Iron: a target for the management of Kaposi's sarcoma?
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Kaposi's sarcoma (KS) is a mesenchymal tumour associated with human herpesvirus-8 infection. However, the incidence of human herpesvirus-8 infection is far higher than the prevalence of KS, suggesting that viral infection per se is not sufficient for the development of malignancy and that one or more additional cofactors are required.
Epidemiological data suggest that iron may be one of the cofactors involved in the pathogenesis of KS. Iron is a well-known carcinogen and may favour KS growth through several pathways. Based on the apoptotic and antiproliferative effect of iron chelation on KS cells, it is suggested that iron withdrawal strategies could be developed for the management of KS. Studies using potent iron chelators in suitable KS animal models are critical to evaluate whether iron deprivation may be a useful anti-KS strategy.
It is suggested that iron may be one of non-viral co-factors involved of KS pathogenesis and that iron withdrawal strategies might interfere with tumour growth in patients with KS.
KeywordsDeferiprone Potent Iron Chelator Volcanic Clay Isonicotinyl Hydrazone
Lists of abbreviations
vascular cell adhesion molecule-1
A large body of evidence indicates that human herpesvirus-8 (HHV-8) has an important etiologic role in the pathogenesis of KS; 1) HHV-8 can be detected in all the epidemiological and histological forms of KS [1, 2, 3] and can directly infect the KS spindle cells [4, 5]; 2) HHV-8 encodes several genes that can independently transform cells to a malignant phenotype ; 3) infection precedes development of the tumour and tracks tightly with KS risk . However, HHV-8 infection appears as a very low risk factor for KS development. Most reports suggest a 2 to 10% global seroprevalence of HHV-8, with much higher rates in some areas [7, 8]. Assuming a 5% prevalence of HHV-8 in the United States and a 1970s baseline incidence of KS in men in the United States of about 0.3 cases per 100000 men, the HHV-8 rate would be one case of KS in every 17000 HHV-8 infections . In addition, seroprevalence rates in different geographic areas do not always correlate with KS development. Eighty-nine percent to 100% of serum samples from the general population in non-KS-endemic African areas such as Gambia or the Ivory Coast, proved to be positive; such a rate is higher than the 40% rate found in sub-Saharan Africa, where KS is endemic . A similar finding among Brazilian-Amerindians has been published; seroprevalence was 53%, although KS has never been reported in this population . Another puzzling finding is the similarity of rates of HHV-8 infection among men and women in Africa . Since the KS found in Africa is about 8 to 10 times as common among men as among women, there must be some reason other than HHV-8 infection to explain this difference.
Thus, there is now compelling evidence that HHV-8 is a necessary, albeit not sufficient, cause of KS and that one or more additional cofactors are required. These co-factors may represent a target for the prevention and/or treatment of KS.
High incidence of KS in iron oxide-rich volcanic clays
Exposure to volcanic clays may also help to explain the distribution of classic KS in the Mediterranean, prevalent in volcanic regions such as the Pelopenese, Sardinia and Sicily. Supporting this hypothesis, Montella et al. noted that the risk of classic KS was twofold higher among people born near Mount Vesuvius than among people born in neighbouring areas . Interestingly, a magmatic substrate similar to that of the East African Rift system (extrusive igneous rocks composed of mafic (and hence iron oxide-rich) minerals)  is also present in Iceland and in the Faroe Islands which are other geographic areas known to exhibit surprisingly high incidence rates of classic KS . One of the characteristics of these mafic minerals is that they are highly weatherable, allowing a significant release of iron compounds in the environment, such as in water or in vegetables . The unusually high prevalence of the classic and endemic forms of KS in regions of intercontinental rifts and volcanism may thus point to prolonged exposure to indigenous iron oxide-rich volcanic soils as a common aetiological risk factor.
Carcinogenic role of iron
Several observations have been made linking cellular iron content to the development of cancers . In prospective studies in animals, administration of excessive amounts of injected or oral iron increases markedly the risk of adenocarcinomas, colorectal tumours, hepatomas, mammary tumours, mesotheliomas, renal tubular cell carcinomas, and sarcomas . In humans, injections of iron complexes have been observed to result in sarcomas at the sites of deposition . Similarly, inhalation of industrial sources of iron may be responsible for respiratory tract neoplasias [25, 26]. Patients with hemochromatosis, a genetic disease characterised by increased iron absorption, show a markedly enhanced susceptibility to primary liver cancer and various other malignancies . Patients with moderate elevation of body iron levels may also have an increased risk of neoplasms of various kinds [28, 29].
Iron status in individuals prone to develop KS
Amazingly, a high iron load is expected to be found in the different epidemiological forms of KS. Iron load is elevated in renal transplant recipients who had received blood transfusions for years before the availability of erythropoietin and before transplantation. Iron load could also be higher in patients with episodes of haemolytic anaemia which are common features in Central Africa or in Mediterranean areas, mostly secondary to glucose-6-phosphatase deficiency, thalassemia or sickle cell anaemia. In HIV infection, the alteration of iron metabolism has been recognised in a variety of ways . The majority of patients in advanced stages of AIDS are hypoferrimic and moderately hyperferritinemic, and they have increased deposition of iron-ferritin and/or haemosiderin in cells of the bone marrow, brain white matter, skeletal muscle, and sometimes in the liver. The 'iron hypothesis' may also provide a non-hormonal explanation for the lower prevalence of KS among women, as they are known to have lower iron reserves than men. In this connection, it may also help to understand the reported disappearance of KS lesions during or just after pregnancy . It is interesting to note that there are high incidence rates of KS among Bantu in the South African Transvaal  and that these individuals are known to frequently suffer from iron overload resulting from the interaction between their genotype and an environmental factor – namely, increased amounts of bioavailable iron in the diet. The source of this dietary iron is a traditional fermented beer that is home-brewed from local crops in steel drums .
Iron withdrawal strategies: a role for the management of KS?
Based on a possible role of iron in tumour development, several studies have shown that iron withdrawal strategies possess considerable activity in vitro in inhibiting tumour growth [38, 39]. More particularly, we found that the chemically unrelated iron chelators desferrioxamine (DFO) and deferiprone could inhibit the growth and induce the apoptosis of human KS-derived cells at clinically achievable concentrations , suggesting that iron chelation may represent an experimental therapeutic approach for the treatment of KS. Iron chelators have also been shown to inhibit vascular cell adhesion molecule-1 (VCAM-1) expression in human dermal microvascular cells . As VCAM-1 may favour angiogenesis and account for inflammation-augmented tumour development [42, 43] and as it is used by cancer cells to enhance metastatic implantation and spread , VCAM-1 inhibition represents another mechanism through which iron chelation might prevent KS growth.
We previously initiated studies investigating the effect of DFO on the growth of immortalized KS-Y1 cells in immunodeficient mice, which resulted in paradoxical enhancement of the growth of the xenografts . These results could be related to the upregulation of angiogenic growth factors by DFO  as well as to its short half-life in mouse plasma  and to its subsequent inability to induce significant iron depletion in non-iron-overloaded mice . Another disadvantage of DFO is its poor ability to permeate cell membranes and bind intracellular Fe pools . Obviously, investigation of iron chelators showing higher iron chelation and use of animal models closely mimicking human KS are required.
Several chelators with greater antiproliferative and/or better pharmacokinetics than DFO have been recently developed . Among the most promising molecules are the 2-pyridoxal isonicotinyl hydrazone (PIH) analogues . Their antiproliferative activity is much greater than that of DFO and is comparable to that of bleomycin and cisplatin . These molecules affect the expression of several molecules involved in cell cycle through their ability to chelate intracellular iron . As PIH analogues may have potential as agents to treat cancer, they represent potential drugs for KS therapy. Another promising chelator with greater efficacy than DFO is ICL670A , which is an orally active representative of a new class of tridentate iron chelator developed for the treatment iron overload and which has been shown to be relatively well-tolerated in phase III studies . Triapine, a ribonucelotide reductase inhibitor, has completed phase I studies in patients with advanced leukaemia and with advanced solid tumours [51, 52] and is currently in phase II clinical trial as an anticancer agent. CP502, GT56-252, NaHBED, and MPB0201 are examples of other new chelators in preclinical/clinical development .
Models closely mimicking human KS are obviously required to evaluate the effect of potential anti-KS drugs. Although there is currently no animal model that accurately represents KS pathogenesis, a number of mouse models have been established that attempt to address specific factors known to contribute to the development of the disease. In early studies, transformed KS cell lines such as KS Y-1 were injected into nude mice, which led to the development of KS-like lesions. This model was used to investigate the effect of various therapies on KS growth, such as human chorionic gonadotropin or interleukin-4 [35, 54]. However, these xenografts models may be flawed, because none of the KS cells used for tumour establishment harbour HHV-8 sequences, as opposed to human KS lesions. More promising models have recently been obtained by creating transgenic mice expressing the HHV8-encoded chemokine receptor (viral G protein-coupled receptor) within hematopoietic cells . The mice develop angioproliferative lesions in multiple organs that morphologically resemble KS lesions. These lesions are characterized by a spectrum of changes ranging from erythematous maculae to vascular tumours, by the presence of spindle and inflammatory cells, and by expression of vGPCR, CD34, and vascular endothelial growth factor . In another model, HHV-8 was injected into normal human skin transplanted onto SCID mice. Injection of HHV-8 induced lesion formation that is morphologically and phenotypically consistent with KS, including the presence of angiogenesis and spindle-shaped cells latently infected with HHV-8 . This in vivo system has the advantage of using human skin cells as the target of the virus, and may be the most accurate model of KS; however, it does not completely mimic KS and is difficult to reproduce .
At present, several types of iron withdrawal strategies have been shown to possess considerable activity in vitro in inhibiting tumour growth. Based on the probable role of iron in KS pathogenesis, it is suggested that manipulations of iron load might interfere with tumour growth in patients with KS. However, further studies using potent iron chelators in suitable KS animal models are critical to evaluate whether iron deprivation may be a useful anti-KS strategy.
The author thanks Dr. P. Herbauts (Free University of Brussels, Belgium) for helpful comments regarding the geological data and Dr. P. Hermans (St. Pierre Hospital, Brussels, Belgium) for having provided the illustration for figure 1.
- 2.Noel JC, Hermans P, Andre J, Fayt I, Simonart T, Verhest A, Haot J, Burny A: Herpesvirus-like DNA sequences and Kaposi's sarcoma. Relationship with epidemiology, clinical spectrum, and histologic features. Cancer. 1996, 77: 2132-2136. 10.1002/(SICI)1097-0142(19960515)77:10<2132::AID-CNCR26>3.0.CO;2-V.CrossRefPubMedGoogle Scholar
- 15.Ziegler JL, Newton R, Katongole-Mbidde E, Mbulataiye S, De Cock K, Wabinga H, Mugerwa J, Katabira E, Jaffe H, Parkin DM, Reeves G, Weiss R, Beral V: Risk factors of Kaposi's sarcoma in HIV-positive subjects in Uganda. AIDS. 1997, 11: 1619-1626. 10.1097/00002030-199713000-00011.CrossRefPubMedGoogle Scholar
- 16.Ziegler JL, Newton R, Bourboulia D, Casabonne D, Beral V, Mbidde E, Carpenter L, Reeves G, Parkin DM, Wabinga H, Mbulaiteye S, Jaffe H, Weiss R, Boshoff C: Risk factors for Kaposi's sarcoma: a case-control study of HIV-seronegative people in Uganda. Int J Cancer. 2003, 103: 233-240. 10.1002/ijc.10818.CrossRefPubMedGoogle Scholar
- 17.Price EW: Podoconiosis. Non-filarial elephantiasis. Oxford: Oxford University Press. 1990Google Scholar
- 20.Krauskopf KB: Introduction to Geochemistry. 1979, McGraw-Hill, Kogahusha Ltd: LondonGoogle Scholar
- 22.Ollier C: Weathering. 1984, Longman Group Ltd: EssexGoogle Scholar
- 25.Dreyfus JR: Lungencarcinoma bei Geschwisteern nach Inhalation von eisenoxydaltigem Staub in der Jugend. Zeit Klin Med. 1936, 130: 256-260.Google Scholar
- 33.Simonart T, Noel JC, Andrei G, Parent D, Van Vooren JP, Hermans P, Lunardi-Yskandar Y, Lambert C, Dieye T, Farber CM, Liesnard C, Snoeck R, Heenen M, Boelaert JR: Iron as a potential cofactor in the pathogenesis of Kaposi's sarcoma. Int J Cancer. 1998, 78: 720-726. 10.1002/(SICI)1097-0215(19981209)78:6<720::AID-IJC9>3.3.CO;2-6.CrossRefPubMedGoogle Scholar
- 35.Lunardi-Iskandar Y, Bryant JL, Zeman RA, Lam VH, Samaniego F, Besnier JM, Hermans P, Thierry AR, Gill P, Gallo RC: Tumorigenesis and metastasis of neoplastic Kaposi's sarcoma cell line in immunodeficient mice blocked by a human pregnancy hormone. Nature. 1995, 375: 64-68. 10.1038/375064a0.CrossRefPubMedGoogle Scholar
- 40.Simonart T, Degraef C, Andrei G, Mosselmans R, Hermans P, Van Vooren JP, Noel JC, Boelaert JR, Snoeck R, Heenen M: Iron chelators inhibit the growth and induce the apoptosis of Kaposi's sarcoma cells and of their putative endothelial precursors. J Invest Dermatol. 2000, 115: 893-900. 10.1046/j.1523-1747.2000.00119.x.CrossRefPubMedGoogle Scholar
- 42.Vidal-Vanaclocha F, Fantuzzi G, Mendoza L, Fuentes AM, Anasagasti MJ, Martin J, Carrascal T, Walsh P: IL-18 regulates IL-1beta-dependent hepatic melanoma metastasis via vascular cell adhesion molecule-1. Proc Natl Acad Sci USA. 2000, 97: 734-739. 10.1073/pnas.97.2.734.CrossRefPubMedPubMedCentralGoogle Scholar
- 44.Simonart T, Boelaert JR, Andrei G, van den Oord JJ, Degraef C, Hermans P, Noel JC, Van Vooren JP, Heenen M, De Clercq E, Snoeck R: Desferrioxamine enhances AIDS-associated Kaposi's sarcoma tumor development in a xenograft model. Int J Cancer. 2002, 100: 140-143. 10.1002/ijc.10475.CrossRefPubMedGoogle Scholar
- 48.Richardson DR, Milnes K: The potential of iron chelators of the pyridoxal isonicotinoyl hydrazone class as effective antiproliferative agents II: the mechanism of action of ligands derived from salicylaldehyde benzoyl hydrazone and 2-hydroxy-1-naphthylaldehyde benzoyl hydrazone. Blood. 1997, 89: 3025-3038.PubMedGoogle Scholar
- 49.Galanello R, Piga A, Alberti D, Rouan MC, Bigler H, Sechaud R: Safety, tolerability, and pharmacokinetics of ICL670, a new orally active iron-chelating agent in patients with transfusion-dependent iron overload due to beta-thalassemia. J Clin Pharmacol. 2003, 43: 565-572. 10.1177/0091270003043006002.CrossRefPubMedGoogle Scholar
- 50.Nisbet-Brown E, Olivieri NF, Giardina PJ, Grady RW, Neufeld EJ, Sechaud R, Krebs-Brown AJ, Anderson JR, Alberti D, Sizer KC, Nathan DG: Effectiveness and safety of ICL670 in iron-loaded patients with thalassaemia: a randomised, double-blind, placebo-controlled, dose-escalation trial. Lancet. 2003, 361: 1597-1602. 10.1016/S0140-6736(03)13309-0.CrossRefPubMedGoogle Scholar
- 52.Giles FJ, Fracasso PM, Kantarjian HM, Cortes JE, Brown RA, Verstovsek S, Alvarado Y, Thomas DA, Faderl S, Garcia-Manero G, Wright LP, Samson T, Cahill A, Lambert P, Plunkett W, Sznol M, DiPersio JF, Gandhi V: Phase I and pharmacodynamic study of Triapine, a novel ribonucleotide reductase inhibitor, in patients with advanced leukemia. Leuk Res. 2003, 27: 1077-83. 10.1016/S0145-2126(03)00118-8.CrossRefPubMedGoogle Scholar
- 55.Yang TY, Chen SC, Leach MW, Manfra D, Homey B, Wiekowski M, Sullivan L, Jenh CH, Narula SK, Chensue SW, Lira SA: Transgenic expression of the chemokine receptor encoded by human herpesvirus 8 induces an angioproliferative disease resembling Kaposi's sarcoma. J Exp Med. 2000, 191: 445-54. 10.1084/jem.191.3.445.CrossRefPubMedPubMedCentralGoogle Scholar
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