Showing papers on "Transdifferentiation published in 2001"

Transforming Growth Factor-β1 Mediates Epithelial to Mesenchymal Transdifferentiation through a RhoA-dependent Mechanism

Abstract: Transforming growth factor-beta1 (TGF-beta) can be tumor suppressive, but it can also enhance tumor progression by stimulating the complex process of epithelial-to-mesenchymal transdifferentiaion (EMT). The signaling pathway(s) that regulate EMT in response to TGF-beta are not well understood. We demonstrate the acquisition of a fibroblastoid morphology, increased N-cadherin expression, loss of junctional E-cadherin localization, and increased cellular motility as markers for TGF-beta-induced EMT. The expression of a dominant-negative Smad3 or the expression of Smad7 to levels that block growth inhibition and transcriptional responses to TGF-beta do not inhibit mesenchymal differentiation of mammary epithelial cells. In contrast, we show that TGF-beta rapidly activates RhoA in epithelial cells, and that blocking RhoA or its downstream target p160(ROCK), by the expression of dominant-negative mutants, inhibited TGF-beta-mediated EMT. The data suggest that TGF-beta rapidly activates RhoA-dependent signaling pathways to induce stress fiber formation and mesenchymal characteristics.

Advanced glycation end products cause epithelial-myofibroblast transdifferentiation via the receptor for advanced glycation end products (RAGE)

Abstract: Tubulointerstitial disease, a prominent phenomenon in diabetic nephropathy, correlates with decline in renal function. The underlying pathogenic link between chronic hyperglycemia and the development of tubulointerstitial injury has not been fully elucidated, but myofibroblast formation represents a key step in the development of tubulointerstitial fibrosis. RAGE, the receptor for advanced glycation end products (AGEs), induces the expression of TGF-beta and other cytokines that are proposed to mediate the transdifferentiation of epithelial cells to form myofibroblasts. Here we report specific binding of (125)I-AGE-BSA to cell membranes prepared from a rat proximal tubule cell line and show that the binding site was RAGE. AGE exposure induced dose-dependent epithelial-myofibroblast transdifferentiation determined by morphological changes, de novo alpha smooth-muscle actin expression, and loss of epithelial E-cadherin staining. These effects could be blocked with neutralizing Ab's to RAGE or to TGF-beta. Transdifferentiation was also apparent in the proximal tubules of diabetic rats and in a renal biopsy from a patient with type 1 diabetes. The AGE cross-link breaker, phenyl-4,5-dimethylthiazolium bromide (ALT 711) reduced transdifferentiation in diabetic rats in association with reduced tubular AGE and TGF-beta expression. This study provides a novel mechanism to explain the development of tubulointerstitial disease in diabetic nephropathy and provides a new treatment target.

Transforming Growth Factor β1 Treatment Leads to an Epithelial-Mesenchymal Transdifferentiation of Pancreatic Cancer Cells Requiring Extracellular Signal-regulated Kinase 2 Activation

Abstract: The aim of this study was to examine the effects of transforming growth factor (TGF) beta1 on the phenotype and the biological behavior of pancreatic cancer cell lines with and without mutations in the TGF-beta signaling pathway and to elucidate whether the Ras signaling cascade participates in mediating these effects of TGF-beta1. TGF-beta-responsive (PANC-1, COLO-357, and IMIM-PC1) and nonresponsive (CAPAN1 and IMIM-PC2) pancreatic cancer cell lines with activating mutations of the Ki-Ras oncogene were treated with 10 ng/ml TGF-beta1 over time. Phenotypic alterations were studied by electron and phase contrast microscopy and by immunohistochemistry and expression analyses of differentiation markers. The influence of TGF-beta on tumor cell scattering, migration, and invasion was determined. The role of the Ras-mitogen-activated protein kinase kinase (MEK)-extracellular signal-regulated kinase (ERK) cascade in mediating TGF-beta-induced morphological and functional effects were studied by pretreatment with the MEK1 inhibitor PD 98059 and by measuring ERK2 activation using immune complex kinase assays. TGF-beta1 led to a reversible and time-dependent epithelial-mesenchymal transdifferentiation (EMT) in TGF-beta-responsive pancreatic cancer cell lines, characterized by a fibroblastoid morphology and an up-regulation of mesenchymal markers and a down-regulation of epithelial markers. EMT was associated with an increase in tumor cell migration, invasion, and scattering. In the responsive cell lines, TGF-beta1 induced a moderate but sustained activation of ERK2. EMT, the concomitant changes in gene expression, and the invasive and migratory potential were reduced or abolished by pretreatment with the selective MEK1 inhibitor. Thus, in TGF-beta-responsive pancreatic cancer cells with activating Ki-Ras mutations, TGF-beta1 treatment caused an EMT associated with a more invasive phenotype. Cross-talk with the Ras-MEK-ERK-signaling cascade appears to be essential for mediating these effects of TGF-beta1.

Renal Fibrosis: Collagen Composition and Assembly Regulates Epithelial-Mesenchymal Transdifferentiation

Abstract: Type IV collagen is a major component of basement membranes and it provides structural and functional support to various cell types. Type IV collagen exists in a highly complex suprastructure form and recent studies implicate that protomer (the trimeric building unit of type IV collagen) assembly is mediated by the NC1 domain present in the C-terminus of each collagen α-chain polypeptide. Here we show that type IV collagen contributes to the maintenance of the epithelial phenotype of proximal tubular epithelial cells, whereas type I collagen promotes epithelial-to-mesenchymal transdifferentiation (EMT). In addition, the recombinant human α1NC1 domain inhibits assembly of type IV collagen NC1 hexamers and potentially disrupts the deposition of type IV collagen, facilitating EMT in vitro. Inhibition of type IV collagen assembly by the α1NC1 domain up-regulates the production of transforming growth factor-β1 in proximal tubular epithelial cells, an inducer of EMT. These results strongly suggest that basement membrane architecture is pivotal for the maintenance of epithelial phenotype and that changes in basement membrane architecture potentially lead to up-regulation of transforming growth factor-β1, which contributes to EMT during renal fibrosis.

Role of Muller cells in retinal degenerations.

Abstract: Muller (radial glial) cells span the entire thickness of the retina, and contact and ensheath every type of neuronal cell body and process. This morphological relationship is reflected by a multitude of functional interactions between retinal neurons and Muller cells, including extracellular ion homeostasis and glutamate recycling by Muller cells. Virtually every disease of the retina is associated with a reactive Muller cell gliosis. Muller cell gliosis may either support the survival of retinal neurons or accelerate the progress of neuronal degeneration. Muller cells are key mediators of nerve cell protection, especially via release of basic fibroblast growth factor, via uptake and degradation of the excitotoxin glutamate, and via secretion of the antioxidant glutathione. Neovascularization during hypoxic conditions is mediated by Muller cells via release of vascular endothelial growth factor and transforming growth factor beta or via direct contact to endothelial cells. Primary Muller cell insufficiency has been suggested to be the cause of different cases of retinal degeneration including hepatic and methanol-induced retinopathy and glaucoma. It is conceivable that, in the future, new therapeutic strategies may utilize Muller cells for, e.g., somatic gene therapy or transdifferentiation of retinal neurons from dedifferentiated Muller cells.

Aortic Valve Endothelial Cells Undergo Transforming Growth Factor-β-Mediated and Non-Transforming Growth Factor-β-Mediated Transdifferentiation in Vitro

Abstract: Cardiac valves arise from endocardial cushions, specialized regions of the developing heart that are formed by an endothelial-to-mesenchymal cell transdifferentiation. Whether and to what extent this transdifferentiation is retained in mature heart valves is unknown. Herein we show that endothelial cells from mature valves can transdifferentiate to a mesenchymal phenotype. Using induction of α-smooth muscle actin (α-SMA), an established marker for this process, two distinct pathways of transdifferentiation were identified in clonally derived endothelial cell populations isolated from ovine aortic valve leaflets. α-SMA expression was induced by culturing clonal endothelial cells in medium containing either transforming growth factor-β or low levels of serum and no basic fibroblast growth factor. Cells induced to express α-SMA exhibited markedly increased migration in response to platelet-derived growth factor-BB, consistent with a mesenchymal phenotype. A population of the differentiated cells co-expressed CD31, an endothelial marker, along with α-SMA, as seen by double-label immunofluorescence. Similarly, this co-expression of endothelial markers and α-SMA was detected in a subpopulation of cells in frozen sections of aortic valves, suggesting the transdifferentiation may occur in vivo. Hence, the clonal populations of valvular endothelial cells described here provide a powerful in vitro model for dissecting molecular events that regulate valvular endothelium.

The adipose organ: morphological perspectives of adipose tissues.

Abstract: Adipose tissue of an individual, generally regarded as connective tissues without a specific anatomy, consists of many adipose depots that are organized to form a large organ with discrete anatomy, specific vascular and nerve supplies, complex cytology, and high physiological plasticity. The authors discuss anatomy and morphology, plasticity of adipose tissue, plasticity of adipose tissue and adipose stem cells, ADSCs and their use in regenerative medicine, plasticity of adipose tissue and the role of mature adipocytes (the phenomenon of transdifferentiation), white to brown transdifferentiation, and adipo-epithelial transdifferentiation. Adipose tissue, despite its simple appearance and morphology, represents a complex structure with highly plastic properties. These capacities are due to the nature of its parenchymal cells, the adipocytes, that are unique specialized cells involved in fuel storage, management and endocrine, nervous, and immune function and that are even provided with the ability to reprogram their genes and transdifferentiate into cells with a different morphology and physiology.

IL-4 determines eicosanoid formation in dendritic cells by down-regulation of 5-lipoxygenase and up-regulation of 15-lipoxygenase 1 expression

Abstract: Dendritic cell (DC) differentiation from human CD34(+) hematopoietic progenitor cells (HPCs) can be triggered in vitro by a combination of cytokines consisting of stem cell factor, granulocyte-macrophage colony-stimulating factor, and tumor necrosis factor alpha. The immune response regulatory cytokines, IL-4 and IL-13, promote DC maturation from HPCs, induce monocyte-DC transdifferentiation, and selectively up-regulate 15-lipoxygenase 1 (15-LO-1) in blood monocytes. To gain more insight into cytokine-regulated eicosanoid production in DCs we studied the effects of IL-4/IL-13 on LO expression during DC differentiation. In the absence of IL-4, DCs that had been generated from CD34(+) HPCs in response to stem cell factor/granulocyte-macrophage colonystimulating factor/tumor necrosis factor alpha expressed high levels of 5-LO and 5-LO activating protein. However, a small subpopulation of eosinophil peroxidase(+) (EOS-PX) cells significantly expressed 15-LO-1. Addition of IL-4 to differentiating DCs led to a marked and selective down-regulation of 5-LO but not of 5-LO activating protein in DCs and in EOS-PX(+) cells and, when added at the onset of DC differentiation, also prevented 5-LO up-regulation. Similar effects were observed during IL-4- or IL-13-dependent monocyte-DC transdifferentiation. Down-regulation of 5-LO was accompanied by up-regulation of 15-LO-1, yielding 15-LO-1(+) 5-LO-deficient DCs. However, transforming growth factor beta1 counteracted the IL-4-dependent inhibition of 5-LO but only minimally affected 15-LO-1 up-regulation. Thus, transforming growth factor beta1 plus IL-4 yielded large mature DCs that coexpress both LOs. Localization of 5-LO in the nucleus and of 15-LO-1 in the cytosol was maintained at all cytokine combinations in all DC phenotypes and in EOS-PX(+) cells. In the absence of IL-4, major eicosanoids of CD34(+)-derived DCs were 5S-hydroxyeicosatetraenoic acid (5S-HETE) and leukotriene B(4), whereas the major eicosanoids of IL-4-treated DCs were 15S-HETE and 5S-15S-diHETE. These actions of IL-4/IL-13 reveal a paradigm of eicosanoid formation consisting of the inhibition of one and the stimulation of another LO in a single leukocyte lineage.

Transforming Growth Factor-β, Basement Membrane, and Epithelial-Mesenchymal Transdifferentiation : Implications for Fibrosis in Kidney Disease

Abstract: Interstitial fibrosis is characteristic of many clinical entities including diabetes, ureteral obstruction, transplant rejection, and glomerulonephritis. 1 The interstitial fibrosis that accompanies renal disease is a complex process involving derangements in both the synthesis and degradation of collagen and other extracellular matrix proteins. Cellular sources of the extracellular matrix laid down during the development of interstitial fibrosis include fibroblasts and infiltrating macrophages. 1 The fibroblasts may be resident renal fibroblasts, fibroblasts that migrate into the kidney from external sources, or a specialized population of fibroblasts known as myofibroblasts. 2 Furthermore, recent evidence suggests that during renal injury, renal epithelial cells may transform into fibroblasts in a process known as epithelial-mesenchymal transdifferentiation (EMT). 3,4 The synthesis and processing of extracellular matrix that malfunction in fibrosis are under the complex control of many cytokines and other factors. 1 One cytokine in particular that has been implicated in fibrotic disease, both in the kidney and in other tissues, is transforming growth factor-β (TGF-β). In the accompanying article “Renal Fibrosis: Collagen Composition and Assembly Regulates Epithelial-Mesenchymal Transdifferentiation,” by Zeisberg and colleagues 5 in this issue of The American Journal of Pathology, Zeisberg and co-workers use murine renal cell lines in culture to demonstrate that the integrity of basement membrane collagen has a significant effect on EMT in vitro. They further demonstrate that when basement membrane assembly is disrupted, the production of TGF-β is up-regulated. In this article we will discuss the emerging role of EMT in fibrosis and its regulation, both in vitro and in vivo, with emphasis on effects of TGF-β and collagen IV.

Posttransplantation Relapse of FSGS Is Characterized by Glomerular Epithelial Cell Transdifferentiation

Abstract: This study examined six cases of idiopathic nephrotic syndrome with primary lesions of focal segmental glomerulosclerosis (FSGS) that relapsed after renal transplantation. The glomerular lesions comprised the cellular, the collapsing, and the scar variants of FSGS and showed shedding of large round cells into Bowman's space and within the tubular lumens. Immunohistochemistry and confocal laser microscopy carried out on kidneys with FSGS relapse disclosed several phenomena. (1) Some podocytes that expressed podocalyxin, synaptopodin, and glomerular epithelial protein-1 were detached from the tuft and were free in the urinary space. (2) In the cellular variant, most podocytes had lost podocyte-specific epitopes (podocalyxin, synaptopodin, glomerular epithelial protein-1, Wilm's tumor protein-1, complement receptor-1, and vimentin). In the scar variant, these podocyte markers were absent from cobblestone-like epithelial cells and from pseudotubules. (3) Podocytes had acquired expression of various cytokeratins (CK; identified by the AE1/AE3, C2562, CK22, and AEL-KS2 monoclonal antibodies) that were not found in the podocytes of control glomeruli. Parietal epithelial cells expressed AE1/AE3 CK that were faintly, if ever, found on the parietal epithelial cells of normal glomeruli. (4) Numerous cells located at the periphery of the tuft or free in Bowman's space and within tubular lumens expressed macrophagic epitopes (identified by PGM1 [CD68], HAM56, and 25F9 monoclonal antibodies). These macrophage-like cells expressed the activation epitopes HLA-DR and CD16. (5) A number of these cells coexpressed podocalyxin + AE1/AE3 CK, podocalyxin + CD68, and CD68 + AE1/AE3. These findings suggest that in primary FSGS relapsing on transplanted kidneys, some "dysregulated" podocytes, occasionally some parietal epithelial cells, and possibly some tubular epithelial cells undergo a process of transdifferentiation. This process of transdifferentiation was especially striking in podocytes that acquired macrophagic and CK epitopes that are absent from normal adult and fetal podocytes.

Transdifferentiation of polymorphonuclear neutrophils: acquisition of CD83 and other functional characteristics of dendritic cells

Abstract: Polymorphonuclear neutrophils (PMN) are in the first line of defense against bacterial infections. They are considered to be end-differentiated cells undergoing constitutive apoptosis within hours after release from the bone marrow. During pathological events, however, their life span is extended in conjunction with morphological and functional alterations indicative of a transdifferentiation of mature PMN. To further characterize differentiated PMN, the alterations seen in vivo were reproduced by cultivating PMN of healthy donors with either γ-interferon, granulocyte/macrophage colony stimulating factor, or a combination thereof. Thus cultivated cells escaped from apoptosis, and protein synthesis was induced, notably of the major histocompatibility complex (MHC) class II antigens, CD80 and CD86. Moreover, CD83, thought to be specific for dendritic cells was synthesized, while typical markers of PMN, including CD66b, CD11a/CD11b/CD11c, CD15, CD18 were preserved. A profound alteration of both cellular morphology and of function was seen: the cultivated PMN lost their chemotactic activity but had acquired the ability to present to T-cells a peptide antigen in a MHC class II restricted manner. The data lead to the conclusion that mature PMN can differentiate further to cells with characteristics of DCs, thereby connecting PMN to the specific T-cell response.

Transdifferentiation of pigmented epithelial cells: a source of retinal stem cells?

Abstract: In urodeles, larval anurans, embryonic chicks and rodents, the retinal pigmented epithelium (RPE) is capable of transdifferentiation and generating new neurons. Recent evidence suggests that pigmented cells in the ciliary body of the adult rodent eye are capable of producing new neurons in vitro. Here we provide data to suggest that the pigmented epithelium at the retinal margin of postnatal chickens is similar to that found in the embryonic retina. Pigmented cells at the retinal margin expressed mitf and pax6, transcription factors that are transiently expressed by the developing RPE. Furthermore, these pigment cells at the retinal margin express high levels of proliferating cell nuclear antigen and accumulate bromodeoxyuridine, indicating that they continue to proliferate long after embryonic stages of development. Exogenous fibroblast growth factor-2 (FGF2) or insulin alone did not affect the proliferation of these cells, while FGF2 plus insulin induced their proliferation and loss of pigmentation. We propose that the pigmented cells at the retinal margin of the postnatal chicken are similar to those found in the embryonic eye, and these cells could be a source of neural regeneration under appropriate conditions.

Conversion of pancreatic cells to hepatocytes.

Abstract: Transdifferentiation is the name used to describe the conversion of one differentiated cell type to another. During development, the liver and pancreas arise from the same region of the endoderm and cells from the two organs can transdifferentiate in the adult under different experimental procedures. We have produced two in vitro models for the transdifferentiation of pancreatic cells to hepatocytes. The first utilizes a pancreatic exocrine cell line AR42J-B13 and the second comprises cultures of mouse embryonic pancreas. We have analysed the pancreatic hepatocytes and they express a range of liver markers including albumin, transferrin and transthyretin. We also present evidence for (i) the molecular mechanism which regulates the conversion between pancreas and liver and (ii) the cellular basis of the switch in phenotype.

Transdifferentiation of human islet cells in a long-term culture.

Abstract: It has been established that ductal cells or precursor cells within the ductal tree of the pancreas can differentiate into islet cells. Although islet cells can also form exocrine cells, it is unclear whether they arise from precursor (stem) cells or from mature endocrine cells by transdifferentiation. Using a defined culture medium and technique for islet purification, for the first time we were able to maintain human islets in culture for more than a year. Multilabeling immunohistochemical and immunoelectron microscopic examination of the islets at different days of culture using islet cell markers (antibodies to hormones, neuron-specific enolase, chromogranin A) and ductal cell markers (cytokeratins 7 and 19, carbonic anhydrase II, DU-PAN2, CA 19-9, and MUC1) revealed that endocrine cells gradually transdifferentiate to ductal, acinar, and intermediary cells. Although islet hormone secretion ceased after day 28 in culture, endocrine cells were still detectable at day 60. However, later, all endocrine and exocrine cells were replaced by undifferentiated cells that expressed neuron-specific enolase, chromogranin A, laminin, vimentin, cytokeratin 7 and 19, alpha-1-antitrypsin, transforming growth factor-alpha, and epidermal growth factor receptor. Our data thus show that, under proper conditions, human islets can be maintained in vitro over a long period and that, in the culture condition, islet cells seem to transdifferentiate to exocrine cells and undifferentiated cells, which may be considered pancreatic precursor (stem) cells.

LIM-domain protein cysteine- and glycine-rich protein 2 (CRP2) is a novel marker of hepatic stellate cells and binding partner of the protein inhibitor of activated STAT1.

Abstract: Activation of hepatic stellate cells is considered to be the main step in the development of liver fibrosis, which is characterized by the transition of quiescent vitamin-A-rich cells to proliferative, fibrogenic and contractile myofibroblasts. The identification of regulatory genes during early cell activation and transdifferentiation is essential to extend our knowledge of hepatic fibrogenesis. In liver, the gene CSRP2 is exclusively expressed by stellate cells, whereas no transcripts are detectable in hepatocytes, sinusoidal endothelial cells or Kupffer cells. The early activation of stellate cells induced by platelet-derived growth factor is accompanied by an enhanced expression of CSRP2. During later stages of transdifferentiation, the expression of CSRP2 in these cells is suppressed in vitro and in vivo. The CSRP2-encoded cysteine- and glycine-rich double-LIM-domain protein (CRP)2 is proposed to function as a molecular adapter, arranging two or more as yet unidentified protein constituents into a macromolecular complex. To identify these proteins and assign a cellular function to CRP2, a human cDNA library was screened with full-length CRP2 as bait in a yeast two-hybrid screen. The protein inhibitor of activated STAT1 ('PIAS1') was shown to associate selectively with the C-terminal LIM domain of CRP2. Physical interaction of both proteins in the cellular environment was confirmed by co-localization experiments with confocal laser scanning microscopy and co-immunoprecipitation analysis. These results establish CRP2 as a potential new factor in the JAK/STAT-signalling pathway and suggest that the suppression of CSRP2 might be a prerequisite for the myofibroblastic transition of hepatic stellate cells.

Epitheliomesenchymal transdifferentiation of cultured RPE cells

Abstract: Retinal pigment epithelium (RPE) cells of the proliferative vitreoretinopathy (PVR) membrane take on the shape of fibroblasts and participate in fibrosis, thus deviating from the character of epithelial cells. This study was undertaken to evaluate RPE cell transdifferentiation in vitro. During the culture of porcine RPE cells, primary and 10th-passaged RPE cells were investigated for cell growth in response to transforming growth factor (TGF) β2, change of phenotype and amount in collagen synthesis as well as expression of α-smooth-muscle actin (α-SMA). TGF-β2 inhibited the proliferation of the primary cultures of RPE cells in a dose-dependent manner, while the spindle-shaped 10th-passaged RPE cells were not inhibited by TGF-β2. The 10th-subcultured cells did not show much difference in the quality of collagen synthesis, other than type VIII collagen which was not produced. Collagen synthesis was dose-dependently stimulated by TGF-β2. The stimulation by TGF-β2 in the 10th-passaged RPE cells was much greater than in primary RPE cells. The 10th-subcultured RPE cells produced substantial α-SMA compared to α-SMA production by primary RPE cells. These results were also observed by confocal laser microscopy. These findings indicated that RPE metaplasia resulting in a change of biological cell behavior might be a necessary predisposing step in the development of PVR.

Factors mediating the transdifferentiation of islets of Langerhans to duct epithelial-like structures.

Abstract: We have previously shown that isolated islets embedded in type 1 collagen gel in the presence of a defined medium undergo transdifferentiation within 96 h to duct epithelial structures. The aim of this study was to identify the factors implicated in this process. Freshly isolated canine islets were embedded in type 1 collagen gel, Matrigel or agarose for up to 120 h and cultured in (i) Dulbecco's modified Eagle's medium (DMEM)/F12 plus cholera toxin (CT), (ii) medium CMRL1066 plus CT, (iii) CMRL1066 plus forskolin and (iv) CMRL1066 alone. At 16 h, intracellular levels of cAMP (fmol/10(3) islets) were increased in groups i-iii (642+/-17, 338+/-48, 1128+/-221) compared with group iv (106+/-19, P<0.01). Epithelial differentiation correlated with the total amount of intracellular cAMP measured over 120 h. Islet-epithelial transformation during the initial 36 h was associated with a wave of apoptosis which was followed by a wave of cell proliferation. During epithelial differentiation there was a progressive loss of all islet hormones and the concomitant expression of cytoskeletal proteins characteristic of duct epithelial cells. Islets in collagen and Matrigel demonstrated high rates of epithelial differentiation (63+/-2% and 71+/-4% respectively) compared with those in agarose gel (0+/-0%, P<0.001). Islets suspended in DMEM/F12 plus CT supplemented with soluble laminin or fibronectin did not undergo transformation. Prior incubation of freshly isolated islets with an integrin-binding arginine-glycine-aspartate motif-presenting synthetic peptide also reduced islet transformation. These studies confirm the biological potential of islets of Langerhans to differentiate to duct epithelial structures. cAMP-mediated signal transduction and an appropriate integrin-matrix interaction are necessary for this process to proceed.

Morphostats: a missing concept in cancer biology.

Abstract: The role of specific morphogens is well established in the determination of body plans in development. A variety of morphogens have been identified; others are suspected. Pathways have been delineated. In complex tissues, the ability to maintain fidelity of microarchitectural structure is crucial. Microarchitecture is a consequence of relationships among cells, not a function of single cells. Epithelial layers, in particular, are able to maintain their microarchitecture with remarkable accuracy over many decades despite recurrent damage, regular cell turnover, and complexity of structure. Nonetheless, metaplasia and transdifferentiation (change in tissue structure without cell dysplasia) do occur, suggesting that there is the possibility of loss of control or change of control of the microarchitecture. A strong inference to be derived from the above is that there are control systems and molecules and that these are derived from cells that are outside, but plausibly adjacent to, the respective epithelia. It is postulated is that there are morphogen-like controller molecules with morphogen-like functions in adult epithelial tissues. These are responsible for the maintenance of normal tissue microarchitecture. Because the function of these putative molecules is maintenance of tissue structure, I have chosen to call them morphostats by analogy with morphogens. It seems plausible that morphostats and morphogens may constitute overlapping families of molecules. Evidence for the existence of morphostats can be derived from a variety of in vivo and in vitro data and from studies of normal tissue, precancer, and cancer, including: (a) the existence but rarity of metaplasia and transdifferentiation; (b) the fact that metaplasias are multicentric and are only one step from normal but do not show any consistent epithelial mutation; (c) the genesis of animal cancers by simple transplantation of tissues into the wrong environment and the evidence that epithelial mutation is not a feature of such transplantation carcinogenesis; (d) the fact that carcinogenesis occurs frequently at the junctions of different epithelial types, e.g., squamocolumnar junctions in gastrointestinal and genital tracts; (e) the fact that cancer-associated fibroblasts can stimulate proliferation in transformed cells but not influence normal cells; and (f) the failure to grow most epithelial organs in a fully differentiated structural pattern in monolayer culture. It is suggested that morphostats may function like morphogens inasmuch as they may act via a diffusion gradient from source mesenchymal cells and provide architectural instruction for complex adult epithelia. Morphostats may influence architecture via control of cell adhesion, apoptosis, and proliferation. Some specific predictions follow from this hypothesis, most notably, a new two-hit model of cancer: one mutation in an epithelial cell resulting in disruption of cell function and structure (e.g., dysplasia); and the other in a mesenchymal or other supporting cell resulting in disruption of tissue microarchitecture. The corollary of this is that there will be mesenchymal mutations producing microarchitectural abnormalities without epithelial dysplasia and vice versa. Disruption of the functions of morphostats may result in a variety of abnormalities. Such disruption may be a key event in carcinogenesis.

A unique aged human retinal pigmented epithelial cell line useful for studying lens differentiation in vitro.

Abstract: Lens regeneration occurs in some urodeles and fish throughout their adult life. Such an event is possible by the transdifferentiation of the pigment epithelial cells (PECs) from the dorsal iris. Studies of this event at the cellular level have been facilitated owing to the ability of PECs to become lens cells even when they are placed in culture, outside of the eye. In fact, PECs possess the capacity for transdifferentiation regardless of the origin of species or age. However, studies at the molecular level are still hindered by the intrinsic problems of primary cultures, namely storage, reproducibility and genetic manipulation. In an attempt to establish an ideal model system for lens transdifferentiation, we have analyzed the ability of a human dedifferentiated PEC line to differentiate into lens. We have found that this cell line can indeed be induced to synthesize crystallin and morphologically differentiate to three-dimensional structures resembling lentoids under controlled treatment in vitro. Gene expression studies also provided important insights into the role of key genes. This human cell line can be used for detailed genetic studies in order to identify the key factors involved in lens transdifferentiation from PECs.