Advances in the understanding and management of acute promyelocytic leukemia

Considerable progress has been made over the past decade in the understanding and management of acute promyelocytic leukemia (APL). At the laboratory level, molecular mechanisms underlying the arrest of differentiation that typically features in this malignancy, have been clarified and currently provide important models for addressing future investigation aimed at releasing the maturation block in other malignancies. In the clinic, advances in the management of APL have converted this rapidly fatal disease into the most frequently curable leukemia in adults. Use of retinoids in combinatorial protocols with anthracycline-based chemotherapy for front line treatment currently results in long-term survival and potential cure in at least 60% of newly diagnosed patients. Even after relapse, the disease is still curable in a high percentage of cases by various approaches including combinations of chemotherapy, retinoids, arsenic trioxide, stem cell transplantation and antibody-targeted chemotherapy. Genetic testing for identification of the disease-specific gene rearrangement and monitoring of residual disease have proved critical in establishing correct diagnosis and better evaluate the response to therapy at the molecular level. Current 'hot' issues for clinical investigation include: (i) better understanding and management of the severe coagulopathy present at diagnosis in most patients; (ii) the definition of risk categories to improve identification of patients at highest risk of relapse and (iii) the translation of successful differentiation therapy to other leukemia subsets.     

Clinical applications of retinoids in cancer medicine

The retinoids are compounds structurally related to vitamin A. The most extensively studied agents in cancer medicine include all-trans-retinoic acid, 9-cis-retinoic acid, and 13-cis-retinoic acid. In addition to several described immune regulatory functions, these agents may exert their antineoplastic effects through the regulation of tumor suppressor genes such as RAR-beta2. The survival benefit provided to patients with acute promyelocytic leukemia (APL) after induction therapy with all-trans RA and the responses experienced by patients with cutaneous lesions from Kaposi's sarcoma and cutaneous T cell lymphoma treated with 9-cis RA and a selective rexinoid--bexarotene--respectively, led to their approval by the Food and Drug Administration during the last decade. As chemopreventive agents, retinoids have proven to effectively regress laryngeal papillomatosis and oral leukoplakia lesions. The ability of 13-cis-RA to prevent second primary malignancies in patients with carcinoma of the head and neck has also been demonstrated. Unfortunately, this intervention did not affect the primary tumor recurrence rates. The toxicity and efficacy of retinoids administered in combination with other biological and cytotoxic agents have also been explored in patients with renal cell carcinoma, breast cancer, myelodysplasia, prostate, cervix, and other malignancies with a broad range of reported responses. Further characterization of the molecular processes modulated by these agents will serve to better define their role in the prevention and treatment of human cancer and to tailor specific targeted therapies in combination with other compounds. Newer and more selective retinoids and rexinoids are completing phase I and phase II studies and hold promising.     

Involvement of UBE1L in ISG15 conjugation during retinoid-induced differentiation of acute promyelocytic leukemia

Acute promyelocytic leukemia (APL) cases expressing the t(15,17) product, promyelocytic leukemia (PML)/retinoic acid receptor alpha (RARalpha), have clinical remissions through leukemic cell differentiation after all-trans-retinoic acid (RA) treatment. This differentiation therapy propelled interest in uncovering molecular mechanisms for RA-dependent APL differentiation. We previously identified the ubiquitin-activating enzyme-E1-like protein (UBE1L) as an RA-regulated target gene in APL that triggers PML/RARalpha degradation and apoptosis. This study reports that conjugation of the ubiquitin-like species, interferon-stimulated gene, 15-kDa protein (ISG15), also occurs during RA-induced APL differentiation. Knock-down of UBE1L expression inhibited this conjugation. RA treatment of APL and other RA-responsive leukemic cells induced expression of UBE1L and ISG15 as well as intracellular ISG15 conjugates. Notably, ISG15 conjugation did not occur in RA-resistant NB4-R1 APL cells. Induction of UBE1L and ISG15 along with ISG15 conjugation in RA-sensitive NB4-S1 APL cells were detected following treatment with specific retinoids and type I interferon (IFN). UBE1L and ISG15 mRNAs were co-expressed in normal human tissues that were examined. In contrast, UBE1L mRNA expression was markedly repressed in several cancer cell lines. A physical association was found between UBE1L and ISG15 in vivo. This required the conserved diglycine motif in the carboxyl terminus of ISG15. Targeting UBE1L expression with small inhibitory RNA or small hairpin RNA inhibited IFN and RA-induced ISG15 conjugation. Formation of ISG15 conjugates through induction of an activating enzyme represents a novel pharmacologic mechanism for regulation of this ubiquitin-related species. Taken together, the observed rela tionship between expression of UBE1L and ISG15, their physical association and coordinate regulation, and induced ISG15 conjugation during leukemic cell differentiation implicate an important role for these proteins in retinoid response.     

Leukemia: beneficial actions of retinoids and rexinoids

Acute promyelocytic leukemia (APL), a subtype of acute myeloid leukemia, is the prototype of a cancer that can be cured by differentiation therapy using combined retinoic acid (RA) and chemotherapy. Acute promyelocytic leukemia is caused by chromosomal translocations, which in the large majority of cases generate the prototypic promyelocytic leukemia-retinoic-acid receptor alpha (PML-RARalpha) an oncogenic fusion protein formed from the retinoic-acid receptor alpha and the so-called PML protein. The fusion protein leads to the deregulation of wild type PML and RARalpha function, thus inducing the differentiation block and an altered survival capacity of promyelocytes of affected patients. A plethora of studies have revealed molecular details that account for the oncogenic properties of acute promyelocytic leukemia fusion proteins and the events that contribute to the therapy-induced differentiation and apoptosis of patients' blasts. Illustrating the beneficial mechanisms of action of retinoids for acute promyelocytic leukemia patients this review goes on to discuss a plethora of recently recognized molecular paradigms by which retinoids and rexinoids, alone or in combination with other compounds, regulate growth, differentiation and apoptosis also in non-acute promyelocytic leukemia cells, highlighting their potential as drugs for cancer therapy and prevention.     

Retinoids as chemopreventive agents

Retinoids are promising agents for cancer chemoprevention. The myriad effects of retinoids on biological processes including development, differentiation, homeostasis, carcinogenesis and apoptosis are mediated through their molecular targets, the retinoid and rexinoid receptors. Tissue specific expression patterns, ligand specificities, receptor numbers, their distinct functions and functional redundancy make retinoid signaling highly complex. The cross-talks of these receptors with cell surface receptors signaling pathways, as well as their interactions with multiple co-activators and co-repressors further add to the complexity of the pleiotropic effects of retinoids. Elucidation of retinoid signaling pathways and indepth understanding of the mechanisms that underlie the anti-proliferative and apoptotic action of retinoids has paved the way for designing synthetic retinoids for effective chemoprevention and therapy of cancer. Development of receptor selective synthetic retinoids is a major focus of molecular retinoid development. Other new avenues encompass identification of novel retinoid regulated genes, orphan-receptor ligands/functions, novel retinoid mechanisms involving receptor-independent apoptosis inducing activity and synergistic combinations with other agents for cancer prevention and therapy. This review focuses on recent advances in the understanding of molecular mechanisms underlying the action of retinoids and retinoid molecular targeting studies designed primarily to develop retinoids with reduced toxicity, while maintaining or enhancing activity in context of chemoprevention. The clinical efficacy of retinoid based chemoprevention trials is discussed.     

Receptor-independent induction of apoptosis by synthetic retinoids

Retinoids modulate cell proliferation, differentiation and apoptosis. Many of these effects are mediated by nuclear retinoid receptors. However, studies with certain synthetic retinoids, including some that can activate retinoid receptors, revealed that they affect cell growth and especially apoptosis by mechanisms that are independent of nuclear receptors. This chapter describes the pro-apoptotic effects of the synthetic retinoid CD437 [6-[3-(1-adamantyl)-4-hydroxyphenyl]-2-naphthalene carboxylic acid], and structurally-related retinoids and summarizes the mechanisms by which they induce apoptosis.