1 The Islet Research Laboratory, Whittier Institute for Diabetes, Department of Pediatrics, School of Medicine, University of California San Diego, La Jolla, California
2 Laboratory of Molecular Medicine and Neuroscience, National Institute of Neurological Disorders and Stroke, National Institutes of Health, Bethesda, Maryland
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ABSTRACT |
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The overall goal in the treatment of type 1 diabetes is the maintenance of normoglycemia in patients with diabetes. Replacement of ß-cell mass offers an alternative to standard insulin replacement and may overcome the long-term side effects associated with current therapies. However, an abundant source of tissue that will satisfy the demand for ß-cells has yet to be found. Recently, a potential source of cells was described in and isolated from the adult rat and human islets of Langerhans (1,2). These cells were characterized by the expression of the neurepithelial marker nestin. With the use of selective adhesion in tissue culture conditions, nestin+ cells were enriched and expanded. Addition of growth factors to these cultures induced the expression of ß-cell markers. Insulin expression has also been induced from nestin+ mouse embryonic stem cells in vitro (35). These in vitro observations have led to the hypothesis that nestin is a marker of pancreatic stem cells; however, little is known about the role of nestin in human pancreatic development.
Nestin is an intermediate filament protein originally described in the developing central nervous system (6). Human and rodent neurepithelial stem cells colocalize nestin and vimentin before cell cycle exit and neuronal or glial differentiation upon which nestin expression is lost (6,7). Because of the similarities between ß-cells and neurepithelial development (8), a similar transient expression of nestin was proposed to occur in the human insulin-producing ß-cell precursors (1,2). However, nestin expression is not restricted to human neurepithelial stem cells. Not surprisingly, nestin is also observed in human glioblastomas and neurectodermal tumors (9). In addition, angiogenesis occurring in neoplastic tissue is associated with an increase in nestin+ endothelial cells compared with the subpopulation of nestin+ endothelial cells in the normal brain tissue. Developing human myocytes also express nestin, which persists in the adult skeletal muscle and is upregulated during regeneration and in myosarcomas (10). Nestin is also widely expressed in the human gastrointestinal submucosa and in gastrointestinal stromal cell tumors of mesenchymal origin (11). Therefore, nestin is expressed in a variety of human cell types, observed during development, terminal differentiation, and oncogenic transformation.
Here, we describe the characterization of nestin expression in the developing human pancreas and determine the ability of nestin+ cells, isolated using a promoter-defined selection plasmid, to differentiate into the ß-cell lineage in vitro and in vivo after transplantation. We show that nestin is specifically localized to the fetal pancreatic vasculature and fibroblasts. In addition, proven models of ß-cell development fail to induce ß-cell differentiation from a pure population of nestin+ cells derived from the human fetal pancreas.
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RESEARCH DESIGN AND METHODS |
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Tissue processing and cell lines.
Fetal pancreata were enzymatically digested for the generation of islet-like cell clusters (ICCs) as previously described (12). After 4 days in suspension, ICCs were collected for protein analysis, transplantation, or in vitro expansion, where cell clusters were transferred to dishes coated with the HTB-9 matrix and cultured in the presence of 10 ng/ml hepatocyte growth factor/scatter factor (HGF/SF; donation from Genentech, South San Francisco, CA) to facilitate the outgrowth and expansion in monolayer (13). Human fetal and adult pancreatic fibroblast cell lines (HFF and HAF, respectively) were previously generated in our laboratory and were cultured as described (14). A human neonatal foreskin fibroblast (Hs 168.Fs; American Type Culture Collection, Manassas, VA) also served as a control.
pCI-nes-neo vector construction.
The pCI-nes-neo vector was generated by replacing the SV-40 enhancer/early promoter of the pCI-neo vector (Promega, Madison, WI) by the second intron of the human nestin gene followed by 160 bp of the basic HSV TK promoter. The second intron and TK promoter are sufficient to drive nestin gene expression in neurepithelial precursors (15). Briefly, the pCI-neo vector was cleaved with DraIII and StuI, liberating the SV-40 enhancer/promoter. The nestin enhancer TK promoter insert was excised from the vector Nes 1852/TK Lac Z (provided by Dr. Urban Lendahl, Medical Nobel Institute, Stockholm, Sweden) by HindIII and NotI digestion. Vector and insert were ligated, and the orientation of the insert was confirmed by restriction digests.
For confirming that the second intron of the human nestin gene and TK promoter are also sufficient to drive reporter gene expression in human pancreatic precursors, the nestin enhancer TK promoter insert was subcloned into the SmaI site of the pEGFP promoterless vector (Clontech, Palo Alto, CA; the HindIII and NotI sites were not recreated after fill-in and ligation into the SmaI site). The cassette containing the nestin enhancer TK promoter driving the green fluorescent protein (GFP) coding sequence was excised with HindIII and NotI.
Adeno-shuttle plasmid pE1Z was constructed by inserting the human cytomegalovirus (hCMV) promoter-enhancer, intron, multicloning site, and bovine growth hormone poly-A signal sequence into the adenovirus E1 region in the plasmid p
E1sp1A (Microbix Biosystems, Toronto, Ontario, Canada) (16). The hCMV promoter was removed by HindIII and NotI digestion and replaced with the nestin-GFP insert. The adenovirus backbone pJM17 was provided by Dr. Frank Graham. Viral lysates from 293 cells were used to plaque-purify a clonal isolate, and viral titers were checked by plaque formation assay on 293 cells as previously described in our laboratory (17).
Infection, transfection, and selection of nestin+ cells.
Fetal pancreata were processed for the generation of ICCs, except that the cell clusters were dispersed into single cells using warm 0.25% Trypsin 24 h after the initial digestion. The single-cell suspension was plated overnight on HTB-9coated dishes in RPMI 1640 (Gibco, Carlsbad, CA) with 10% fetal bovine serum (FBS; Gibco) without antibiotics and transfected with the pCI-nes-neo vector using Lipofectamine Plus reagent as suggested by the manufacturer (Invitrogen, Carlsbad, CA). Selection was in the presence of 400 µg/ml G418 (Gibco) for 1014 days and surviving colonies were grown to confluence and exposed to a variety of differentiation factors.
Virus infection was performed as previously described in our laboratory, achieving infectivity of 95% (17). Briefly, monolayers of ICCs were incubated with adenoviral particles (MOI 80) in RPMI 1640 with 10% FBS for 2 h at 37°C. Cells were washed twice in PBS, cultured for 4 days, and fixed in 4% paraformaldehyde for immunofluorescent analysis.
Cell culture.
The selected nestin+ cells from the same pancreas were split and expanded in RPMI 1640 with 11 mmol/l glucose containing 10% FBS supplemented with either 10 ng/ml HGF/SF grown on HTB-9 matrix or 20 ng/ml epidermal growth factor (EGF) and fibroblast growth factor-2 (FGF2; both Invitrogen) grown on tissue culturetreated plates (Nunc, Rochester, NY). For differentiation, early passage cells from both expansion protocols were split into serum (10% FBS) or serum-free media (RPMI 1640) and grown on either HTB-9 matrix or tissue culturetreated six-well plates. Serum-free medium was supplemented with ITS (BD Biosciences, San Jose, CA) and 400 µmol/l MnCl2 (Sigma, St. Louis, MO). Both serum and serum-free media contained 4 nmol/l betacellulin (R&D Systems, Minneapolis, MN), 10 nmol/l exendin-4 (GLP-1 analogue; Sigma), 10 ng/ml HGF/SF, 4 nmol/l activin A (CalBiochem, San Diego, CA), or 10 mmol/l nicotinamide (Sigma). An untreated control was performed in parallel. Cells were exposed to the growth factors for 6 days and collected for RT-PCR analysis.
In addition to monolayers, early passage nestin+ cells were reaggregated as previously described (13) and grown in RPMI 1640 containing 10% Human Serum (BioWhittaker, Walkersville, MD) either with or without 10 mmol/l nicotinamide for 4 days. HFFs were treated in parallel with the nestin monolayers and reaggregates as a negative control. Control ICCs were also plated on HTB-9 in 10 ng/ml HGF/SF, transfected with the pCIneo parent vector, expanded for 5 days, reaggregated, and cultured in the presence of 10 mmol/l nicotinamide for 4 days to demonstrate that both transfection and expression of neomycin resistance do not impair ß-cell differentiation.
RT-PCR.
RNA was purified using the RNeasy minikit (Qiagen, Valencia, CA) and reverse transcribed using Superscript II with 250 ng of random primer (both Invitrogen) and 1 µg of total RNA in a reaction volume of 20 µl. For detection of insulin and pancreatic and duodenal homeobox gene-1 (PDX-1) in the nestin+ cells, 1.5 µl of cDNA was used for each PCR (35 cycles) in a total volume of 30 µl. Oligonucleotide primers used for the PCR were insulin (18), PDX-1 (19), and ß-actin (Stragene, La Jolla, CA). For semiquantitative analysis of insulin and neomycin resistance expression after reaggregation of the fetal monolayers, the PCR was carried out using 1 µl of cDNA in a total volume of 30 µl over 22 cycles, and ß-actin was used as a control. The forward and reverse primers for neomycin resistance are 5'-AGGCTATTCGGCTATGACTGG-3' and 5'-GATACTTTCTCGGCAGGAGC-3', respectively. The whole PCR product was loaded onto a 1.2% Agarose gel and stained with ethidium bromide.
Western blotting.
SDS-PAGE immunoblotting was performed as previously described (7) with some alterations. Briefly, cultured cells were lysed in TBS (pH 7.8) containing 5 mmol/l EDTA, 1% TritonX100, 0.2% SDS, and a cocktail of proteinase inhibitors. Total cell lysates (10 µg) were resuspended in reducing NuPage sample buffer (Invitrogen) and electrophoresed on a 10% SDSpolyacrylamide gel and transferred onto Opti-tran nitrocellulose membrane (Schleicher and Schuell, Keene, NH). Membranes were blocked with TBS containing 5% nonfat milk and 0.05% Tween and incubated in mouse anti-human nestin (1:1,000; provided by Conrad Messam, National Institutes of Health, Bethesda, MD) for 2 h at room temperature. Blots were then incubated for 1 h with peroxidase-conjugated anti-mouse antibodies (1:5,000; Jackson ImmunoResearch, West Grove, PA), followed by chemiluminescence detection (Amersham Pharmacia Biotech, Piscataway, NJ).
Transplantation.
Nestin+ cells isolated from pancreata of gestational ages 1824 weeks were reaggregated and cultured in RPMI 1640 with 11 mmol/l glucose, 10% human serum, and either with or without 10 mmol/l nicotinamide for 24 days before transplantation. ICCs and reaggregated monolayers of expanded ICCs pretreated with nicotinamide were used as positive controls, and reaggregated HFFs were used as negative controls. The cell clusters were transplanted into athymic nude mice under the kidney capsule as previously described (20). After 3 months, the animals were challenged with 3 g/kg glucose i.p., and human C-peptide was measured by radioimmunoassay as previously described (20).
Immunofluorescence.
Fetal pancreata ranging from gestational ages 12 to 24 weeks were collected and processed for cryosectioning as previously described (21). The expanded ICCs in monolayer and selected nestin+ cells were grown on coverslips coated with HTB-9 and processed as previously described (13). Primary antibodies used were sheep anti-human insulin (The Binding Site, San Diego, CA), mouse anti-human nestin and rabbit anti-human nestin 331B (provided by Conrad Messam), mouse anti-pan cytokeratin and mouse anti-vimentin (both from Immunotech, Villepinte, France), mouse anti-platelet endothelial cell adhesion molecule (PECAM; Caltag, Burlingame, CA), mouse anti smooth muscle actin conjugated to FITC (Sigma), and rabbit antiKi-67 (Dako, Carpinteria, CA). Affinity-purified FITC-donkey anti-rabbit IgG, Rhodamine-donkey anti-mouse IgG, and Cy5-donkey anti-sheep IgG (5 µg/ml; all from Jackson ImmunoResearch) were directed against unconjugated primary antibodies. Control sections for all experiments were incubated with a cocktail of normal sheep, rabbit, and mouse IgGs (Jackson ImmunoResearch), followed by the appropriate secondary antibodies. Sections and coverslips were mounted in antifade medium (Biomeda, Foster City, CA) and viewed on Zeiss Axiovert 35 mol/l microscope equipped with a laser scanning confocal attachment (MRC-1024; Bio-Rad Laboratories, Hercules, CA). Color composite pictures were processed using Adobe Photoshop 6.0 (Adobe Systems, Mountainview, CA).
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RESULTS |
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GFP expression was observed in a subpopulation of fetal pancreatic cells in monolayer, demonstrating that the nestin enhancer TK promoter was sufficient to drive gene expression in human fetal pancreatic cells. Colocalization with the nestin protein and promoter activity was observed (Fig. 2A), and in a similar pattern to in vivo, robust GFP expression was associated with vimentin-positive cells and was absent in pCK-positive cells (Fig. 2A and B). In some monolayer preparations, a rare population of pCK-positive cells also contained a very low level of GFP expression. However, these cells were never observed to coexpress the nestin protein. Insulin was never observed in GFP-positive cells (Fig. 2B).
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In vitro differentiation of nestin+ cells.
The transfection procedure and expression of neomycin resistance (neoR) in human fetal pancreatic cells may be detrimental to the cells ability to further differentiate. Transfection of the PCIneo parent vector into monolayers of expanded ICCs resulted in a high level of neoR expression (Fig. 3A). Both transfection of plasmid DNA and expression of neoR did not impair ß-cell differentiation and the induction of insulin message after the reaggregation of the monolayer into a three-dimensional islet-like structure (Fig. 3A).
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Reaggregation into an islet-like three-dimensional cell cluster is known to stimulate insulin gene transcription in fetal pancreatic cells compared with cells grown in monolayer (13) (Fig. 3A). Reaggregated nestin+ cells cultured in human serum in the presence or absence of nicotinamide showed neither PDX-1 nor insulin message (Fig. 3D). A similar result was found using reaggregated HFFs (Fig. 3D).
Transplantation of nestin+ cells.
An effective model to examine human ß-cell development is transplantation of fetal pancreatic cells into an in vivo environment provided under the renal capsule of athymic mice. Differentiation of ß-cells in the graft tissue can be monitored with the detection of human C-peptide after glucose stimulation (13). Three months after engraftment, positive control grafts containing either ICCs or reaggregated monolayers of expanded ICCs released high levels of human C-peptide after glucose stimulation (Fig. 4). This level of release corresponds to a graft that contains 50% of insulin-positive cells (24). In contrast, the levels of C-peptide detected in the selected nestin+ cells were not significantly different from the HFF-negative control graft and the background levels seen in the sham-operated animal (Fig. 4). No evidence of insulin-positive cells was seen in the nestin graft. Pretreatment with nicotinamide did not affect the outcome of the reaggregated nestin+ graft; therefore, the results for treated and untreated aggregates were combined.
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DISCUSSION |
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Here, we characterized and isolated a population of nestin+ cells from the developing human pancreas and investigated its ability to differentiate into ß-cells both in vitro and after transplantation. We found that nestin is localized specifically to the mesenchyme of the developing human pancreas but not to any epithelial cell population. Furthermore, we showed that after isolation, nestin+ cells do not differentiate into ß-cells, neither in vitro nor in vivo.
The mesenchymal expression of nestin was localized to the vasculature of the developing pancreas and vimentin-positive stromal cells. Localization of nestin to the blood vessels is consistent with previous reports describing nestin expression in a diverse group of human organs, including the CNS (9), the gastrointestinal tract (11), and the majority of the vasculature supplying developing organs in the fetal mouse (25). Nestin expression was also observed in the blood vessels during adult rat pancreatic regeneration and fetal pancreatic development (26). More recently, nestin expression was shown to be confined to the endothelium in the adult human pancreas (27). Although a recent study demonstrated the requirement of blood vessels for ß-cell development (28), our studies demonstrate that the ß-cell lineage itself has no developmental relationships with a putative pool of nestin+ precursors.
Vimentin-positive stromal cells have been well characterized as pancreatic fibroblasts. Colocalization of nestin and vimentin within pancreatic fibroblasts is also consistent with the observations of fibroblast-like cells expressing nestin in the human gastrointestinal tract (11). Nestin expression was also solely localized to the developing mouse pancreatic stroma; however, cell types in the interstitial tissue were not fully characterized (29).
The mesenchymal localization of nestin is not consistent with the currently accepted model of pancreatic ß-cells arising from the ductal epithelium. An alternative to vimentin and nestin colocalization representing a population of fibroblasts is a population of cells similar to the neurepithelial precursors. The pure population of nestin cells selected on the basis of nestin enhancer/promoter activity also expressed a high level of vimentin, and virtually all of the cells were mitotically active. Neurepithelial precursors also colocalize vimentin and nestin (6,7); this expression pattern in the pancreas may represent migrating neural crest cells as suggested in past models of islet development (30). However, compelling evidence by LeDouarin (31) excluded the contribution of neurectodermal cells to pancreatic lineages.
Generation of insulin-secreting cells from nestin+ mouse embryonic stem cells has led to further models of ß-cell differentiation. Preferential growth of nestin+ embryonic stem cells ("nestin selection") has recently been shown to increase the yield of insulin+ cells (5). This increase was attributed to the possible selection of endocrine precursors because nestin may have a role in neuroendocrine migration (5). Therefore, in the human fetal pancreas, ductal cells may lose their epithelial phenotype upon a migratory stimulus and transiently express nestin and other intermediate filament proteins such as vimentin before insulin expression. This would explain their stromal localization in the fetal pancreas. However, there was no loss of epithelial phenotype before the expression of insulin in the human fetal pancreas, because colocalization of epithelial cytokeratins and insulin was observed in the current study and by others (32). Furthermore, neither nestin and cytokeratin nor nestin and insulin colocalization was observed, suggesting that a transient stage of nestin expression is not required before hormone production and loss of the epithelial markers. Isolation of the of nestin+ pancreatic cells supported the in vivo observations because ß-cell differentiation was not achieved in vitro or in vivo. The results from the current study, however, do suggest that the nestin+ mouse embryonic stem cells that generate insulin-producing cells (35) are a different population from that seen in the fetal pancreas.
The nestin selection approach clearly suggests that nestin is not a specific marker of ß-cell precursors during normal development. However, the potential shortfalls of this approach must be noted. Although the second intron of the human nestin gene is sufficient to drive gene expression in neurepithelial precursors (15,16,22), additional elements of the nestin promoter may be required for gene expression in human fetal pancreatic cells. The current study demonstrated that the second intron of the nestin gene was sufficient to drive GFP expression in human fetal pancreatic cells. Furthermore, GFP colocalization with nestin protein was observed in the same cell types as seen in vivo.
The developmental stage at which the selection plasmid is introduced is also of critical importance. It is possible that during 1224 gestational weeks, transient expression of nestin is not observed in ß-cell precursors, therefore explaining the lack of immunofluorescent evidence and the isolation of a nestin+ ß-cell precursor. It seems unlikely that during the period of 1224 weeks gestation, when ICCs contain a large proportion of ß-cell precursors capable of differentiating into a population of 50% insulin-positive cells after transplantation (24), that our approach would miss the detection of nestin+ ß-cell precursors.
The efficiency of transfection raises the concern that the selection plasmid did not transfect a small subpopulation of nestin+ cells capable of undergoing ß-cell differentiation. An adenoviral vector containing the same regulatory elements driving GFP expression was used to transduce 95% of the fetal pancreatic cells. Robust GFP expression was observed in the same population of cells that were selected on the basis of neoR introduced by transfection.
From the data presented, we conclude that nestin+ cells in the fetal pancreas are unlikely to generate ß-cells and do not represent a candidate population from the fetal pancreas to be used for transplantation therapy. This conclusion is based on characterizing the population of nestin+ cells during human pancreatic development, isolating a pure population of nestin+ cells, and challenging the cells both in vitro and in vivo with conditions known to stimulate ß-cell differentiation.
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ACKNOWLEDGMENTS |
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The technical expertise of Kathryn Bouic in the production of the adenovirus is greatly appreciated.
Address correspondence and reprint requests to Alberto Hayek, Whittier Institute for Diabetes, Department of Pediatrics, University of California San Diego, 9894 Genesee Ave., La Jolla, CA 92037. E-mail ahayek{at}ucsd.edu
Received for publication January 17, 2003 and accepted in revised form July 7, 2003
EGF, epidermal growth factor; FBS, fetal bovine serum; GFP, green fluorescent protein; HAF, human adult fibroblast; hCMV, human cytomegalovirus; HFF, human fetal fibroblast; HGF/SF, hepatocyte growth factor/scatter factor; ICC, islet-like cell cluster; neoR, neomycin resistance; pCK, pan cytokeratin; PDX-1, pancreatic and duodenal homeobox gene-1; PECAM, platelet endothelial cell adhesion molecule
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REFERENCES |
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