Liposomes targeting tumour stromal cells

Abstract

Liposomes have found clinical application in cancer therapy in the delivery of cytostatic agents. As a result of the targeted delivery of these toxic molecules to the tumour cells coupled to avoidance of toxicity-sensitive tissues, the therapeutic window is widened. Over the past years the focus of cancer therapy has shifted towards the stromal cells that are present in the tumour. It appears that clinically relevant tumours have acquired the ability to modulate the microenvironment in such a way that a chronic pro-inflammatory and pro-angiogenic state is achieved that contributes to invasion and metastasis and continued proliferation. Over the past years, liposomal formulations have been designed that target key stromal cell types that contribute to tumour growth. At the same time, many promising cell types have not been targeted yet and most of the studies employ drugs that aim at depleting stromal cells rather than modulating their activity towards an anti-tumour phenotype. In this review these target cell types will be addressed. Complementing these targeted formulations with the appropriate drugs to optimally suppress tumour-promoting signals while preserving anti-tumour action will be the challenge for the future.     

Carbon nanotubes in cancer diagnosis and therapy

During the past years, great progress has been made in the field of nanomaterials given their great potential in biomedical applications. Carbon nanotubes (CNTs), due to their unique physicochemical properties, have become a popular tool in cancer diagnosis and therapy. They are considered one of the most promising nanomaterials with the capability of both detecting the cancerous cells and delivering drugs or small therapeutic molecules to these cells. Over the last several years, CNTs have been explored in almost every single cancer treatment modality, including drug delivery, lymphatic targeted chemotherapy, thermal therapy, photodynamic therapy, and gene therapy. In this review, we will show how they have been introduced into the diagnosis and treatment of cancer. Novel SWNT-based tumor-targeted drug delivery systems (DDS) will be highlighted. Furthermore, the in vitro and in vivo toxicity of CNTs reported in recent years will be summarized.     

Nano-biotechnology in tumour and cancerous disease: A perspective review

In recent years, drug manufacturers and researchers have begun to consider the nanobiotechnology approach to improve the drug delivery system for tumour and cancer diseases. In this article, we review current strategies to improve tumour and cancer drug delivery, which mainly focuses on sustaining biocompatibility, biodistribution, and active targeting. The conventional therapy using cornerstone drugs such as fludarabine, cisplatin etoposide, and paclitaxel has its own challenges especially not being able to discriminate between tumour versus normal cells which eventually led to toxicity and side effects in the patients. In contrast to the conventional approach, nanoparticle-based drug delivery provides target-specific delivery and controlled release of the drug, which provides a better therapeutic window for treatment options by focusing on the eradication of diseased cells via active targeting and sparing normal cells via passive targeting. Additionally, treatment of tumours associated with the brain is hampered by the impermeability of the blood–brain barriers to the drugs, which eventually led to poor survival in the patients. Nanoparticle-based therapy offers superior delivery of drugs to the target by breaching the blood–brain barriers. Herein, we provide an overview of the properties of nanoparticles that are crucial for nanotechnology applications. We address the potential future applications of nanobiotechnology targeting specific or desired areas. In particular, the use of nanomaterials, biostructures, and drug delivery methods for the targeted treatment of tumours and cancer are explored.     

Epigenetic cancer therapy: Proof of concept and remaining challenges

Over the past few years several drugs that target epigenetic modifications have shown clinical benefits, thus seemingly validating epigenetic cancer therapy. More recently, however, it has become clear that these drugs are either characterized by low specificity or that their target enzymes have low substrate specificity. As such, clinical proof-of-concept for epigenetic cancer therapies remains to be established. Human cancers are characterized by widespread changes in their genomic DNA methylation and histone modification patterns. Epigenetic cancer therapy aims to restore normal epigenetic modification patterns through the inhibition of epigenetic modifier enzymes. In this review, we provide an overview about the known functional roles of DNA methyltransferases, histone deacetylases, histone methyltransferases, and demethylases in cancer development. The available data identify several examples that warrant further consideration as drug targets. Future research should be directed toward targeted enzyme inhibition and toward exploring interactions between epigenetic pathways to maximize cancer specificity.     

Gene therapy for cancer and metastatic disease

Gene therapy has been applied to the treatment of cancer and metastatic disease for over ten years. Research in this area has utilised multiple gene therapy approaches including targeting tumour suppressor genes and oncogenes, stimulating the immune system, targeted chemotherapy, antiangiogenic strategies, and direct viral oncolysis. In recent years, gene delivery vectors have been developed that selectively target tumour cells through tumour-specific receptors, deletion of certain viral gene sequences, or incorporation of tumour-specific promoter sequences that drive gene expression. Preclinical models have produced promising results, demonstrating significant tumour regression and reduction of metastatic disease. Unfortunately, only limited responses have been observed in clinical trials. The main limitations in treating metastatic disease include poor vector transduction efficiencies and difficulties in targeting remote tumour cells with systemic vector delivery. Currently, various groups are investigating means to improve gene delivery and clinical responses by continuing to modify gene delivery vectors and by concentrating on combination gene therapy and multimodality therapy.     

E phage gene transfection associated to chemotherapeutic agents increases apoptosis in lung and colon cancer cells

The limited ability of conventional therapies to achieve the long-term survival of metastatic lung and colon cancer patients suggests the need for new treatment options. In this respect, genes encoding cytotoxic proteins have been proposed as a new strategy to enhance the activity of drugs, and combined therapies involving such genes and classical antitumoral drugs have been studied intensively. The E gene from phiX174 encodes a membrane protein with a toxic domain that leads to a decrease in tumour cell growth rates. Therefore, in order to improve the anti-tumour effects of currently used chemotherapeutic drugs on cancer cells, we investigated the association of the E suicide gene with these antineoplastic drugs. The E gene has antitumoral effects in both lung and colon cancer cells. In addition, expression of this gene induces ultrastructural changes in lung cancer transfected cells (A-549), although the significance of these changes remains unknown. The effect of combined therapy (gene and cytotoxic therapy) enhances the inhibition of tumour cell proliferation in comparison to single treatments. Indeed, our in vitro results indicate that an experimental therapeutic strategy based on this combination of E gene therapy and cytotoxic drugs may result in a new treatment strategy for patients with advanced lung and colon cancer.     

Matrix metalloproteinases in cancer: from new functions to improved inhibition strategies

Over the last years, the relevance of the matrix metalloproteinase (MMP) family in cancer research has grown considerably. These enzymes were initially associated with the invasive properties of tumour cells, owing to their ability to degrade all major protein components of the extracellular matrix (ECM) and basement membranes. However, further studies have demonstrated the implication of MMPs in early steps of tumour evolution, including stimulation of cell proliferation and modulation of angiogenesis. The establishment of causal relationships between MMP overproduction in tumour or stromal cells and cancer progression has prompted the development of clinical trials with a series of inhibitors designed to block the proteolytic activity of these enzymes. Unfortunately, the results derived from using broad-spectrum MMP inhibitors (MMPIs) for treating patients with advanced cancer have been disappointing in most cases. There are several putative explanations for the lack of success of these MMPIs including the recent finding that some MMPs may play a paradoxical protective role in tumour progression. These observations together with the identification of novel functions for MMPs in early stages of cancer have made necessary a reformulation of MMP inhibition strategies. A better understanding of the functional complexity of this proteolytic system and global approaches to identify the relevant MMPs which must be targeted in each individual cancer patient, will be necessary to clarify whether MMP inhibition may be part of future therapies against cancer.     

Antibodies targeting cancer stem cells: A new paradigm in immunotherapy?

Antibody targeting of cancer is showing clinical and commercial success after much intense research and development over the last 30 years. They still have the potential to delivery long-term cures but a shift in thinking towards a cancer stem cell (CSC) model for tumour development is certain to impact on how antibodies are selected and developed, the targets they bind to and the drugs used in combination with them. CSCs have been identified from many human tumours and share many of the characteristics of normal stem cells. The ability to renew, metabolically or physically protect themselves from xenobiotics and DNA damage and the range of locomotory-related receptors expressed could explain the observations of drug resistance and radiation insensitivity leading to metastasis and patient relapse.

Targeting CSCs could be a strategy to improve the outcome of cancer therapy but this is not as simple as it seems. Targets such as CD133 and EpCAM/ESA could mark out CSCs from normal cells enabling specific intervention but indirect strategies such as interfering with the establishment of a supportive niche through anti-angiogenic or anti-stroma therapy could be more effective.

This review will outline the recent discoveries for CSCs across the major tumour types highlighting the possible molecules for intervention. Examples of antibody-directed CSC therapies will be given and the outlook for the future development of this emerging area will be given.     

Progress in the application of exosomes as therapeutic vectors in tumor-targeted therapy

Cancer is the second leading cause of death in the world with a high annual incidence level. Researchers have been working on developing treatments for cancer. Targeted therapy is an emerging treatment modality that is more novel than surgery, radiotherapy and chemotherapy. In targeted therapy, exogenous nanoscale microparticles are applied as carriers for drugs or genes. However, conventional particles have certain limitations attributed to non-specific cytotoxicity, biocompatibility and low delivery efficacy in individual therapeutic vector systems. Exosomes are small vesicles secreted by various cells that consist of lipid bilayer membranes without organelles. Due to their excellent biocompatibility, exosomes have received increased attention in recent years for targeted therapy applications. This review briefly introduces the current status of targeted therapy, and exosomes are introduced by their structural characteristics, physiological effects and separation methods. This review also discusses the applications of engineered exosomes derived from different cells in the field of targeted therapies and compares the two-way regulation of mesenchymal stromal cell–derived exosomes in tumor therapy.     

Bacterially-Derived Nanocells for Tumor-Targeted Delivery of Chemotherapeutics and Cell Cycle Inhibitors

Chemotherapeutic drug therapy in cancer is seriously hampered by severe toxicity primarily due to indiscriminate drug distribution and consequent collateral damage to normal cells. Molecularly targeted drugs such as cell cycle inhibitors are being developed to achieve a higher degree of tumor cell specificity and reduce toxic side effects. Unfortunately, relative to the cytotoxics, many of the molecularly targeted drugs are less potent and the target protein is expressed only at certain stages of the cell cycle thus necessitating regimens like continuous infusion therapy to arrest a significant number of tumor cells in a heterogeneous tumor mass. Here we discuss targeted drug delivery nanovectors and a recently reported bacterially-derived 400nm sized minicell that can be packaged with therapeutically significant concentrations of chemotherapeutic drugs, targeted to tumor cell surface receptors and effect intracellular drug delivery with highly significant anti-tumor effects in-vivo. We also report that molecularly targeted drugs can also be packaged in minicells and targeted to tumor cells with highly significant tumor growth-inhibition and regression in mouse xenografts despite administration of minute amounts of drug. This targeted intracellular drug delivery may overcome many of the hurdles associated with the delivery of cytotoxic and molecularly targeted drugs.     

CAR T cells transform to trucks: chimeric antigen receptor–redirected T cells engineered to deliver inducible IL-12 modulate the tumour stroma to combat cancer

Adoptive T cell therapy recently achieved impressive efficacy in early-phase clinical trials; this significantly raises the profile of immunotherapy in the fight against cancer. A broad variety of tumour cells can specifically be targeted by patients' T cells, which are redirected in an antibody-defined, major histocompatibility complex-unrestricted fashion by endowing them with a chimeric antigen receptor (CAR). Despite promising results for some haematologic malignancies, the stroma of large, established tumours, the broad plethora of infiltrating repressor cells, and cancer cell variants that had lost the target antigen limit their therapeutic efficacy in the long term. This article reviews a newly described strategy for overcoming some of these shortcomings by engineering CAR T cells with inducible or constitutive release of IL-12. Once redirected, these T cells are activated, and released IL-12 accumulates in the tumour lesion where it promotes tumour destruction by at least two mechanisms: (1) induction of an innate immune cell response towards those cancer cells which are invisible to redirected T cells and (2) triggering programmatic changes in immune-suppressive cells. Given the enormous complexity of both tumour progression and immune attack, the upcoming strategies using CAR-redirected T cells for local delivery of immune-modulating payloads exhibited remarkable efficacy in pre-clinical models, suggesting their evaluation in clinical trials.     

Metastatic cancer stem cells: A new target for anti-cancer therapy?

Over the past few years, supporting evidence for the cancer stem cell hypothesis has been provided for an increasing number of tumor entities. According to this hypothesis, only a small population of undifferentiated cells with stem cell characteristics has the ability to form tumors through asymmetric division and subsequent differentiation of the progeny into the heterogeneous cell types that comprise a tumor. Recently, we were able to show that cancer stem cells are not only responsible for tumorigenesis, but that they contain a subpopulation characterized by CXCR4 expression which is exclusively capable of disseminating and subsequently providing the substrate for tumor metastasis. Of note, these recent advances in our understanding of cancer stem cell biology raise more questions than they answer. Some of these arising questions regarding the targeted elimination of these cancer stem cells will be addressed in this perspective.     

Investigation of parameters influencing incorporation,retention and cellular cytotoxicity in liposomal formulations of poorly soluble camptothecin

Abstract

Improving tumor delivery of lipophilic drugs through identifying advanced drug carrier systems with efficient carrier potency is of high importance. We have performed an investigative approach to identify parameters that affect liposomes’ ability to effectively deliver lipophilic camptothecin (CPT) to target cells. CPT is a potent anticancer drug, but its undesired physiological properties are impairing its therapeutic use. In this study, we have identified parameters influencing incorporation and retention of lipophilic CPT in liposomes, evaluating the effect of lipid composition, lipid chemical structure (head and tail group variations, polymer inclusion), zeta potential and anisotropy. Polyethyleneglycol (PEG) surface decoration was included to avoid liposome fusing and increase the potential for prolonged in vivo circulation time. The in vitro effect of the different carrier formulations on cell cytotoxicity was compared and the effect of active targeting of one of the formulations was evaluated. We found that a combination of liposome surface charge, lipid headgroup and carbon chain unsaturation affect CPT incorporation. Retention in liposomes was highly dependent on the liposomal surroundings and liposome zeta potential. Inclusion of lipid tethered PEG provided stability and prevented liposome fusing. PEGylation negatively affected CPT incorporation while improving retention. In vitro cell culture testing demonstrated that all formulations increased CPT potency compared to free CPT, while cationic formulations proved significantly more toxic to cancer cells that healthy cells. Finally, antibody mediated targeting of one liposome formulation further enhanced the selectivity towards targeted cancer cells, rendering normal cells fully viable after 1 hour exposure to targeted liposomes.     

Cancer gene-therapy: clinical trials

The objective of gene therapy for the treatment of cancer is to kill tumour cells but preserve normal tissue; therefore, the ideal gene therapy agent would be targeted for specific transduction of tumour cells and have specificity in its cytotoxic action. A variety of strategies to achieve these aims have demonstrated promising results in the laboratory, including enzyme-pro-drug activating systems, correction of genetic mutations contributing to the malignant phenotype and stimulation of a T-cell-mediated anti-tumour immune response. The key to the success of all these strategies is an effective vector that can direct appropriate expression of the therapeutic gene. Viruses have many properties that can be adapted to achieve this therapeutic endpoint; furthermore, they can be engineered to replicate selectively in cancer cells and lyse them. The challenge now is to translate these features into effective therapies that can supplement or supplant existing treatments.     

Potential of apoptotic pathway-targeted cancer therapeutic research: Where do we stand?

Underneath the intricacy of every cancer lies mysterious events that impel the tumour cell and its posterity into abnormal growth and tissue invasion. Oncogenic mutations disturb the regulatory circuits responsible for the governance of versatile cellular functions, permitting tumour cells to endure deregulated proliferation, resist to proapoptotic insults, invade and erode normal tissues and above all escape apoptosis. This disruption of apoptosis has been highly implicated in various malignancies and has been exploited as an anticancer strategy. Owing to the fact that apoptosis causes minimal inflammation and damage to the tissue, apoptotic cell death-based therapy has been the centre of attraction for the development of anticancer drugs. Increased understanding of the molecular pathways underlying apoptosis has enabled scientists to establish unique approaches targeting apoptosis pathways in cancer therapeutics. In this review, we reconnoitre the two major pathways (intrinsic and extrinsic) targeted cancer therapeutics, steering toward chief modulators of these pathways, such as B-cell lymphoma 2 protein family members (pro- and antiapoptotic), inhibitor of apoptosis proteins, and the foremost thespian of extrinsic pathway regulator, tumour necrosis factor-related apoptosis-inducing agent. Together, we also will have a look from clinical perspective to address the agents (drugs) and therapeutic strategies adopted to target these specific proteins/pathways that have entered clinical trials.     

Non-viral in vivo immune gene therapy of cancer: combined strategies for treatment of systemic disease

Many patients with various types of cancers have already by the time of presentation, micrometastases in their tissues and are left after treatment in a minimal residual disease state [Am J Gastroenterol 95(12), 2000]. To prevent tumour recurrence these patients require a systemic based therapy, but current modalities are limited by toxicity or lack of efficacy. We have previously reported that immune reactivity to the primary tumour is an important regulator of micrometastases and determinant of prognosis. This suggests that recruitment of specific anti-tumour mechanisms within the primary tumour could be used advantageously for tumour control as either primary or neo-adjuvant treatments. Recently, we have focused on methods of stimulating immune eradication of solid tumours and minimal residual disease using gene therapy approaches. Gene therapy is now a realistic prospect and a number of delivery approaches have been explored, including the use of viral and non-viral vectors. Non-viral vectors have received significant attention since, in spite of their relative delivery inefficiency, they may be safer and have greater potential for delivery of larger genetic units. By in vivo electroporation of the primary tumour with plasmid expressing GM-CSF and B7-1, we aim to stimulate immune eradication of the treated tumour and associated metastases. In this symposium report, we describe an effective gene based approach for cancer immunotherapy by inducing cytokine and immune co-stimulatory molecule expression by the growing cells of the primary tumour using a plasmid electroporation gene delivery strategy. We discuss the potential for enhancement of this therapy by its application as a neoadjuvant to surgical excision and by its use in combination with suppressor T cell depletion.This article is a symposium paper from the Annual Meeting of the “International Society for Cell and Gene Therapy of Cancer”, held in Shenzhen, China, on 9–11 December 2005.     

Tumour-initiating cells vs. cancer 'stem' cells and CD133: what's in the name?

Recent evidence suggests that a subset of cells within a tumour have 'stem-like' characteristics. These tumour-initiating cells, distinct from non-malignant stem cells, show low proliferative rates, high self-renewing capacity, propensity to differentiate into actively proliferating tumour cells, resistance to chemotherapy or radiation, and they are often characterised by elevated expression of the stem cell surface marker CD133. Understanding the molecular biology of the CD133(+) cancer cells is now essential for developing more effective cancer treatments. These may include drugs targeting organelles, such as mitochondria or lysosomes, using highly efficient and selective inducers of apoptosis. Alternatively, agents or treatment regimens that enhance sensitivity of these therapy-resistant "tumour stem cells" to the current or emerging anti-tumour drugs would be of interest as well.     

Nanoparticle-mediated targeted drug delivery for breast cancer treatment

Breast cancer (BC) is the most common malignancy in women worldwide, and one of the deadliest after lung cancer. Currently, standard methods for cancer therapy including BC are surgery followed by chemotherapy or radiotherapy. However, both chemotherapy and radiotherapy often fail to treat BC due to the side effects that these therapies incur in normal tissues and organs. In recent years, various nanoparticles (NPs) have been discovered and synthesized to be able to selectively target tumor cells without causing any harm to the healthy cells or organs. Therefore, NPs-mediated targeted drug delivery systems (DDS) have become a promising technique to treat BC. In addition to their selectivity to target tumor cells and reduce side effects, NPs have other unique properties which make them desirable for cancer treatment such as low toxicity, good compatibility, ease of preparation, high photoluminescence (PL) for bioimaging in vivo, and high loadability of drugs due to their tunable surface functionalities. In this study, we summarize with a critical analysis of the most recent therapeutic studies involving various NPs-mediated DDS as alternatives for the traditional treatment approaches for BC. It will shed light on the significance of NPs-mediated DDS and serve as a guide to seeking for the ideal methodology for future targeted drug delivery for an efficient BC treatment.     

Use of bacteria in anti-cancer therapies

While a number of valid molecular targets have been discovered for tumours over the past decade, finding an effective way of delivering therapeutic genes specifically to tumours has proved more problematic. A variety of viral and non-viral delivery vehicles have been developed and applied in anti-cancer gene therapies. However, these suffer from either inefficient and/or short-lived gene transfer to target cells, instability in the bloodstream and inadequate tumour targeting. Recently, various types of non-pathogenic obligate anaerobic and facultative anaerobic bacteria have been shown to infiltrate and selectively replicate within solid tumours when delivered systemically. This has prompted the development of cancer gene therapy protocols that use such bacteria as gene delivery vehicles. Here, we review the evidence for the success of these in pre-clinical models and clinical trials, as single modality treatments and in combination with conventional cancer therapies.     

Connexins,important players in the dissemination of prostate cancer cells

Over the past 50 years, increasing experimental evidences have established that connexins (Cxs) and gap junctional intercellular communication (GJIC) ensure an important role in both the onset and development of cancerous processes. In the present review, we focus on the impact of Cxs and GJIC during the development of prostate cancer (PCa), from the primary growth mainly localized in acinar glands and ducts to the distant metastasis mainly concentrated in bone. As observed in several other types of solid tumours, Cxs and especially Cx43 exhibit an ambivalent role with a tumour suppressor effect in the early stages and, conversely, a rather pro-tumoural profile for most of invasion and dissemination steps to secondary sites. We report here the current knowledge on the function of Cxs during PCa cells migration, cytoskeletal dynamics, proteinases activities and the cross talk with the surrounding stromal cells in the microenvironment of the tumour and the bones. In addition, we discuss the role of Cxs in the bone tropism even if the prostate model is rarely used to study the complete sequence of cancer dissemination compared to breast cancer or melanoma. Even if not yet fully understood, these recent findings on Cxs provide new insights into their molecular mechanisms associated with progression and bone targeted behaviour of PCa. This article is part of a Special Issue entitled: Gap Junction Proteins edited by Jean Claude Herve.