Does improved control of tumour growth require an anti-cancer therapy targeting both neoplastic and intratumoral endothelial cells?

Angiosuppression and Chemotherapy: Strategies Aimed at Their Integration in Cancer Patients

A number of antiangiogenic agents have been developed as pharmaceuticals and are currently being tested in clinical studies. Potential strategies to enhance the activity of angiogenesis inhibitors could be to combine them, or better still, to administer them either sequentially or concurrently with cytotoxic drugs. Chemotherapy would be a more appropriate initial choice for patients with advanced disease since cytostatic agents can induce a fast regression of the tumor and cancer-related symptoms. Antiangiogenic treatment could be used after chemotherapy in patients who achieve disease remission to prolong the time to progression, the symptom-free interval and the overall survival. Antiangiogenic treatment is likely to attain an important role in the adjuvant setting. In fact, it could be used for prolonged periods after radical surgery to maintain dormancy of residual tumor cells. In spite of these promising preclinical data, several points need to be clarified before the initiation of clinical trials. In fact, certain misconceptions may interfere with their optimum design and result analysis.

Review : Angiogenesis: A new target for antineoplastic therapy

Objective. To review the pathophysiologic rationale and therapeutic applications of inhibiting angiogenesis in solid tumor growth.

Data Sources. A MEDLINE search of articles published from 1985 to 1995 and a CancerLit search of articles published from 1988 to 1995, using the MESH heading "neovascularization" and text words "angiogenesis" and "antiangiogenesis." References listed in identified publications were reviewed for additional pertinent literature.

Study Selection. All human trials evaluating angiogenesis inhibitors in malignant disease and pre- clinical trials that illustrate potential mechanisms of action of such agents were included.

Data Synthesis. Angiogenesis, the formation of new blood vessels, is necessary for the development of significant solid tumor growth. Inhibition of angio genesis is a unique mechanism of antineoplastic ther apy that does not use traditional cytotoxic actions. Four investigational antiangiogenic agents are cur rently being evaluated in phase I and II trials. Poten tially beneficial applications of angiogenesis inhibitors include suppression of occult and premalignant le sions, symptomatic control of angiogenesis-depen dent malignancies, and combination therapy with traditional antineoplastic agents.

Conclusion. Inhibition of angiogenesis is a new pharmacologic strategy that may prove useful in controlling malignant growth. A number of agents with antiangiogenic activity have been developed, and further study of these drugs will define their role in antineoplastic therapy.

Molecular interactions in cancer cell metastasis

Metastasis, the process by which cancer cells leave the primary tumour, disseminate and form secondary tumours at anatomically distant sites, is a serious clinical problem as it is disseminated disease, which is often impossible to eradicate successfully, that causes the death of most cancer patients. Metastasis results from a complex molecular cascade comprising many steps, all of which are interconnected through a series of adhesive interactions and invasive processes as well as responses to chemotactic stimuli. In spite of its clinical significance, it remains incompletely understood. This review provides an overview of some of the molecular interactions that are critical to metastasis. It summarises the principle molecular players in the major steps of the metastatic cascade. These are: (1) tumour angiogenesis, (2) disaggregation of tumour cells from the primary tumour mass, mediated by cadherins and catenins, (3) invasion of, and migration through, the basement membrane (BM) and extracellular matrix (ECM) surrounding the tumour epithelium, and subsequent invasion of the BM of the endothelium of local blood vessels. This is mediated through integrins and proteases, including urokinase form of plasminogen activator (uPA), matrix metalloproteinases (MMPs) and cathepsins, (4) intravasation of the tumour cells into the blood vessels prior to hematogeneous dissemination to distant sites, (5) adhesion of the circulating tumour cells to the endothelial cell lining at the capillary bed of the target organ site. This occurs through adhesive interactions between cancer cells and endothelial cells involving selectins, integrins and members of the immunoglobulin superfamily (IgSF), (6) invasion of the tumour cells through the endothelial cell layer and surrounding BM (extravasation) and target organ tissue and (7) the development of secondary tumour foci at the target organ site.

Metronomic scheduling: the future of chemotherapy?

Tumour endothelium is a new target for anticancer treatments. Proliferating endothelial cells from the tumour, even if qualitatively different from those of blood vessels in the normal tissue of origin, remain putatively normal and genetically stable cells. The results of recent experimental studies have suggested that frequent administration of certain cytotoxic agents at low doses (a tenth to a third of the maximum tolerated dose), known as 'metronomic' chemotherapy, increases the antiangiogenic activity of the drugs. The effects of these metronomic schedules of cytotoxic agents may be further enhanced by concurrent administration of novel, selective, treatments that inhibit, at a molecular level, the processes of tumour formation and growth eg angiogenesis, growth factor pathways, and other signal transduction cascades. The need to treat patients for long periods also supports the use of metronomic scheduling for chemotherapy, to minimise toxicity and to target both proliferating tumour cells and endothelial cells. This review describes the experimental studies involving metronomic schedules of chemotherapy, alone and in combination with angiogenesis inhibitors, and suggests a new therapeutic anticancer paradigm for controlling cancer by long-term therapy, based on the development of combinations of metronomic cytotoxic agents with individually tailored compounds designed to target specific molecules.

Student Report - The Fight against Cancer and Angiogenesis Inhibitors: Are we Entering a New Era?

Chemoresistance is currently the main cause of failure in the treatment of cancer which, despite extensive research, remains unsolved. In this report the theoretical assumptions underlying antiangiogenic therapy are described and future perspectives and limits are discussed.

The rationale and future potential of angiogenesis inhibitors in neoplasia

Malignant tumours are angiogenesis-dependent diseases. Several experimental studies suggest that primary tumour growth, invasiveness and metastasis require neovascularisation. Tumour-associated angiogenesis is a complex multistep process under the control of positive and negative soluble factors. A mutual stimulation occurs between tumour and endothelial cells by paracrine mechanisms. Angiogenesis is necessary, but not sufficient, as the single event for tumour growth. There is, however, compelling evidence that acquisition of the angiogenic phenotype is a common pathway for tumour progression, and that active angiogenesis is associated with other molecular mechanisms leading to tumour progression. Experimental research suggests that it is possible to block angiogenesis by specific inhibitory agents, and that modulation of angiogenic activity is associated with tumour regression in animals with different types of neoplasia. The more promising angiosuppressive agents for clinical testing are: naturally occurring inhibitors of angiogenesis (angiostatin, endostatin, platelet factor-4 and others), specific inhibitors of endothelial cell growth (TNP-470, thalidomide, interleukin-12 and others), agents neutralising angiogenic peptides (antibodies to fibroblast growth factor or vascular endothelial growth factor, suramin and analogues, tecogalan and others) or their receptors, agents that interfere with vascular basement membrane and extracellular matrix [metalloprotease (MMP) inhibitors, angiostatic steroids and others], antiadhesion molecules antibodies such as antiintegrin alpha v beta 3, and miscellaneous drugs that modulate angiogenesis by diverse mechanisms of action. Antiangiogenic therapy is to be distinguished from vascular targeting. Gene therapy aimed to block neovascularisation is also a feasible anticancer strategy in animals bearing experimental tumours. Antiangiogenic therapy represents one of the more promising new approaches to anticancer therapy and it is already in early clinical trials. Because angiosuppressive therapy is aimed at blocking tumour growth indirectly, through modulation of neovascularisation, antiangiogenic agents need to be developed and evaluated as biological response modifiers. Therefore, adequate and well designed clinical trials should be performed for a proper evaluation of antiangiogenic agents, by determination and monitoring of surrogate markers of angiogenic activity.

Association of tumour vasculature with tumour progression and overall survival of patients with non-early gastric carcinomas

In order to investigate the relationship between intratumoral vasculature and progression of gastric carcinomas and between vessel counts and survival of patients with non-early gastric carcinoma, we counted the intratumoral microvessels and compared their numbers with clinicopathological parameters, as well as with the patients' survival. Microvessels were stained with anti-CD34 monoclonal antibody before counting by microscopy (x200). In a group of 181 patients who had undergone tumour resection and were followed for more than 24 months the vessel counts for 83 patients with stage IV disease were significantly higher than those for patients with any other stage of disease. Among various clinicopathological variables, haematogenous metastasis, lymph node metastasis, peritoneal metastasis, stage IV disease and non-curative resection were more frequent in the patients with highly vascularized tumours (intratumoral vessel count > 155) than in those with less vascularized tumours. As a classification of stage IV disease such as haematogenous or peritoneal metastasis generally indicates non-curative resection, it can be considered that the development of stage IV disease is associated with the increase in tumour angiogenesis. Both univariate and multivariate analyses showed that the intratumoral vessel count was significantly predictive of overall survival, when tested as either a continuous or dichotomous variable. Cox hazards model analysis showed that the vessel count was one of the significant and independent prognostic variables. Patients with highly vascularized tumours were significantly more likely to die than those with less vascularized tumours. Assessment of tumour vasculature may therefore be important, not only for its prognostic value, but also as it may help to predict responses to angiogenesis-inhibiting agents.

The metastatic phenotype--prognostic implications

Strong efforts are being made in order to better understand the molecular mechanisms underlying cancer dissemination. We have attempted to summarise some of the findings in this area. A large number of differences in gene expression have been described in metastatic and non-metastatic cells. In the mouse B16 melanoma system, more than 50 different markers have been described. It is likely that many of these differences reflect the same genetic alteration (i.e. a mutation in a regulatory gene alters the expression of a set of co-regulated target genes). One could argue that it is more effective to study mutations in regulatory as opposed to expression of down-stream target genes. However, we feel that proto-oncogenes are less suitable as markers compared to target genes, since it is difficult to screen for mutations at multiple levels in regulatory pathways. In contrast, measuring the expression of a small number of target genes (i.e. one of the targets in Fig. 1), the expression of which are stimulated by upstream regulators, is accomplished more easily. It is anticipated that the future of optimised panels of independent markers will sharpen cancer diagnosis and lead to individualised therapy.

Role of gangliosides in tumour progression: a molecular target for cancer therapy?

In a number of patients with tumours of either neuroectodermal or epithelial origin, polysialylated gangliosides (e.g. GD3) are over-expressed. The mechanism of ganglioside over-expression may be different for the two classes of tumour and could represent distinct secondary genetic mutations or epigenetic changes affecting the enzymes (transferases and/or hydrolases) controlling the metabolic interconversions of these gangliosides. Tumour cells of neuroectodermal origin (e.g. melanomas and brain tumours) are known to produce and shed polysialylated gangliosides, whereas paracrine signal(s) from tumour cells of epithelial origin (e.g. carcinomas of cervix, lung, prostate, breast, head and neck, colon and ovary) may stimulate over-expression and shedding from tumour infiltrating mesenchymal cells (e.g. macrophages and/or fibroblasts). This cellular membrane over-expression and shedding of acidic glycosphingolipids into the interstitial spaces and blood of cancer patients may play a central role in increased tumour cell growth, lack of immune cell recognition and neovascularization and could represent a molecular target for cancer therapy.

Breast cancer angiogenesis--new approaches to therapy via antiangiogenesis, hypoxic activated drugs, and vascular targeting

Several groups have shown that quantitation of tumor angiogenesis by counting blood vessels in primary breast cancer gives an independent assessment of prognosis. Poor prognosis is associated with high blood vessel counts. We have shown that the rate of cell division in endothelial cells is much higher in breast tumours than in normal breast. Breast cancer cell lines and primary human breast tumours express a wide range of vascular growth factors, including VEGF, placenta growth factor, pleiotrophin, TGF beta 1, acidic and basic FGF, and platelet-derived endothelial cell growth factor. Inhibiting angiogenesis by blocking vascular growth factors would be difficult with highly specific agents, but drugs with a broader spectrum of antagonism may be effective. We have developed several suramin analogues which are less toxic than suramin in vivo but more potent in inhibiting angiogenesis, and these have been developed for Phase I. A combination of anti-angiogenesis agents with drugs activated by hypoxia may also be useful, because anti-angiogenesis alone may not kill cells, whereas activation of hypoxic drugs could synergize. New endpoints may be necessary because inhibition of new blood vessel formation may not cause tumour regression. Thus, the endpoint of stable disease and biochemical assessment of inhibition of angiogenesis may be much more important in therapeutic studies and for drug development in the future. The prognostic importance of angiogenesis suggests that this should be a major new therapeutic target.

Vascular endothelial growth factor (VEGF) mRNA expression in human tumor models of different histologies

BACKGROUND

Vascular endothelial growth factor (VEGF) is a polypeptide with specific effects on endothelial cell growth and blood vessel permeability. Recent studies demonstrated a key role for VEGF in tumor neovascularization, which is a prerequisite for tumor proliferation and metastasis.

MATERIALS AND METHODS

We studied the expression of VEGF mRNA in a panel of 65 different human tumor xenografts of various histologies using Northern and slot blot analyses. Analyis of vessel density was performed morphologically and after immunohistochemical staining of endothelial cells.

RESULTS

High expression levels were observed in 22/65 tumors. In melanoma, colorectal, gastric, breast and lung cancers only single tumors showed strong expression signals, whereas 7/10 renal cell carcinoma (RCC) xenografts demonstrated high levels of VEGF mRNA. Vessel density analysis revealed a clear correlation of VEGF mRNA expression with vascularization in RCC (p = 0.0048). Patient survival time was compared for tumors showing high versus low expression values. The overall 5-year survival rate was significantly lower for patients with high expression of VEGF mRNA (p = 0.0306).

CONCLUSIONS

These data support the hypothesis that tumor cells of various histologies secrete VEGF, which acts as a paracrine factor to induce endothelial cell proliferation and vessel formation and mediates tumor progression.