability of Adv to infect epithelium-based targets and its inability to effectively transfect HSCs have been used in the development of eradication schemes that use Adv to preferentially infect and "purge" tumor cell-contaminating HSC grafts. However, there are data supporting the existence of productive Adv infections into HSCs. Such protocols involve the application of cytokine mixtures, high multiplicities of infection, long incubation periods, and more recently, immunological and genetic modifications to Adv itself to enable it to efficiently transfer genes into HSCs. This is a rapidly growing field, both in terms of techniques and applications. This review examines the two sides of the Adv/CD34 controversy as well as the current developments in this field.

Purging of contaminating breast cancer cells from hematopoietic stem cell grafts by adenoviral GAL-TEK gene therapy and magnetic antibody cell separation.

The presence of contaminating tumor cells in autologous bone marrow or peripheral blood stem cell (PB-SC) preparations increase the likelihood of relapse in women receiving transplants for metastatic breast cancer. We describe a new technique for purging breast cancer cells (BCCs) that combines two independent strategies: (a) the specific enrichment of CD34+ progenitor stem cells by magnetic antibody cell separation (MACS), and then (b) infection of the contaminating BCCs with a recombinant adGAL-TEK marker/suicide gene adenovirus (ad-v), followed by the addition of ganciclovir (GCV). Infection with this ad-v results in three to four times greater expression of ad-v-delivered reporter gene in BCCs than in CD34+ cells. In addition -2 h, -low multiplicity of infection (50:1) adGAL-TEK infections of BCC lines (MCF-7 and BT474) eradicated >99% of BCCs after 72 h of exposure to 20 microM GCV. However, exposure to both adenovirus and GCV at the MOIs and doses used had little effect on hematopoietic stem cells to form colonies in colony-forming unit assays. adGAL-TEK infection in our model system (10(3)-10(5) BCCs added into 10(7) HSCs) also resulted in the 3 to 5 log eradication of clonogenic BCCs after the addition of GCV. MACS enrichment/purification of CD34+ cells from PB-SC contaminated with 2 x 10(6) to 5 x 10(7) BCCs followed by adGAL-TEK infection and GCV addition resulted in 5-7-log depletion of clonogenic BCCs as well as enrichment of CD34+ progenitor cells to >98%, with the recovery of >70% of hematopoietic stem cells. This adenoviral purging system is so robust that poor MACS purification, resulting in 1.5-log depletion of BCCs, still permits excellent ad-v infection and BCC killing.

Autocrine interleukin-1beta production in leukemia: evidence for the involvement of mutated RAS.

Interleukin (IL)-1beta is constitutively expressed in many leukemias and operates as an autocrine growth factor. To study the cellular basis for this aberrant production, we analyzed two cell lines, B1 (acute lymphoblastic leukemia) and W1 (juvenile chronic myelogenous leukemia), which express high levels of IL-1beta and have mutations in the K-RAS and N-RAS genes, respectively. Electromobility shift assays demonstrated transcription factor binding at multiple IL-1beta promoter elements [nuclear factor (NF)-IL6/CREB, NFB1, NFkappaB, and NF-IL6], consistent with the activation of an upstream signaling pathway. To determine whether activated Ras was involved, two structurally distinct classes of farnesyltransferase (FTase) inhibitors (the monoterpenes and a peptidomimetic) and an adenoviral vector expressing antisense targeted to K-RAS were used to specifically interfere with Ras function and/or expression. Treatment with the FTase inhibitors resulted in a concentration-dependent decrease in both NF-IL6/CREB binding to the IL-1beta promoter and IL-1beta protein levels, without a significant change in total cellular protein levels. Furthermore, exposure of the B1 cells to antisense against K-RAS resulted in an approximately 50% reduction in both p21Ras and IL-1beta protein levels. Growth suppression was observed after FTase inhibitor or antisense exposure, an effect that was partially reversible by the addition of recombinant IL-1beta to the cultures. Our observations suggest that mutated RAS genes may mediate autocrine IL-1beta production in some leukemias by stimulating signal transduction pathways that activate the IL-1beta promoter.

Production and culture of HSVtk transduced suicidal lymphocytes induces variable changes in the lymphocyte subset composition.

Allogeneic bone marrow transplant followed by donor lymphocyte infusion (DLI) is limited by T cell-mediated graft-versus-host disease (GVHD). A potential solution to alleviate uncontrolled GVHD is to create a controllable suicidal lymphocyte using retroviral transduction of the herpes simplex virus thymidine kinase gene (HSVtk) into the T cell graft. Should GVHD arise, the administration of ganciclovir (GCV) should eliminate the causal T cells. The culture conditions and expansion protocols required to produce suicidal lymphocytes may affect the composition of the T cell product. In this report we describe how T cells from individual donor samples respond to the same culture condition in highly varied ways. Among five donors, two demonstrated predominant expansion of CD4+ cells (with a decrease of CD8+), two donors resulted in predominately CD8+ cells, and one donor developed mainly dual positive CD8+/CD56+ cells. We observed a 20-fold expansion of T cells during the 14 day protocol. The function of the T cells was not affected by the transduction procedures (as tested by 51Cr release assays). In contrast to suicidal lymphocytes prepared using entire T cell populations, T cells pre-selected into CD3+/CD4+ or CD3+/CD8+ subpopulations prior to culture maintained their initial phenotype during the 14 day culture period, with little or no drift. Results from clinical trials using suicidal lymphocytes may be confounded by variance in lymphocyte subset compositions (LSC) and optimal use of suicidal lymphocytes may require separate culture and transduction to control the LSC delivered to the patient.

Transduction of normal and malignant oral epithelium by particle bombardment.

Although genetic approaches to the treatment and prevention of oral cancer are being developed, there are no suitable methods of transduction of the oral mucosa or early cancers. We therefore tested the technique of particle bombardment for its ability to transduce oral cancer cells in vitro and normal epithelium of the hamster cheek pouch in vivo. A gene gun was used to transfer a plasmid that encoded a marker/suicide fusion gene, beta-galactosidase-thymidine kinase (GAL-TEK), under control of a CMV promoter. For comparison we used the method of lipofection and an adenovirus vector. Particle bombardment transduced up to 13% of cells in culture, resulting in a 24.3% reduction in growth in the presence of ganciclovir. The efficiency of transduction was similar to that of lipofection but was much less than that of the adenovirus vector, which transduced 54% of cells and completely inhibited their growth in the presence of ganciclovir. Transduction of the hamster cheek pouch by particle bombardment produced expression of beta-galactosidase as judged by macroscopic staining, for up to 5 days. However, histological examination showed that the transduced cells were rare and superficial, and that administration of systemic ganciclovir did not lead to any changes in the tissue. Improvements in efficiency are necessary before the gene gun can be used in the management of oral cancer.

The drug verapamil inhibits bystander killing but not cell suicide in thymidine kinase-ganciclovir prodrug-activated gene therapy.

The bystander effect, in which unmodified cells are killed as the result of enzyme-prodrug activation in genetically modified neighboring cells, amplifies the suicide response in a tumor in which only a fraction of the cells are targeted. The drug verapamil (VRP), a calcium channel antagonist that is also used to counteract the multidrug resistance of tumor cells, is shown to inhibit the bystander effect by herpes simplex virus thymidine kinase (HSVtk) enzyme-prodrug therapy with ganciclovir by protecting beta geo marked bystander cells in both in vitro coculture assays and in an in vivo animal tumor model. VRP had no stimulatory or inhibitory effect on the proliferation of CT 26 cells, their tumorigenicity, or prodrug-activated cell death produced by the action of the HSVtk gene. The kinetics of the protection afforded by VRP was time dependent with respect to the time of addition of the prodrug, and protection was ineffective when added two or more days after prodrug administration.

Assessment of bystander effect potency produced by intratumoral implantation of HSVtk-expressing cells using surrogate marker secretion to monitor tumor growth kinetics.

A molecular marker, human alpha-1-antitrypsin (hAAT) was transduced into tumor cells and its secretion was found to correlate with tumor growth or regression, allowing for an accurate and continuous measurement of tumor growth kinetics. Using this system, we investigated the therapeutic potential produced purely from the bystander effect of HSVtk+ CT26 cells to eradicate established CT26 colon carcinomas in mice by direct intratumoral implantation and subsequent ganciclovir administration. With lower ratios (0.1% and 1% of initial tumor burden), tumor growth kinetics went into a static (remission) phase of approximately 2 weeks duration before relapse and resumption of progressive tumor growth. When the number of CT26tk+ modified cells injected into the tumor equaled 10% to 100% of the initial tumor cell number the bystander effect was sufficient to completely eradicate established tumors indicating that a potent bystander killing effect is produced in this system, and that a cellular therapy based on this approach may have applications.

In vivo marking of spontaneous or vaccine-induced fibrosarcomas in the domestic house cat, using an adenoviral vector containing a bifunctional fusion protein, GAL-TEK.

We evaluated the ability of a replication-deficient, recombinant adenoviral vector to transfer the bifunctional gene GAL-TEK, which expresses a marking/therapeutic gene product, to naturally occurring cat fibrosarcomas in situ. GAL-TEK contains an in-frame fusion of the bacterial LacZ gene for histochemical marking of tumors with beta-galactosidase (beta-Gal) and the HSV tk gene for enzyme-prodrug activation of the prodrug ganciclovir (GCV) to induce selective tumor cell killing. GAL-TEK bifunctional marking and cell killing activities were tested in vitro after adenoviral vector infection of HT1080 human fibrosarcoma cells. The tk activity of GAL-TEK is shown to be almost as potent as HSV tk to catalyze conversion of GCV to GCV nucleotides and promote selective cell killing. Using 8 cats with recurring 2.5-cm2 fibrosarcomas that either arose spontaneously or were induced by vaccine, we determined experimentally the administration routes and times required for optimum GAL-TEK gene transfer by beta-Gal histological staining and reverse transcriptase polymerase chain reaction to the multiple compartments of the growing fibrosarcomas consonant with minimizing collateral infection of neighboring tissues and other unwanted side effects.

Abnormal secretagogue-induced intracellular free Ca2+ regulation in cystic fibrosis nasal epithelial cells.

These studies identify a further abnormality in cystic fibrosis (CF). The increase in intracellular free calcium concentration ([Ca2+]i) after exposure to histamine and PGE1 is demonstrated to be abnormally low in nasal cells, studied in short-term culture, from patients with CF compared with control subjects. [Ca2+]i is measured by using the Ca(2+)-sensitive fluorescent dye fura-2 and a fluorescence microscope imaging system. The percentage of CF cells that increase [Ca2+]i in response to histamine is decreased compared with controls, and, even in those CF cells that increase [Ca2+]i, the magnitude of the increase in [Ca2+]i in response to histamine is smaller than in controls. When exposed to PGE1, a similar number of control and CF cells responded with an increase in [Ca2+]i, but again the magnitude of the response was smaller in the CF cells. The mechanism of the PGE1-induced increase in [Ca2+]i is not mediated by cAMP, since 8-bromo-cAMP failed to increase [Ca2+]i in these cells. This abnormality in [Ca2+]i response did not apply to all secretagogues, with the response to carbachol being similar in CF and normal cells. How the abnormal CF gene product accounts for the abnormality in intracellular Ca2+ response to some but not all secretagogues is unknown.

Expression of normal and cystic fibrosis phenotypes by continuous airway epithelial cell lines.

Continuous epithelial cell lines from individuals with cystic fibrosis (CF) and normal controls are required to understand the genetic and cellular defects in CF. We used retroviruses to transduce SV40 large T antigen into nasal epithelial cells. Transformed continuous cell lines were isolated that expressed epithelial markers, cytokeratin, and tight junctions. Northern blot analysis shows that all of the cell lines express the putative CF gene mRNA. Studies of transepithelial electrolyte transport show that CF and normal cell lines develop a transepithelial electrical resistance. Normal but not CF cell lines secreted Cl- in response to agonists that increase cellular levels of adenosine 3',5'-cyclic monophosphate (cAMP) (isoproterenol, forskolin, and a membrane-permeant analogue of cAMP) or in response to a tumor-promoting phorbol ester that activates protein kinase C. In contrast, the Ca2(+)-elevating agonist bradykinin and the Ca2+ ionophore A23187 stimulated secretion in both normal and CF cell lines. The continuous cell lines we have produced maintain their proper phenotypes and will serve as useful tools in understanding the pathophysiology of CF.