Clinical study of cryosurgery efficacy in the treatment of skin and subcutaneous tumors in dogs and cats

Objective-To evaluate the efficacy of cryosurgery for treatment of skin and subcutaneous tumors in dogs and cats. Study Design-Prospective study. Animals-Dogs (n = 20), cats (10). Methods-Cutaneous or subcutaneous tumors were treated by liquid nitrogen cryosurgical spray (1 cm from target tissue at 90 degrees until a 5-mm halo of frozen tissue was achieved) for 15-60 seconds. Malignant lesions had 3 freeze-thaw cycles benign tumors, 2 cycles. The second or third freeze cycle was performed after complete thaw of the preceding freeze. Wounds healed by second intention. Follow-up was weekly for 1 month and then twice monthly until wounds healed, and final outcome was determined by telephone interview of owners. Results-Tumor size ranged from 0.3 to 11 cm, diameter with 28 (60%) being 0.3-1 cm; 8 (17%) 1.1-3cm, and 11 (23%) >3.4cm. Complications included edema, erythema and for extremity lesions, pain and lameness. Treated lesions (n = 47) had an overall remission of 98% (mean follow-up.. 345 +/- 172.02 days [range, 150-750 days]). One malignant peripheral nerve sheath tumor recurred 7 months after cryosurgical treatment. Conclusion-Cryo surgery is an efficient method for treatment of skin and subcutaneous tumors in dogs and cats. Clinical Relevance-Cryosurgical ablation is an effective means of treating small cutaneous or subcutaneous tumors in dogs and cats, especially in older animals where wound closure or cosmetic outcome might limit surgical excision alone. (C) Copyright 2008 by The American College of Veterinary Surgeons.

Role of tumor–host interactions in interstitial diffusion of macromolecules: Cranial vs. subcutaneous tumors

The large size of many novel therapeutics impairs their transport through the tumor extracellular matrix and thus limits their therapeutic effectiveness. We propose that extracellular matrix composition, structure, and distribution determine the transport properties in tumors. Furthermore, because the characteristics of the extracellular matrix largely depend on the tumor–host interactions, we postulate that diffusion of macromolecules will vary with tumor type as well as anatomical location. Diffusion coefficients of macromolecules and liposomes in tumors growing in cranial windows (CWs) and dorsal chambers (DCs) were measured by fluorescence recovery after photobleaching. For the same tumor types, diffusion of large molecules was significantly faster in CW than in DC tumors. The greater diffusional hindrance in DC tumors was correlated with higher levels of collagen type I and its organization into fibrils. For molecules with diameters comparable to the interfibrillar space the diffusion was 5- to 10-fold slower in DC than in CW tumors. The slower diffusion in DC tumors was associated with a higher density of host stromal cells that synthesize and organize collagen type I. Our results point to the necessity of developing site-specific drug carriers to improve the delivery of molecular medicine to solid tumors.

Subcutaneous vaccination with irradiated, cytokine-producing tumor cells stimulates CD8+ cell-mediated immunity against tumors located in the "immunologically privileged" central nervous system.

Vaccination with cytokine-producing tumor cells generates potent immune responses against tumors outside the central nervous system (CNS). The CNS, however, is a barrier to allograft and xenograft rejection, and established tumors within the CNS have failed to respond to other forms of systemic immunotherapy. To determine what barriers the "immunologically privileged" CNS would pose to cytokine-assisted tumor vaccines and what cytokines would be most efficacious against tumors within the CNS, we irradiated B16 murine melanoma cells producing murine interleukin 2 (IL-2), IL-3, IL-4, IL-6, gamma-interferon, or granulocyte-macrophage colony stimulating factor (GM-CSF) and used these cells as subcutaneous vaccines against tumors within the brain. Under conditions where untransfected B16 cells had no effect, cells producing IL-3, IL-6, or GM-CSF increased the survival of mice challenged with viable B16 cells in the brain. Vaccination with B16 cells producing IL-4 or gamma-interferon had no effect, and vaccination with B16 cells producing IL-2 decreased survival time. GM-CSF-producing vaccines were also able to increase survival in mice with pre-established tumors. The response elicited by GM-CSF-producing vaccines was found to be specific to tumor type and to be abrogated by depletion of CD8+ cells. Unlike the immunity generated against subcutaneous tumors by GM-CSF, however, the effector responses generated against tumors in the CNS were not dependent on CD4+ cells. These data suggest that cytokine-producing tumor cells are very potent stimulators of immunity against tumors within the CNS, but effector responses in the CNS may be different from those obtained against subcutaneous tumors.

In vivo DNA electrotransfer

The use of electrotransfer for DNA delivery to prokaryotic cells, and eukaryotic cells in vitro, has been well known and widely used for many years. However, it is only recently that electric fields have been used to enhance DNA transfer to animal cells in vivo, and this is known as DNA electrotransfer or in vivo DNA electroporation. Some of the advantages of this method of somatic cell gene transfer are that it is a simple method that can be used to transfer almost any DNA construct to animal cells and tissues in vivo; multiple constructs can be co-transfected; it is equally applicable to dividing and nondividing cells; the DNA of interest does not need to be subeloned into a specific viral transfer vector and there is no need for the production of high titre viral stocks; and, as no viral genes are expressed there is less chance of an adverse immunologic reaction to vector sequences. The ease with which efficient in vivo gene transfer can be achieved with in vivo DNA electrotransfer is now allowing genetic analysis to be applied to a number of classic animal model systems where transgenic and embryonic stem cell techniques are not well developed, but for which a wealth of detailed descriptive embryological information is available, or surgical manipulation is much more feasible. As well as exciting applications in developmental biology, in vivo DNA electrotransfer is also being used to transfer genes to skeletal muscle and drive expression of therapeutically active proteins, and to examine exogenous gene and protein function in normal adult cells situated within the complex environment of a tissue and organ system in vivo. Thus, in effect providing the in vivo equivalent of the in vitro transient transfection assay. As the widespread use of in vivo electroporation has really only just begun, it is likely that the future will hold many more applications for this technology in basic research, biotechnology and clinical research areas.

Development of a bifunctional CD1d-anti-HER2 scFv fusion molecule to redirect the iNKT cell-mediated immune response to the tumor site

Abstract : Invariant natural killer T lymphocytes (iNKT) are a unique subpopulation of T lymphocytes recognizing glycolipid antigens in the context of the MHC class I-like molecule CD1d. Upon activation with the high affinity ligand α-galactosylceramide (αGalCer), iNKT cells rapidly produce large amounts of the pro-inflammatory cytokine interferon gamma (IFN-γ) and potently activate cells of the innate and adaptive immune response, such as dendritic cells (DCs), NK and T cells. In this context, iNKT cells have been shown to efficiently mediate antitumor activity, and recent research has focused on the manipulation of these cells for antitumor therapies. However, a major drawback of αGalCer as a free drug is that a single injection of this ligand leads to a short-lived iNKT cell activation followed by a long-term anergy, limiting its therapeutic use. In contrast, we demonstrate here that when αGalCer is loaded on a recombinant soluble CD1d molecule (αGalCer/sCD1d), repeated injections lead to a sustained iNKT and NK cell activation associated with IFN-γ secretion as well as with DC maturation. Most importantly, when the αGalCer/sCD1d is fused to an anti-HER2 scFv antibody fragment, potent inhibition of experimental lung metastasis and established subcutaneous tumors is obtained when systemic treatment is started two to seven days after the injection of HER2-expressing B16 melanoma cells, whereas at this time free αGalCer has no effect. The antitumor activity of the sCD1d-anti-HER2 fusion protein is associated with HER2-specific tumor localization and accumulation of iNKT, NK and T cells at the tumor site. Importantly, active T cell immunization combined with the sCD1d-anti-HER2 treatment leads to the accumulation of antigen-specific CD8 T cells exclusively in HER2-expressing tumors, resulting in potent tumor inhibition. In conclusion, sustained activation and tumor targeting of iNKT cells by recombinant αGalCer/sCD1d molecules thus may promote a combined innate and adaptive immune response at the tumor site that may prove to be effective in cancer immunotherapy. RESUME : Les lymphocytes «invariant Natural Killer T » (iNKT) forment une sous-population particulière de lymphocytes T reconnaissant des antigènes glycolipidiques présentés sur la molécule non-polymorphique CD1d, analogue aux protéines du complexe majeur d'histocompatibilité de classe I. Après activation avec le ligand de haute affinité α-galactosylceramide (αGalCer), les cellules iNKT produisent des grandes quantités de la cytokine pro-inflammatoire interferon gamma (IFN-γ) et activent les cellules du système immunitaire inné et acquis, telles que les cellules dendritiques (DC), NK et T. En conséquence, on a montré que les cellules iNKT exercent des activités anti-tumorales et la recherche s'est intéressée à la manipulation de ces cellules pour développer des thérapies anti-tumorales. Néanmoins, le désavantage majeur de l'αGalCer, injecté seul, est qu'une seule dose de ce ligand aboutit à une activation des cellules iNKT de courte durée suivie par un état anergique prolongé, limitant l'utilisation thérapeutique de ce glycolipide. En revanche, l'étude présentée ici démontre que, si l'αGalCer est chargé sur des molécules récombinantes soluble CD1d (αGalCer/sCDld), des injections répétées aboutissent à une activation prolongée des cellules iNKT et NK associée avec la sécrétion d'IFN-γ et la maturation des cellules DC. Plus important, si on fusionne la molécule αGalCer/sCD1d avec un fragment single-chain (scFv) de l'anticorps anti-HER2, on observe une importante inhibition de métastases expérimentales aux poumons et de tumeurs sous-cutanées même lorsque le traitement systémique est commencé 2 à 7 jours après la greffe des cellules de mélanome B16 transfectées avec l'antigène HER2. Dans les mêmes conditions le traitement avec l'αGalCer seul est inefficace. L'activité anti-tumorale de la protéine sCDld-anti-HER2 est associée à son accumulation spécifique dans des tumeurs exprimant le HER2 ainsi qu'avec une accumulation des cellules iNKT, NK et T à la tumeur. De plus, une immunisation active combinée avec le traitement sCD1d-anti-HER2 aboutit à une accumulation des lymphocytes T CD8 spécifiques de l'antigène d'immunisation, ceci exclusivement dans des tumeurs qui expriment l'antigène HER2. Cette combinaison résulte dans une activité anti-tumeur accrue. En conclusion, l'activation prolongée des cellules iNKT redirigées à la tumeur par des molécules recombinantes αGalCer/sCDld conduit à l'activation de la réponse innée et adaptative au site tumoral, offrant une nouvelle stratégie prometteuse d'immunothérapie contre le cancer. RESUME POUR UN LARGE PUBLIC : Le cancer est une cause majeure de décès dans le monde. Sur un total de 58 millions de décès enregistrés au niveau mondial en 2005, 7,6 millions (soit 13%) étaient dus au cancer. Les principaux traitements de nombreux cancers sont la chirurgie, en association avec la radiothérapie et la chimiothérapie. Néanmoins, ces traitements nuisent aussi aux cellules normales de notre corps et parfois, ils ne suffisent pas pour éliminer définitivement une tumeur. L'immunothérapie est l'une des nouvelles approches pour la lutte contre le cancer et elle vise à exploiter la spécificité du système immunitaire qui peut distinguer des cellules normales et tumorales. Une cellule exprimant un marqueur tumoral (antigène) peut être reconnue par le système immunitaire humoral (anticorps) et/ou cellulaire, induisant une réponse spécifique contre la tumeur. L'immunothérapie peut s'appuyer alors sur la perfusion d'anticorps monoclonaux dirigés contre des antigènes tumoraux, par exemple les anticorps dirigés contre les protéines oncogéniques Her-2/neu dans le cancer du sein. Ces anticorps ont le grand avantage de spécifiquement se localiser à la tumeur et d'induire la lyse ou d'inhiber la prolifération des cellules tumorales exprimant l'antigène. Aujourd'hui, six anticorps monoclonaux non-conjugés sont approuvés en clinique. Cependant l'efficacité de ces anticorps contre des tumeurs solides reste limitée et les traitements sont souvent combinés avec de la chimiothérapie. L'immunothérapie spécifique peut également être cellulaire et exploiter par immunisation active le développement de lymphocytes T cytotoxiques (CTL) capables de détruire spécifiquement les cellules malignes. De telles «vaccinations »sont actuellement testées en clinique, mais jusqu'à présent elles n'ont pas abouti aux résultats satisfaisants. Pour obtenir une réponse lymphocytaire T cytotoxique antitumorale, la cellule T doit reconnaître un antigène associé à la tumeur, présenté sous forme de peptide dans un complexe majeur d'histocompatibilité de classe I (CHM I). Cependant les cellules tumorales sont peu efficace dans la présentation d'antigène, car souvent elles se caractérisent par une diminution ou une absence d'expression des molécules d'histocompatibilité de classe I, et expriment peu ou pas de molécules d'adhésion et de cytokines costimulatrices. C'est en partie pourquoi, malgré l'induction de fortes réponses CTL spécifiquement dirigés contre des antigènes tumoraux, les régressions tumorales obtenus grâce à ces vaccinations sont relativement rares. Les lymphocytes «invariant Natural Killer T » (iNKT) forment une sous-population particulière de lymphocytes T reconnaissant des antigènes glycolipidiques présentés sur la molécule non-polymorphique CD1d, analogue aux protéines CMH I. Après activation avec le ligand de haute affinité α-galactosylceramide (αGalCer), les cellules iNKT produisent des grandes quantités de la cytokine pro-inflammatoire interferon gamma (IFN-γ) et activent les cellules du système immunitaire inné et acquis, telles que les cellules dendritiques (DC), NK et T. En conséquence, on a montré que les cellules iNKT exercent des activités anti-tumorales et la recherche s'est intéressée à la manipulation de ces cellules pour développer des thérapies anti-tumorales. Néanmoins, le désavantage majeur de l'αGalCer, injecté seul, est qu'une seule dose de ce ligand aboutit à une activation des cellules iNKT de courte durée suivie par un état anergique prolongé, limitant l'utilisation thérapeutique de ce glycolipide. Notre groupe de recherche a donc eu l'idée de développer une nouvelle approche thérapeutique où la réponse immunitaire des cellules iNKT serait prolongée et redirigée vers la tumeur par des anticorps monoclonaux. Concrètement, nous avons produit des molécules récombinantes soluble CD1d (sCD1d) qui, si elles sont chargés avec l'αGalCer (αGalCer/sCDld), aboutissent à une activation prolongée des cellules iNKT et NK associée avec la sécrétion d'IFN-γ et la maturation des cellules DC. Plus important, si la molécule αGalCer/sCD1d est fusionnée avec un fragment single-chain (scFv) de l'anticorps anti-HER2, la réponse immunitaire est redirigée à la tumeur pour autant que les cellules cancéreuses expriment l'antigène HER2. Les molécules αGalCer/sCDld ainsi présentées activent les lymphocytes iNKT. Avec cette stratégie, on observe une importante inhibition de métastases expérimentales aux poumons et de tumeurs sous-cutanées, même lorsque le traitement systémique est commencé 2 à 7 jours après la greffe des cellules de mélanome B16 transfectées avec l'antigène HER2. Dans les mêmes conditions le traitement avec l'αGalCer seul est inefficace. L'activité anti-tumorale de la protéine sCDld-anti-HER2 est associée à son accumulation spécifique dans des tumeurs exprimant le HER2 ainsi qu'avec une accumulation des cellules iNKT, NK et T à la tumeur. En conclusion, l'activation prolongée des cellules iNKT redirigées à la tumeur par des molécules récombinantes αGalCer/sCD1d conduit à l'activation de la réponse innée et adaptative au site tumoral, offrant une nouvelle stratégie prometteuse d'immunothérapie contre le cancer.

Régulation du processus métastatique tumoral par l'oxyde nitrique (NO), le TGF-β el les cellules de l'hôte

RESUME Nous avons étudié le rôle de deux molécules, le Transfon-ning Growth Factor (TGF-β) et l'oxyde nitrique (NO), dans le processus métastatique. Deux clones tumoraux ont été sélectionnés à partir d'un carcinome du côlon pour leur différence de potentiel tumorigénique dans des rats syngéniques. La croissance tumorale du clone progressif PROb a été corrélée à sa capacité à sécréter le TGF-β actif Cependant, la transfection du clone régressif REGb, sécrétant du TGF-β latent, par une vecteur codant pour le TGF-β bio-actif n'a pas permis d'induire le développement tumoral. Les deux clones tumoraux présentent des activités des protéases MMP-2, APN et DPPIV identiques et qui ne semblent pas modifiées par le TGF-β. L'interaction des cellules tumorales avec l'endothélium et l'activité de la NO synthase (iNOS) responsable de la synthèse de NO sont impliqués dans la progression de nombreux cancers. Le clone PROb, mais pas le clone REGb, inhibe l'activation de la iNOS des cellules endothéliales par sa sécrétion de TGF-β actif Les deux clones montrent cependant des propriétés d'adhésion identiques aux cellules endothéliales et sont capables d'inhiber par contact cellulaire direct l'activation de la iNOS endothéliale. Ceci suggère que ces contacts directs pourraient créer un micro-environnement favorable à la conversion du TGF-β latent en TGF-β actif ou à d'autres interactions moléculaires pouvant réguler l'activation endothéliale. Par ailleurs, les deux clones activent des macrophages du système nerveux central, organe où ils ne forment pas de métastases, mais pas les macrophages circulants, illustrant des mécanismes différentiels et spécifiques dans l'activation de différents types de cellules immunitaires. Afin de mieux comprendre le rôle du NO dans la dissémination métastatique, deux clones cellulaires différant par le taux d'activité de la iNOS ont été sélectionnés à partir de la lignée murine parentale de carcinome du sein EMT-6. Bien que le NO soit un inhibiteur potentiel de la prolifération cellulaire, les deux clones montrent des propriétés prolifératives identiques in vitro. Les cellules EMT-6H qui produisent peu de NO in vitro forment de nombreux nodules tumoraux pulmonaires in vivo corrélés à une mortalité significative des souris syngéniques injectées. Les cellules EMT-6J qui présentent une expression élevée de iNOS et de NO induisent de rares nodules tumoraux pulmonaires et peu de mortalité. Dans ce modèle, l'expression tumorale de NO semble donc défavoriser la croissance tumorale. Les deux clones cellulaires ont des propriétés identiques d'adhésion et de prolifération mesurées in vitro sur des cellules endothéliales primaires isolées de différents organes et in vivo par une colocalisation identique dans les poumons de souris syngéniques 48h après leur injection. Les cellules EMT-6H présentent une activité MMP-2 plus élevée alors que les activités des protéases APN et DPPIV sont identiques dans les deux clones cellulaires. Le TGF-β soluble ainsi que les fibroblastes primaires bloquent la prolifération des deux clones cellulaires. Cependant, l'activation préalable des fibroblastes par du TGF-β restaure partiellement la prolifération du clone EMT-6H mais pas celle du clone EMT-6J. Ces résultats montrent que le rôle de molécules telles que le TGF-β et le NO tumoral dans la progression tumorale doit être considéré dans un contexte d'interactions des cellules tumorales avec les différentes types cellulaires de l'hôte: en particulier, notre travail souligne que les macrophages et les fibroblastes sont déterminants dans la progression métastatique des carcinomes du côlon ou du sein. RESUME DESTINE A UN LARGE PUBLIC Les métastases tumorales, disséminées et intraitables par chirurgie, représentent un problème majeur dans le traitement clinique du cancer. Elles sont dues à des cellules tumorales qui ont migré de leur site tumoral primaire, circulé et survécu dans le système vasculaire de l'hôte, échappé au système immunitaire, adhéré à et survécu sur l'endothélium des vaisseaux, et envahi le tissu sous-jacent où elles ont proliféré. Cette capacité à former des métastases implique de nombreux facteurs dont certains ont été identifiés mais dont le rôle reste controversé dans les différentes études. Nous nous sommes intéressés au rôle de l'oxyde nitrique (NO) et du facteur de croissance et de transformation cellulaire TGF-β. Dans les carcinomes du sein, l'expression des enzymes responsables de la synthèse de NO a été corrélée avec l'invasion tumorale mais aussi avec un pronostic favorable selon les études. Deux clones cellulaires ont été isolés à partir de la tumeur mammaire EMT-6 chez la souris. Le clone EMT-6H sécrète peu de NO et forme de nombreuses tumeurs dans les poumons des souris *entraînant leur décès. Le clone EMT-6J sécrète beaucoup de NO et ne se développe que peu dans les poumons. Dans ce modèle expérimental, le NO semble donc défavoriser la croissance tumorale. L'analyse des interactions avec les cellules de l'hôte rencontrées lors de la formation de métastases pulmonaires a montré que les deux clones cellulaires adhérent et prolifèrent de manière similaire sur les cellules endothéliales tapissant l'intérieur des vaisseaux sanguins. L'arrêt des cellules tumorales dans les poumons ne permet donc pas d'expliquer la différence de croissance tumorale. Cependant, le clone agressif EMT-6H présente une activité élevée d'une protéase (MMP-2) qui lui permettrait par la suite d'envahir le tissu pulmonaire. Par ailleurs, l'activation des fibroblastes du tissu pulmonaire par le TGF-β, une molécule observée dans des conditions inflammatoires, permet au clone agressif EMT-6H de proliférer mais inhibe la croissance du clone EMT-6J. Dans un modèle expérimental de carcinome du côlon, le TGF-β est considéré favorable à la croissance tumorale. Isolées à partir de la même tumeur initiale, deux lignées de cellules ont des comportements opposés lorsqu'elles sont injectées sous la peau des rats. La capacité de la lignée PROb à former des tumeurs a été corrélée à la sécrétion de TGF-β actif L'introduction du gène codant pour le TGF-β actif dans la lignée REGb, qui ne sécrète pas de TGF-β actif et ne forme pas de tumeurs chez le rat, ne restaure pas leur potentiel tumorigénique. Dans ce modèle, l'expression de TGF-β actif ne semble donc pas suffisante à la croissance tumorale. Les interactions avec différents types cellulaires de l'hôte ont été étudiées. Les deux lignées tumorales adhérent de manière similaire sur les cellules endothéliales et sont capables d'inhiber leur activation, un mécanisme qui pourrait participer à la destruction. Les deux lignées activent les cellules immunitaires du système nerveux central, un organe où elles ne forment pas de métastase. Ces résultats suggèrent que la sélection des cellules métastatiques ne s'effectue pas sur l'endothélium des vaisseaux sanguins mais à des étapes ultérieures dans le micro- environnement cellulaire du nouvel organe colonisé. SUMMARY Metastasis results from the migration of tumor cells from their primary tumor, circulation through the bloodstream, attachment to the endothelium, and invasion of the surrounding tissue where they create a microenvironnement favoring their growth. This multistep process implies various cellular interactions and molecules. Among those, we were interested in the role of the Transforming Growth Factor beta (TGF-β) and the nitric oxide (NO). Two cell lines were isolated from a rat colon tumor and assessed for their metastatic potential in vivo. The PROb cell line that expresses active TGF-β formed subcutaneous tumors in rats while the REGb cell line that expresses only latent TGF-β did not. Transfection of REGb cells with a plasmid encoding for the active form of TGF-β failed to restore their metastatic ability. Thus TGF-β secretion is not sufficient to induce colon carcinoma progression. Activities of various proteases such as APN, DPPIV and MMP were similar in both cell lines and were not regulated by TGF-β. Interactions with the endothelium as well as NO synthase activity (iNOS) and local NO concentrations are believed to be crucial steps in cancer metastasis. Coculture of the two clones with endothelial cells inhibited the cytokine-triggered activation of the iNOS enzyme in primary rat endothelial cells but only PROb cells were capable of increasing the expression of IL-6, a protumoral interleukin that may participate in the impairment of the anti-tumoral immune response of the host. Both cell lines exhibited potential to activate microglial cells but not bone marrow-derived macrophages, pointing to a differential regulation of specialized immune cells. To better understand the conflicting role of NO in breast cancer progression, two cell clones were selected from the murine tumorigenic cell line EMT-6 based on their iNOS activity and NO secretion. Although NO has been shown to inhibit cell proliferation, the two cell clones exhibited similar proliferation rates in vitro. The EMT-6H cells expressed little NO and grew actively in the lungs of syngenic mice, leading to their death. Opposite results were observed with the EMT-6J cells. In these in vivo conditions, NO seems to impair tumor growth. Both clones exhibited similar in vitro adhesive properties to primary endothelial cells isolated from various mouse organs and similar localization in the lungs of mice 48 hours after injection. Sustained metalloproteinase MMP-2 activity was detected in the tumorigenic EMT-6H clone, but not in the EMT-6J cells while other proteases such as APN and DPPIV showed no difference. These results suggested that the two clones differed in invasion steps following adhesion to the endothelium and that NO did not participate in previous steps. Consistent with this, both soluble TGF-β and supernatants of cultures of mouse primary lung fibroblasts inhibited the growth of the two clones. However, previous activation of these fibroblasts with TGF-β restored the growth of the tumorigenic EMT-6H cells, but not of EMT-6J cells. Altogether, these results indicate that the role of a given molecule, such as NO or TGF-β, must be considered in a context of interaction of tumor cells with host cells. They further imply that interaction of tumor cells with specialized immune cells and with stromal cells of the colonized organ, rather than with the endothelium, are critical in regulating metastasis.

Effect of RasGAP N2 fragment-derived peptide on tumor growth in mice.

Peptides that interfere with the natural resistance of cancer cells to genotoxin-induced apoptosis may improve the efficacy of anticancer regimens. We have previously reported that a cell-permeable RasGAP-derived peptide (TAT-RasGAP(317-326)) specifically sensitizes tumor cells to genotoxin-induced apoptosis in vitro. Here, we examined the in vivo stability of a protease-resistant D-form of the peptide, RI.TAT-RasGAP(317-326), and its effect on tumor growth in nude mice bearing subcutaneous human colon cancer HCT116 xenograft tumors. After intraperitoneal injection, RI.TAT-RasGAP(317-326) persisted in the blood of nude mice for more than 1 hour and was detectable in various tissues and subcutaneous tumors. Tumor-bearing mice treated daily for 7 days with RI.TAT-RasGAP(317-326) (1.65 mg/kg body weight) and cisplatin (0.5 mg/kg body weight) or doxorubicin (0.25 mg/kg body weight) displayed reduced tumor growth compared with those treated with either genotoxin alone (n = 5-7 mice per group; P = .004 and P = .005, respectively; repeated measures analysis of variance [ANOVA, two-sided]). This ability of the RI.TAT-RasGAP(317-326) peptide to enhance the tumor growth inhibitory effect of cisplatin was still observed at peptide doses that were at least 150-fold lower than the dose lethal to 50% of mice. These findings provide the proof of principle that RI.TAT-RasGAP(317-326) may be useful for improving the efficacy of chemotherapy in patients.

The Natural Cell-Penetrating Peptide Crotamine Targets Tumor Tissue in Vivo and Triggers a Lethal Calcium-Dependent Pathway in Cultured Cells

Our goal was to demonstrate the in vivo tumor specific accumulation of crotamine, a natural peptide from the venom of the South American rattlesnake Crotalus durissus terrificus, which has been characterized by our group as a cell penetrating peptide with a high specificity for actively proliferating cells and with a concentration-dependent cytotoxic effect. Crotamine cytotoxicity has been shown to be dependent on the disruption of lysosomes and subsequent activation of intracellular proteases. In this work, we show that the cytotoxic effect of crotamine also involves rapid intracellular calcium release and loss of mitochondrial membrane potential as observed in real time by confocal microscopy. The intracellular calcium overload induced by crotamine was almost completely blocked by thapsigargin. Microfluorimetry assays confirmed the importance of internal organelles, such as lysosomes and the endoplasmic reticulum, as contributors for the intracellular calcium increase, as well as the extracellular medium. Finally, we demonstrate here that crotamine injected intraperitoneally can efficiently target remote subcutaneous tumors engrafted in nude mice, as demonstrated by a noninvasive optical imaging procedure that permits in vivo real-time monitoring of crotamine uptake into tumor tissue. Taken together, our data indicate that the cytotoxic peptide crotamine can be used potentially for a dual purpose: to target and detect growing tumor tissues and to selectively trigger tumor cell death.

The role of nitric oxide in apoptosis and cancer metastasis

The purpose of these studies was to investigate the role of nitric oxide (NO) in tumor metastasis. K-1735 Metastatic cells survived in blood circulation to produce experimental lung metastases, whereas nonmetastatic cells did not. After incubation with combination cytokines or lipopolysaccharide (LPS), nonmetastatic cells exhibited high levels of inducible nitric oxide synthase (iNOS) activity and NO production, whereas metastatic cells did not. The production of NO directly correlated with cytotoxic effects of cytokines or LPS. To provide direct evidence for the inverse correlation between the production of endogenous NO and the ability of K-1735 cells to survive in syngeneic mice to produce lung metastases, highly metastatic K-1735 clone 4 cells (C4.P), which express low levels of iNOS, were transfected with a functional iNOS (C4.L8), inactive-mutated iNOS (C4.S2), or neomycin-resistance (C4.Neo) genes in medium containing 3 mM NMA. C4.P, C4.Neo.3, and C4.S2.3 cells were highly metastatic whereas C4.L8.5 cells were not metastatic. The C4.L8.5 cells produced slow growing subcutaneous tumors in nude mice, whereas the other three lines produced fast growing tumors. In vitro studies indicated that the expression of iNOS in C4.L8.5 cells induced apoptosis. Collectively, these data demonstrate that the expression of recombinant iNOS in melanoma cells is associated with apoptosis, suppression of tumorigenicity, and abrogation of metastasis.^ Furthermore, multiple systemic administrations of multilamellar vesicle-liposomes (MLV) containing the lipopeptide CGP 31362 (MLV-31362) or MLV-31362 combined with murine interferon-gamma (IFN-$\gamma$) eradicated the metastases by M5076 reticular cell sarcoma. Tumor regression correlated with iNOS expression within the tumor lesions and with increased NO production. The administration of NMA significantly decreased NO production and diminished the antitumor activities. These data imply that the activation of iNOS can serve as a target for immunotherapeutic agents for treatment of murine reticulum cell sarcoma metastases. ^

Radiolabeled human monoclonal IgM for intracompartmental cancer therapy

Radioimmunotherapy (RIT) with i.v. administered radiolabeled IgG can selectively irradiate tumor cells in vivo. However, it only provides effective therapy for lymphomas. Intracompartmental RIT with radiolabeled human monoclonal IgM may allow curative treatment of solid tumors by increasing tumor deposition of radioactivity, reducing systemic toxicity and allowing repeated administration. This hypothesis was tested in nude mouse models with IgM radiolabeled with indium-111 $\rm(\sp{111}In)$ or yttrium-90 $\rm(\sp{90}Y).$ The use of two radioisotopes, $\rm\sp{111}In$ for imaging and $\rm\sp{90}Y$ for therapy, allow for more quantitative and cautious development of RIT.^ Radiolabled 2B12, an IgM reactive with human ovarian carcinomas was tested by i.v. and intraperitoneal (i.p.) administration in nude mice bearing i.p. nodules of a human ovarian carcinoma cell line (SKOV3 NMP2). Radiolabeled CR4E8, an IgM reactive with human squamous cell carcinomas was tested by i.v. and intralesional (i.l.) administration in nude mice bearing subcutaneous tumors of a human head and neck squamous cell carcinoma cell line (886). These two models were selected to test proof of concept. Radiolabeled irrelevant IgM (CH-1B9), and $\rm\sp{90}Y$-aggregate served as specificity controls. Biodistribution was performed by excising, weighing and then measuring the radioactivity of tumor and normal organs. Therapy was conducted with i.p. $\rm\sp{90}Y$-labeled 2B12 using both single and fractionated administration and with i.l. $\rm\sp{90}Y$-labeled CR4E8 using single administration. Mice were monitored for tumor response, survival and systemic toxicity.^ Intracompartmental administration of radiolabeled IgM produced immediate high and prolonged tumor deposition of radioactivity with low normal tissue uptake. In contrast, i.v. administration resulted in low tumor, but high liver and spleen uptake. Similar biodistributions were demonstrated for $\rm\sp{111}In$- and $\rm\sp{90}Y$-labeled IgM. Intraperitoneal therapy with $\rm\sp{90}Y$-labeled 2B12 increased survival by approximately 12 days for every 100 $\rm\mu Ci$ of activity without significant toxicity for single (0-300 $\rm\mu Ci)$ and fractionated (150-510 $\rm\mu Ci)$ administration. Intralesional therapy with $\rm\sp{90}Y$-labeled CR4E8 (150-400 $\rm\mu Ci)$ induced prolonged complete regressions. Significant local or systemic toxicity was not observed.^ Intracompartmental RIT with radiolabeled tumor-reactive human monoclonal IgM can selectively irradiate tumor cells. Intracompartmental radiolabled IgM can significantly extend the survival of treated mice with minimal toxicity. It deserves further development as a new cancer therapy. ^

Characterization of tumor-associated Foxp3+ regulatory T cells and de-novo induction by the tumor microenvironment

Regulatory T cells expressing the fork-head box transcription factor 3 (Foxp3) play a central role in the dominant control of immunological tolerance. Compelling evidence obtained from both animal and clinical studies have now linked the expansion and accumulation of Foxp3+ regulatory T cells associated with tumor lesions to the failure of immune-mediated tumor rejection. However, further progress of the field is hampered by the gap of knowledge regarding their phenotypic, functional, and the developmental origins in which these tumor-associated Foxp3+ regulatory T cells are derived. Here, we have characterized the general properties of tumor-associated Foxp3+ regulatory T cells and addressed the issue of tumor microenvironment mediated de-novo induction by utilizing a well known murine tumor model MCA-205 in combination with our BAC Foxp3-GFP reporter mice and OT-II TCR transgenic mice on the RAG deficient background (RAG OT-II). De-novo induction defines a distinct mechanism of converting non-regulatory precursor cells to Foxp3+ regulatory T cells in the periphery as opposed to the expansion of pre-existing regulatory T cells formed naturally during thymic T cell development. This mechanism is of particularly importance to how tumors induce tumor-antigen-specific suppressor cells to subvert anti-tumor immune responses. Our study has found that tumor-associated Foxp3+ regulatory T cells are highly activated, undergo vigorous proliferation, are more potent by in-vitro suppression assays, and express higher levels of membrane-bound TGF-β1 than non-tumor regulatory T cells. With Foxp3-GFP reporter mice or RAG OT-II TCR transgenic mice, we show that tumor tissue can induce detectable de-novo generation of Foxp3+ regulatory T cells of both polyclonal or antigen specific naïve T cells. This process was not only limited for subcutaneous tumors but for lung tumors as well. Furthermore, this process required the inducing antigen to be co-localized within the tumor tissue. Examination of tumor tissue revealed an abundance of myeloid CD11b+ antigen-presenting cells that were capable of inducing Foxp3+ regulatory T cells. Taken together, these findings elucidate the general attributes and origins of tumor-associated Foxp3+ regulatory T cells in the tumor microenvironment and in their role in the negative regulation of tumor immunity.^

Regulation of transport pathways in tumor vessels: Role of tumor type and microenvironment

Novel anti-neoplastic agents such as gene targeting vectors and encapsulated carriers are quite large (approximately 100–300 nm in diameter). An understanding of the functional size and physiological regulation of transvascular pathways is necessary to optimize delivery of these agents. Here we analyze the functional limits of transvascular transport and its modulation by the microenvironment. One human and five murine tumors including mammary and colorectal carcinomas, hepatoma, glioma, and sarcoma were implanted in the dorsal skin-fold chamber or cranial window, and the pore cutoff size, a functional measure of transvascular gap size, was determined. The microenvironment was modulated: (i) spatially, by growing tumors in subcutaneous or cranial locations and (ii) temporally, by inducing vascular regression in hormone-dependent tumors. Tumors grown subcutaneously exhibited a characteristic pore cutoff size ranging from 200 nm to 1.2 μm. This pore cutoff size was reduced in tumors grown in the cranium or in regressing tumors after hormone withdrawal. Vessels induced in basic fibroblast growth factor-containing gels had a pore cutoff size of 200 nm. Albumin permeability was independent of pore cutoff size. These results have three major implications for the delivery of therapeutic agents: (i) delivery may be less efficient in cranial tumors than in subcutaneous tumors, (ii) delivery may be reduced during tumor regression induced by hormonal ablation, and (iii) permeability to a molecule is independent of pore cutoff size as long as the diameter of the molecule is much less than the pore diameter.

Melanoma angiogenesis and metastasis modulated by ribozyme targeting of the secreted growth factor pleiotrophin

Clinical and experimental evidence suggests that spreading of malignant cells from a localized tumor (metastasis) is directly related to the number of microvessels in the primary tumor. This tumor angiogenesis is thought to be mediated by tumor-cell-derived growth factors. However, most tumor cells express a multitude of candidate angiogenesis factors and it is difficult to decipher which of these are rate-limiting factors in vivo. Herein we use ribozyme targeting of pleiotrophin (PTN) in metastatic human melanoma cells to assess the significance of this secreted growth factor for angiogenesis and metastasis. As a model we used human melanoma cells (1205LU) that express high levels of PTN and metastasize from subcutaneous tumors to the lungs of experimental animals. In these melanoma cells, we reduced PTN mRNA and growth factor activity by transfection with PTN-targeted ribozymes and generated cell lines expressing different levels of PTN. We found that the reduction of PTN does not affect growth of the melanoma cells in vitro. In nude mice, however, tumor growth and angiogenesis were decreased in parallel with the reduced PTN levels and apoptosis in the tumors was increased. Concomitantly, the metastatic spread of the tumors from the subcutaneous site to the lungs was prevented. These studies support a direct link between tumor angiogenesis and metastasis through a secreted growth factor and identify PTN as a candidate factor that may be rate-limiting for human melanoma metastasis.

Tissue-specific expression of herpes simplex virus thymidine kinase gene delivered by adeno-associated virus inhibits the growth of human hepatocellular carcinoma in athymic mice

About 70% of hepatocellular carcinomas are known to express α-fetoprotein, which is normally expressed in fetal but not in adult livers. To induce herpes simplex virus-thymidine kinase expression in these cancer cells, we constructed an adeno-associated viral vector containing the HSV-TK gene under the control of the α-fetoprotein enhancer and albumin promoter. We previously demonstrated in vitro that although this vector can transduce a variety of human cells, only transduced AFP and albumin-expressing hepatocellular carcinoma cell lines were sensitive to killing by ganciclovir (GCV). In the present study, we explored the effect of this vector on hepatocellular carcinoma cells in vivo. Subcutaneous tumors generated in nude mice by implanting hepatocellular carcinoma cells previously transduced with this vector shrank dramatically after treatment with GCV. Bystander effect was also observed on the tumors generated by mixing transduced and untransduced cells. To test whether the tumor cells can be transduced by the virus in vivo, we injected the recombinant adeno-associated virus into tumors generated by untransduced hepatocarcinoma cell line. Tumor growth were retarded after treatment with GCV. These experiments demonstrate the feasibility of in vivo transduction of tumor cell with rAAV.

An antibody-interleukin 2 fusion protein overcomes tumor heterogeneity by induction of a cellular immune response.

Antibody-based therapies for cancer rely on the expression of defined antigens on neoplastic cells. However, most tumors display heterogeneity in the expression of such antigens. We demonstrate here that antibody-targeted interleukin 2 delivery overcomes this problem by induction of a host immune response. Immunohistochemical analysis demonstrated that the antibody-interleukin 2 fusion protein-induced eradication of established tumors is mediated by host immune cells, particularly CD8+ T cells. Because of this cellular immune response, antibody-directed interleukin 2 therapy is capable to address established metastases displaying substantial heterogeneity in expression of the targeted antigen. This effector mechanism further enables the induction of partial regressions of large subcutaneous tumors that exceeded more than 5% of the body weight. These observations indicate that antibody-directed cytokine delivery offers an effective new tool for cancer therapy.