Langerhans cell histiocytosis

Langerhans cell histiocytosis (LCH) is a rare clonal disorder that consists of single or multiple mass lesions composed of cells with an abnormal Langerhans cell phenotype. Its etiology remains unknown, despite extensive searches for evidence of consistent cytogenetic abnormalities, gene rearrangements, or viral genomes. Similarly, the pathogenesis of the disease is enigmatic, although the altered expression of cytokines and cellular adhesion molecules, important for migration and homing of the activated normal Langerhans cell, may play an important role. The biologic behavior of LCH ranges from spontaneous remission to lethal dissemination, and such behavior cannot be predicted on the basis of histologic features. The presence and degree of organ dysfunction, together with the patient's age at diagnosis, remain the most reliable indicators of prognosis. Treatment of severe, refractory disease continues to be controversial and, in many cases, ineffectual. The revised classification scheme for LCH and related disorders recognizes the uncertain biological potential of LCH and its relation to other processes of dendritic and macrophage origin.     

Expression of cellular adhesion molecules in Langerhans cell histiocytosis and normal Langerhans cells.

Langerhans cell histiocytosis (LCH) is characterized by lesions with an accumulation and/or proliferation of Langerhans cells (LCs). Little is known of the etiology and pathogenesis of LCH. Although the relation between the LCH cell and normal LCs is currently uncertain, the localizations of the LCH cells is considered aberrant when compared with normal LCs. Cellular adhesion molecules (CAMs) are known to play an important role in a variety of cell functions such as migration, antigen presentation, and activation. Aberrant migration of LCs may play a role in the pathogenesis of LCH. We investigated CAMs in 27 tissue specimens of 20 patients with LCH retrieved from our files during the last 15 years. LCH cells showed strong expression of CAMs such as CD54, CD58, and the beta 1-integrin alpha 4 that are upregulated during activation of normal LCs. In contrast, CAMs not found on normal LCs could be demonstrated in a number of cases on LCH cells like CD2, CD11a, and CD11b. Also CD62L, normally expressed only by epidermal LCs, could be detected on LCH cells. The integrins alpha 5 and alpha 6, not or only weakly found on epidermal LCs and highly expressed by activated LCs, could not be demonstrated on LCH cells. Our data suggest abnormal expression of CAMs on LCH cells that may contribute to abnormal migration of LCs in LCH. The aberrant phenotype of LCH cells has characteristics of both epidermal LCs and activated LCs and may be indicative of an arrested state of activation and/or differentiation of LCs.     

Fascin,a sensitive new marker for Reed-Sternberg cells of hodgkin's disease. Evidence for a dendritic or B cell derivation?

Immunohistochemical localization of human fascin, a distinct 55-kd actin-bundling protein, was determined for a wide variety of lymphoid tissues (364 specimens total). In non-neoplastic tissues, reactivity was highly selective and localized predominantly in dendritic cells. In the thymus, this protein was distinctly localized to medullary dendritic cells. In reactive nodes, interdigitating reticulum cells of T zones, cells in subcapsular areas, and cells of the reticular network were reactive, with variable reactivity observed for follicular dendritic cells. Splenic dendritic cells of the white pulp and sinus-lining cells of the red pulp were reactive. Endothelial cells of all tissues exhibited variable reactivity. Lymphoid cells, myeloid cells, and plasma cells were uniformly nonreactive. In the peripheral blood, only dendritic (veiled) cells were reactive for fascin. A striking finding was observed for cases of Hodgkin''s disease (total 187 cases). In all cases of nodular sclerosis (132), mixed cellularity (34), lymphocyte depletion (2), and unclassified types (5), all or nearly all Reed-Sternberg cells and variants were immunoreactive for fascin. Neoplastic cells exhibited strong diffuse cytoplasmic staining and frequently assumed dendritic shapes, particularly in the nodular sclerosis type, producing an interdigitating meshwork or syncytial network of cells. In cases of mixed cellularity type, neoplastic cells generally appeared more discrete. In all 14 cases of nodular lymphocyte predominance type, L&H variants were nonreactive. By contrast, neoplastic lymphoid cells of only 24 of 156 (15%) other lymphoid neoplasms (127 B cell, 27 T cell, and two null cell evaluated) were reactive for fascin. Fascin represents a highly effective marker for detection of certain dendritic cells in normal and neoplastic tissues, is an extremely consistent marker for Reed-Sternberg cells and variants of Hodgkin''s disease (except L&H types), and may be helpful to distinguish between Hodgkin''s disease and non-Hodgkin''s lymphoma in difficult cases. The staining profile for fascin raises the possibility of a dendritic cell derivation, particularly an interdigitating reticulum cell, for the neoplastic cells of Hodgkin''s disease, notably in nodular sclerosis type. However, as fascin expression may be induced by Epstein-Barr virus infection of B cells, the possibility that viral induction of fascin in lymphoid or other cell types must also be considered in Epstein-Barr virus-positive cases.     

Morphoproteomics provides support for TGF-β pathway signaling in the osteoclastogenesis and immune dysregulation of osteolytic Langerhans cell histiocytosis

Langerhans cell histiocytosis (LCH) has a challenging and still unclear pathogenesis. A body of literature points to impaired maturation of the lesional dendritic cells, and to immune dysregulation in the form of increased FoxP3 cells. Various cytokine abnormalities such as expression of transforming growth factor (TGF)-β have been reported, as well as abnormalities in lipid content in LCH cells. Morphoproteomic techniques were applied to identify the signal transduction pathways that could influence histogenesis and immune regulation in osteolytic LCH. Five pediatric cases of osteolytic LCH were examined, using antibodies against CD1a, S100, CD68, CD8, FoxP3, phosphorylated (p)-STAT3 (Tyr705), protein kinase C (PKC)-α, phospholipase (PL)D1, fatty acid synthase (FASN), and zinc finger protein, Gli2. Positive and negative controls were performed. A FoxP3(+)/CD8(+) cell ratio was calculated by counting the FoxP3+ and CD8+ cells in 10 high power fields for each case. There is induction of sonic hedgehog (SHH) mediators consistent with TGF-β signaling pathway through Smad3-dependent activation of Gli2, findings supported by the plasmalemmal and cytoplasmic expression of PKC-α and PLD1, and nuclear expression of Gli2, in lesional cells. The FoxP3+/CD8+ cell ratio is increased, ranging from 1.7-7.94. There is moderate cytoplasmic expression of FASN in most of the Langerhans cells, a finding that supports previously published phospholipid abnormalities in LCH and is consistent with PKC-α/PLD1/TGF-β signaling. With our study, we strongly suggest that the TGF-β cell signaling pathway is a major player in the pathogenesis of LCH, leading to non-canonical induction of nuclear Gli2 expression, thereby contributing to osteoclastogenesis in LCH histiocytes. It could also cause a state of immune frustration in LCH, by inducing the transformation of CD4(+)CD25(-) cells into CD4(+)/FoxP3(+) cells. This coincides with the clinical evidence of a response to thalidomide in patients with osteolytic LCH, given its reported ability to reduce TGF-beta 1 and FoxP3 cells. Such TGF-β signaling in osteoclastogenesis and immune dysregulation, and the presence of FASN in the majority of cells, have additional therapeutic implications for osteolytic LCH.     

Gene expression analysis of dendritic/Langerhans cells and Langerhans cell histiocytosis

Langerhans cell histiocytosis (LCH) is a neoplastic disorder that results in clonal proliferation of cells with a Langerhans cell (LC) phenotype. The pathogenesis of LCH is still poorly understood. In the present study, serial analysis of gene expression (SAGE) was applied to LCs generated from umbilical cord blood CD34+ progenitor cells to identify LC-specific genes and the expression of these genes in LCH was investigated. Besides the expression of several genes known to be highly expressed in LCs and LCH such as CD1a, LYZ, and CD207, high expression of genes not previously reported to be expressed in LCs, such as GSN, MMP12, CCL17, and CCL22, was also identified. Further analysis of these genes by quantitative RT-PCR revealed high expression of FSCN1 and GSN in all 12 LCH cases analysed; of CD207, MMP12, CCL22, and CD1a in the majority of these cases; and CCL17 in three of the 12 cases. Immunohistochemistry confirmed protein expression in the majority of cases. The expression of MMP12 was most abundant in multi-system LCH, which is the LCH type with the worst prognosis. This suggests that expression of MMP12 may play a role in the progression of LCH. These data reveal new insight into the pathology of LCH and provide new starting points for further investigation of this clonal proliferative disorder.     

The immunologic properties of epidermal Langerhans cells as a part of the dendritic cell system

Summary Dendritic cells form a system of antigen-presenting cells that is widely distributed in the body. They constitute trace populations in lymphoid and nonlymphoid tissues and in the circulation. They are characterized by their typical dendritic and veiled morphology, by their constitutive expression of high levels of major histocompatibility complex class II molecules on their surface, and by their outstanding capacity to initiate primary immune responses. Dendritic cells occur in two states of differentiation. In the immature state they are highly specialized for processing foreign protein antigens; in the mature state they efficiently stimulate resting antigen-specific T cells. Dendritic cells can migrate from the non-lymphoid tissues, where they reside in the immature state, via the afferent lymphatics or the blood to the T cell-dependent areas of the lymphoid organs (lymph nodes, spleen). There, they appear as mature dendritic cells. Therefore, dendritic cells are ideally suited to mediate important aspects of immunogenicity: they can acquire antigens in the tissues and process them in an immunogenic form; they can carry the immunogen to the lymphoid organs; and they can find and efficiently activate antigen-specific T cell clones and thus generate an immune response. Studies of epidermal Langerhans cells have greatly helped in establishing this concept. They can be investigated freshly isolated from the epidermis where they represent immature (tissue) dendritic cells. After 2–3 days in culture they develop into mature dendritic cells. The mechanisms of dendritic cell maturation, which can be studied best using epidermal Langerhans cells, and the specific functions of Langerhans cells in immunogenicity are discussed.     

Langerhans cell histiocytosis: fascinating dynamics of the dendritic cell–macrophage lineage

Summary: In its rare occurrence, Langerhans cell histiocytosis (LCH) is a dangerous but intriguing deviation of mononuclear phagocytes, especially dendritic cells (DCs). Clinically, the disease ranges from self-resolving or well manageable to severe and even fatal. LCH lesions in skin, bone, and other sites contain high numbers of cells with phenotypic features resembling LCs admixed with macrophages, T cells, eosinophils, and multinucleated giant cells. Here we review current progress in the LCH field based on two central questions: (i) are LCH cells intrinsically aberrant, and (ii) how does the lesion drive pathogenesis? We argue that LCH cells may originate from different sources, including epidermal LCs, tissue Langerin⁺ DCs, or mononuclear phagocyte precursors. Current and prospective in vitro and in vivo models are discussed. Finally, we discuss recent insights into plasticity of T-helper cell subsets in light of the lesion microenvironment. LCH continues to provide urgent clinical questions thereby inspiring innovative DC lineage research.     

Langerhans-cell histiocytosis 'insight into DC biology'

Langerhans-cell histiocytosis (LCH) is caused by an uncontrolled pathogenic clonal proliferation of dendritic cells (DCs) with Langerhans-cell (LC) characteristics. LCH cells are arrested in an immature, partially activated stage and show a deviant regulation of cell division. Their aberrant interactions with T cells and the lesional microenvironment are typified by high level production of diverse cytokines. Chemokine and chemokine receptor patterns probably explain LCH predilection sites and lesion composition, reminiscent of chronic granulomatous inflammation. Recent advances in LCH immunology suggest that clonal changes in DCs might underlie the aberrant immune interaction with T cells, leading to a unique pathological picture, which combines features of carcinogenesis and chronic inflammation.     

CD101 expression by Langerhans cell histiocytosis cells

AIMS: Our objective was to study the expression of a recently identified cell surface molecule, CD101 and in Langerhans cell histiocytosis (LCH) patients as CD101 has been shown to be present on dendritic cells. We wanted to determine if CD101 expression could be helpful for the diagnosis of LCH in conjunction with other markers (CD1a, S100 protein), and could be predictive of the evolution and dissemination of the disease. METHODS AND RESULTS: The expression of CD101 was studied by immunohistochemical technique in 11 cases of Langerhans cell histiocytosis on frozen sections. The expression of CD101 was positive in nine cases, high in six cases and low in three cases. There was no expression in the other two cases. No correlation with the evolution, the localization or the dissemination of the disease could be evidenced. CONCLUSIONS: CD101 is a new phenotypic marker that might be useful in combination with other markers for the diagnosis of LCH. However, as the anti-CD101 antibody works only in frozen sections, its value is limited compared to anti-CD1a antibody.     

Human cytomegalovirus infection in foci of Langerhans cell histiocytosis

 Langerhans cell histiocytosis (LCH) has been thought to be a disorder of immune regulation, and increasingly, evidence showing that the tissue damage in LCH involves lymphokines and pro-inflammatory cytokines is reported. We detected human cytomegalovirus (HCMV)-DNA in LCH cells in the foci of LCH lesions by immunohistochemistry, in situ hybridization and PCR. HCMV was detected in the nuclei and/or cytoplasm of LCH cells in 9 of 27 LCH cases by immunostaining. HCMV was probably an early antigen. In situ hybridization revealed signals for HCMV-DNA only in the nuclei of LCH cells in 10 of the 27 LCH cases. PCR analysis was performed in 20 of the LCH cases, and HCMV-DNA was detected in 7 of these. All 7 positive cases were also positive for HCMV by ISH and IHC. These findings suggested that early phase infection or reactivation of HCMV occurred in the LCH lesions. HCMV infection may be accompanied by impaired cytokine production. Our study also suggested a relationship between HCMV infection and expression of TNFα. In tissues affected by LCH, dermatopathic lymphadenopathy or malignant fibrous histiocytoma and in normal tissues no signals for Epstein-Barr virus-RNA were detected. These findings suggest that in some cases LCH is associated with HCMV infection. Received: 24 November 1998 / Accepted: 24 April 1998     

Sinus histiocytosis with massive lymphadenopathy and Langerhans cell histiocytosis express the cellular adhesion molecule CD31

Context.-We investigated expression of the adhesion molecule CD31 in sinus histiocytosis with massive lymphadenopathy (SHML) and Langerhans cell histiocytosis (LCH) because (1) SHML and LCH cells express a variety of cellular adhesion molecules and (2) SHML has been characterized as a reactive histiocytic proliferation, and tissue macrophages (histiocytes) are known to express CD31. Objective.-The purpose of this study was to determine whether SHML and LCH cells express CD31 and whether dual staining with CD31 and S100 facilitates diagnosis of these disease states. Methods.-Formalin-fixed, paraffin-embedded archival tissues were immunohistochemically stained via the labeled streptavidin-biotin method using antibodies against CD31 and S100 protein after heat-induced epitope retrieval. Archival tissues included SHML (n = 2), LCH (n = 10), malignant melanoma (n = 5), sinus hyperplasia (n = 4), granulomas (n = 4), granular cell tumor (n = 6), and normal skin (n = 4). Results.-Normal Langerhans cells in the epidermis were CD31(-)/S100(+); neoplastic Langerhans cells in LCH were CD31(+)/S100(+). Histiocytes in granulomas and in sinus hyperplasia were CD31(+)/S100(-); abnormal histiocytes in SHML were CD31(+)/S100(+). S100(+) tumors (malignant melanoma and granular cell tumor) were CD31(-). Conclusions.-The spectrum of cell types that express CD31 is expanded to include SHML and LCH. We speculate that up-regulation of CD31 in neoplastic Langerhans cells contributes to the migratory capability of LCH cells. CD31 may be a useful nonlysosomal marker of macrophages and their neoplastic counterparts (true histiocytic sarcomas). An immunohistochemical staining panel that includes CD31 and S100 facilitates the diagnosis of SHML and LCH.     

Oral manifestations of Langerhans cell histiocytosis with unusual histomorphologic features

Langerhans cell histiocytosis (LCH) is a bone marrow-derived immature myeloid dendritic cell proliferative disorder with diverse clinical manifestations commonly involves bone, skin, lymph node and lung. Oral involvement is uncommon. Intraoral lesions can be the first sign of either a localized LCH or clinically undiagnosed systemic LCH, predates systemic manifestations of LCH, or an early indicator of recurrence in known cases. Clinically, it can be mistaken for primary oral and dental inflammatory, infectious and neoplastic lesions. Histologically, diagnostic challenges may arise because of the nature of oral and dental specimens, different tissue reaction patterns and variations in histomorphology of LCH. We performed a retrospective review study over 10 years. We searched for diagnosed cases of LCH. We retrieved and reviewed cases of LCH with oral involvement. We found 54 cases of LCH, four (7.4%) with oral involvement. The age range was between 1 and 27 years with an average age of 13.7 years. They were males. They were clinically confused with abscess, cysts, infection, granulation tissue and other neoplastic lesions. Histologically, they showed different histopathologic features including different patterns of necrosis, granulomas, allergic-like inflammation, superimposed infection, stomatitis, cyst and sinus formation, foreign body giant cell reaction, and foci mimicking lymphomas and metastasis. Certain cytologic features were helpful hints. In doubtful cases, immunohistochemistry helped confirm the diagnosis. Because of the multiple fragmented nature of oral specimens with different tissue reaction patterns, the diagnostic Langerhans cells may be missed or misinterpreted. Oral LCH may be confused with infectious, inflammatory, benign and malignant neoplastic lesions because of its variable clinical presentations and its heterogeneous histomorphologic features. Pathologists have an important role in guiding clinicians to the correct diagnosis and patients' management. They should be familiar with the different histomorphologic patterns to avoid pitfalls. Attention to certain morphologic features and immunohistochemistry should help resolve challenging cases.     

Human melanocytes and melanoma cells constitutively express the Bcl-2 proto-oncogene in situ and in cell culture.

The Bcl-2 proto-oncogene regulates cell survival by antagonizing events that lead to apoptotic cell death and has been reported to be expressed in situ in lymphoid tissues, glandular epithelium, neurons, and basal epidermal cells. When we performed immunostaining on cryostat sections of normal skin, anti-Bcl-2 reactivity was confined to scattered dendritic cells in the basal epidermal layer. Double-staining experiments showed that the Bcl-2+ cells were positive for vimentin but negative for cytokeratins, CD1a, and CD45 antigens, excluding keratinocytes and Langerhans cells as possible candidates for constitutive Bcl-2 expression. Bcl-2+ epidermal cells also reacted with the monoclonal anti-melanocyte antibody NKI/beteb, and were absent from lesional skin in vitiligo, confirming that they represented epidermal melanocytes. Western blot analysis of cultured melanocytes and melanoma cell lines revealed a 26-kd protein specifically reacting with the anti-Bcl-2 monoclonal antibody. Immunostaining of pigmented lesions revealed strong expression of Bcl-2 by five of five nevocellular nevi and seven of seven melanomas. Our observations demonstrate that, within normal human epidermis, melanocytes are the only cells that express Bcl-2 constitutively and that Bcl-2 is expressed in benign and malignant pigmented tumors of the skin in situ.     

Expression of GM-CSF receptor by Langerhans' cell histiocytosis cells

Langerhans' cell histiocytosis (LCH) is characterized by the proliferation of large mononucleated cells containing Birbeck granules and expressing CD1a. Recent studies have demonstrated that LCH is a clonal proliferation; however, its aetiology is still unknown. Growth and differentiation of bone-marrow-derived cells are controlled by cytokines. The proliferation, differentiation and activation of normal Langerhans cells are controlled by granulocyte/macrophage colony-stimulating factor (GM-CSF) in vitro. Therefore, GM-CSF could be implicated in the pathogenesis of LCH. Indeed, LCH cells contain GM-CSF, and children with disseminated LCH have an elevated GM-CSF serum level. As a cytokine only acts on cells expressing a specific receptor, we investigated the presence of GM-CSF receptor on LCH cells. Fourteen frozen tissue samples from children with LCH were studied by in situ immunohistochemistry with two mouse monoclonal antibodies specific for the chain of the GM-CSF receptor (CDw116). LCH cells of all the samples were positively stained with both antibodies. This study suggests that GM-CSF may be a growth factor for LCH cells.This work was supported by grants from the Groupe de Recherche en Immuno-Pathologie, the Histiocyte Society of America and the Ministère de la Santé (PHRC 94B)     

Immunohistochemical study on antigenic phenotype of Langerhans cell histiocytosis.

Immunohistochemical study on 26 cases of Langerhans cell histiocytosis (LCH) using several leukocyte antibodies in addition to traditionally used markers (S-100 protein and peanut agglutinin) revealed that the proliferating cells of LCH expressed UCHL1, MT1 as well as classically known positivity for S-100 protein, HLA-DR and peanut agglutinin but were negative for OPD4. In comparison to S-100 protein peanut agglutinin (PNA) using a two stage method produced weaker staining and positively stained cells were sparse. Also in this study, a small proportion of proliferating cells in LCH was observed to be reactive for both myeloid/macrophage antigens (KPI, MAC 387 and lysozyme) and Langerhans cell marker (S-100 protein), verifying the existence of a hybrid form of histiocytes.     

Langerhans cell histiocytosis presenting as a thyroid gland mass

We report 2 cases of Langerhans cell histiocytosis (LCH) presenting as a thyroid mass. The first case is a 45-year-old woman with a 13-year history of diabetes insipidus who presented with an enlarging thyroid mass with substernal extension. The second case is a 29-year-old man who presented with an enlarging thyroid mass and skin lesions. Histologic evaluation of the thyroid gland in both cases revealed extensive involvement by LCH, confirmed by immunohistochemical analysis showing Langerhans cells that were positive for CD1a and S-100 protein. Langerhans cell histiocytosis can rarely involve the thyroid gland in adults, and we have identified 30 cases reported in literature. Most patients had evidence of LCH involving other anatomic sites, as was true in these 2 cases, and the diagnosis was initially established by examination of other sites in a subset of patients. Affected patients frequently have diabetes insipidus, as was true in case 1. Thyroid gland involvement as the initial presentation of LCH is a rare phenomenon that can result in misdiagnosis.     

High expression of markers of apoptosis in Langerhans cell histiocytosis

AIMS: Langerhans cell histiocytosis is a rare disease with clonal proliferation of dendritic histiocytes, occurring most frequently in infancy and early childhood. In the localized form (single system), the disease is self-limiting, but in the cases of multisystem disease a third of the patients develop organ dysfunction. In these cases the prognosis is poor. Our objective has been to study the immunohistochemical expression of Fas and Fas-ligand (Fas-L) in order to determine whether the level of expression of these proteins could predict the outcome of the disease. We also wanted to determine the number of apoptotic cells to compare with the expression of Fas and Fas-L. METHODS AND RESULTS: We analysed the expression of Fas and Fas-L in 76 infiltrates from 49 paediatric patients with Langerhans cell histiocytosis. We also compared the results with the expression of the tumour suppressor protein p53 and the number of cells in apoptosis detected with TUNEL. Langerhans cell histiocytosis cells showed strong expression of p53 and in some cases co-expression of Fas and Fas-L. The expression of Fas-L was significantly higher in infiltrates from patients with single-system disease. The actual number of pathological Langerhans cells in apoptosis as estimated by TUNEL was low. CONCLUSIONS: The low number of TUNEL-reactive cells can be explained by the rapid turnover of apoptotic cells in the tissue, not leaving the apoptotic cells long enough in the tissue to be detected. The co-expression of Fas and Fas-L in some Langerhans cells can lead to an autocrine apoptotic shortcut, mediating the death of the double-positive cells. Our findings suggest that apoptosis mediated through the Fas/Fas-L pathway may contribute to the spontaneous regression of lesions in single-system disease. A delicate balance between autocrine death and survival of Langerhans cells may have been disturbed in patients with multisystem lesions.     

No genomic aberrations in Langerhans cell histiocytosis as assessed by diverse molecular technologies

The etiology of Langerhans cell histiocytosis (LCH), a disease characterized by uncontrolled proliferation of Langerhans cells, is unknown. Although some believe that LCH is reactive, others support a neoplastic origin. We tested the hypothesis that LCH is neoplastic by investigating potential consistent chromosomal aberrations in LCH cells. We used multiparameter DNA flow cytometry to analyze the DNA ploidy LCH cells in 20 cases, performed karyotype analysis in 31 cases, array‐based comparative genomic hybridization (arrayCGH) and single nucleotide polymorphism (SNP) arrays with DNA from flow‐sorted CD1a‐positive and CD1a‐negative cells in 19 cases. Ploidy analysis revealed diploid DNA content in all cases. The karyotype of all patients analyzed was normal, excluding the presence of balanced translocations. ArrayCGH and SNP arrays did not show genome abnormalities. Despite positive TP53 protein immunohistochemical staining, sequencing of exon 5 to 8 of p53 gene showed no alterations in 7 cases. This study strongly suggests that gross chromosomal abnormalities do not cause LCH. Although we cannot exclude cryptic point mutations in as yet unidentified genes, this study of 72 LCH cases shows that LCH may be the result of restricted oligoclonal stimulation rather than unlimited neoplastic proliferation. © 2008 Wiley‐Liss, Inc.