Current Molecular Medicine - Volume 3, Issue 8, 2003

Inhibition of tumor angiogenesis suppresses tumor growth and metastatic spreading in many experimental models, suggesting that anti-angiogenic drugs may be used to treat human cancer. During the past decade more than eighty molecules that showed anti-angiogenic activity in preclinical studies were tested in clinical cancer trials, but most of them failed to demonstrate any measurable anti-tumor activity and none have been approved for clinical use. Recent results stemming from trials with anti-VEGF antibodies, used alone or in combination with chemotherapy, suggest that systemic anti-angiogenic therapy may indeed have a measurable impact on cancer progression and patient survival. From the clinical studies it became nevertheless clear that the classical endpoints used in anti-cancer trials do not bring sufficient discriminative power to monitor the effects of anti-angiogenic drugs. It is therefore necessary to identify and validate molecular, cellular and functional surrogate markers of angiogenesis to monitor activity and efficacy of anti-angiogenic drugs in patients. Availability of such markers will be instrumental to re-evaluate the role of tumor angiogenesis in human cancer, to identify new molecular targets and drugs, and to improve planning, monitoring and interpretation of future studies. Future anti-angiogenesis trials integrating biological endpoints and surrogate markers or angiogenesis will require close collaboration between clinical investigators and laboratory-based researchers. Here we review and discuss critical issues and emerging paradigms relevant to tumor angiogenesis and anti-angiogenic drugs and to the monitoring of tumor angiogenesis and anti-angiogenic effects in patients.

A large body of evidence indicates that T cell-mediated dominant suppression of selfreactive T cells is indispensable for maintaining immunologic unresponsiveness to self-constituents (i.e., self-tolerance) and preventing autoimmune disease. CD25+CD4+ regulatory T cells naturally present in normal animals, in particular, engage in this function, as their reduction or functional abnormality leads to the development of autoimmune disease in otherwise normal animals. They are at least in part produced by the normal thymus as a functionally mature and distinct subpopulation of T cells. Recent studies have demonstrated that CD25+CD4+ regulatory T cells control not only autoimmune reactions but also other immune responses, including tumor immunity, transplantation tolerance and microbial infection. Thus, this unique population of regulatory T cells can be exploited to control pathological as well as physiological immune responses.

Glucocorticoids (GC) control cell cycle progression and induce apoptosis in cells of the lymphoid lineage. Physiologically, these phenomena have been implicated in regulating immune functions and repertoire generation. Clinically, they form the basis of inclusion of GC in essentially all chemotherapy protocols for lymphoid malignancies. In spite of their significance, the molecular mechanisms underlying the anti-leukemic GC effects and the clinically important phenomenon of GC resistance are still unknown. This review summarizes recent findings related to GC-induced apoptosis, cell cycle arrest, and GC resistance with particular emphasis on acute lymphoblastic leukemia (ALL). We hypothesize that under conditions of physiological Bcl-2 expression, GC might induce classical programmed cell death by directly perturbing the Bcl-2 rheostat. In the presence of anti-apoptotic Bcl- 2 proteins, cell death might result from accumulating catabolic and / or other detrimental GC effects driven by, and critically dependent on, GC receptor (GR) autoinduction. Although still controversial, there is increasing evidence for release of apoptogenic factors through pores in the outer mitochondrial membrane, rather than ΔΨloss-dependent membrane rupture, with maintenance of mitochondrial function at least in the early phase of the death response. GC-induced cell cycle arrest in ALL cells appears to be independent of apoptosis induction and vice versa, and critically depends on repression of both cyclin-D3 and c-myc followed by increased expression of the cyclin-dependent kinase inhibitor, p27Kip1. Since development of GC-resistant clones requires both cell cycle progression and survival, GC resistance might frequently result from structural or regulatory defects in GR expression, perhaps the most efficient means to target both pathways concurrently.

Adult stem cells were once thought to produce only the cell lineages characteristic of the tissues in which they reside. Recent studies suggest that cells derived from one adult tissue can be reprogrammed to change into cellular phenotypes not normally found in that tissue. Bone marrow (BM) derived cells have been demonstrated to differentiate into multiple lineages, including glial cells and neurons, both in vivo and in vitro. This unexpected plasticity of BM cells occurs not only under experimental conditions, but also in humans following BM transplantation. As a result, BM transplantation has emerged as a novel approach to enhance neural regeneration and restore injured brain tissue. Several research teams have reported that transplanted BM cells can differentiate into neural derivatives; indeed, some of these cells were capable of integration into the host brain, where they promoted functional recovery after brain injury. Other researchers conducting similar studies were unable to find any evidence of neural differentiation, concluding that differentiation 'from marrow to brain' is not a common phenomenon. More recently, two papers in Nature also cast doubt on the plasticity of adult stem cells, suggesting that the acquisition of different identities by grafted BM cells may merely reflect their fusion with host cells. Reasons for the wide discrepancies among findings in current BM stem cell research are unclear, making it difficult to understand the mechanisms by which transplanted marrow stem cells provide therapeutic benefit. Here, we summarize recent findings on this subject, and address some of the major controversies that have marked the evolution of adult stem cell research.

Induction of apoptosis in cancer cells with chemotherapy and radiation treatment is a major strategy in cancer therapy at present. Nevertheless, innate or acquired resistance has been an obstacle for conventional clinical therapy. TNF-related apoptosis inducing ligand (TRAIL / Apo-2L) is a typical member of the TNF ligand family that induces apoptosis through activating the death receptors. In recent years, considerable attention has been focused on the potential benefits of TRAIL in cancer therapy, as the majority of cancer cells are sensitive to TRAIL-induced apoptosis, while most normal cells are TRAIL-resistant. Furthermore, the use of TRAIL in combination with chemotherapeutic agents or irradiation strengthens its apoptotic effects. In this review, we will discuss the regulation mechanism of TRAIL-induced apoptosis and the molecular basis of the synergies created by its use in combination with chemotherapeutic agents and irradiation. We also analyze in detail that TRAIL may be cytotoxic, as this is a potential obstacle to its development for being used in cancer therapy.

Osteoporosis is a leading public health problem in our rapidly growing, aging population. It is characterized by reduced bone mass and microarchitectural deterioration of bone tissue, with a consequent increase in bone fragility and susceptibility to fracture risk. Osteoporosis is a complex multifactorial disease, determined by genetic and environmental factors as well as their interactions. A large number of molecular, genetic and environmental factors underlying osteoporosis have been identified in past decades. In this article, we review 1) the molecular mechanisms of several principal systemic and local factors regulating bone metabolism; and 2) the current status of genetic studies searching for genes underlying osteoporosis. Further, we attempt to integrate knowledge from those two fields, and their potential implications for osteoporosis treatment.

Higher animals establish host defense by orchestrating innate and adaptive immunity. This is mediated by professional antigen presenting cells, i.e. dendritic cells (DCs). DCs can incorporate pathogens, produce a variety of cytokines, maturate, and present pathogen-derived peptides to T cells, thereby inducing T cell activation and differentiation. These responses are triggered by microbial recognition through type I transmembrane proteins, Toll-like receptors (TLRs) on DCs. TLRs consist of ten members and each TLR is involved in recognizing a variety of microorganism-derived molecular structures. TLR ligands include cell wall components, proteins, nucleic acids, and synthetic chemical compounds, all of which can activate DCs as immune adjuvants. Each TLR can activate DCs in a similar, but distinct manner. For example, TLRs can be divided into subgroups according to their type I interferon (IFN) inducing ability. TLR2 cannot induce IFN-α or IFN- β, but TLR4 can lead to IFN-β production. Meanwhile, TLR3, TLR7, and TLR9 can induce both IFN-α and IFN-β. Recent evidences suggest that cytoplamic adapters for TLRs are especially crucial for this functional heterogeneity. Clarifying how DC function is regulated by TLRs should provide us with critical information for manipulating the host defense against a variety of diseases.

Therapeutic vaccines represent an attractive approach to cancer treatment. Traditionally, cancer immunotherapy targets antigens expressed by the tumor cells. Although numerous clinical trials studying different cancer vaccines have been conducted during the past twenty years, very limited clinical responses have been observed. The inefficient anti-tumor immunity is thought to be due, in major part, to the escape mechanisms exerted by the genetically unstable tumor cells, e.g., emergence of antigen-loss mutants, downregulation of MHC molecules and lack of expression of costimulatory molecules. Recently, a novel vaccine strategy has been developed to circumvent these obstacles. Taking advantage of the importance of angiogenesis in tumor growth and the genetic stability of endothelial cells, this immunotherapy strategy targets antigens (e.g., angiogenic growth factor receptors) overexpressed by the tumor neo-vasculature rather than the tumor cells per se. For example, active immunization against vascular endothelial growth factor receptor-2 (VEGFR-2) has been shown to generate strong cellular and humoral immune responses, which lead to the inhibition of angiogenesis and tumor growth and metastasis. This review provides an outline of this emerging field and discusses the advantages and potential pitfalls of such a vaccine strategy.