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COMMENTARY |
Beta Cell Development and Function Group, King’s College London, Hodgkin Building, Guy’s Campus, London SE1 1UL, UK
(Requests for offprints should be addressed to C J Burns; Email: chris.burns{at}kcl.ac.uk)
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Abstract |
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 Top Abstract IntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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Introduction |
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TopAbstractIntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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Beta cells from stem cells |
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TopAbstractIntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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Although seemingly idealistic, many aspects of this scenario are already possible. Human embryos have been cloned using nuclei from somatic cells (Hwang et al. 2004), although there are unresolved ethical and legal issues with this process. Pluripotent human ES cell lines have been generated from both cloned and normal blastocysts, and the number of cell lines available to researchers is on the increase (Cowan et al. 2004). We have the ability to form islet-like structures from ß-cell populations in vitro (Hauge-Evans et al. 1999), and there are now numerous instances (>250 in over 25 centres worldwide) of islet transplantation in people with Type 1 diabetes. However, the pivotal, and as yet unresolved, stage in this novel therapeutic process is the efficient and reproducible differentiation of stem cells into functional insulin-secreting ß-cells.
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Minimum requirements for replacement ß-cells |
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TopAbstractIntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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First, vast numbers of replacement ß-cells will be required to make any significant therapeutic impact. Thus, current transplantation protocols use up to 1 x 106 primary human islets per recipient, equivalent to approximately 2–4 x 109 ß-cells. If we multiply this by the number of potential recipients with Type 1 diabetes (up to~105 in the UK; ~106 in the USA), the scale of the problem becomes apparent. Although a recent report identified pre-existing ß-cells as the source of new ß-cells in normal growth and development (Dor et al. 2004), mature ß-cells have a very low proliferative capacity (Swenne 1992). As a result, the large numbers of cells required will have to be derived from a proliferative precursor population that can be expanded considerably in vitro before differentiation into the mature ß-cell phenotype. The ability of stem cells of adult or embryonic origin to replicate and to differentiate into a range of tissue types makes them attractive candidates for producing replacement ß-cells.
Secondly, the replacement cells must have the ability to synthesise, store and release insulin when it is required, primarily in response to changes in the ambient glycaemia. Pancreatic ß-cells have evolved intricate mechanisms which allow them to monitor and respond rapidly to changes in circulating nutrients, and these mechanisms are now reasonably well understood (reviewed by Jones & Persaud 1998). Given the complexity of the ß-cell glucose-induced stimulus-response coupling mechanism (Fig. 1
), it is perhaps not surprising that attempts to engineer some of these response elements into substitute ß-cells have so far failed to produce cells with normal secretory phenotypes (reviewed by Persaud 1999).
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Finally, the transplanted cells must avoid destruction by the recipient’s immune system. The immunology of transplant rejection is a complex area and various strategies are being adopted to avoid the problems of immune responses without resorting to global and life-long immunosuppression. There are, however, specific problems when considering ß-cell transplantation into patients with Type 1 diabetes since their immune systems are programmed to destroy primary ß-cells, and will presumably target even the immunologically homologous ß-cell replacements that would be derived by therapeutic cloning of embryonic stem cells. One way of circumventing this problem may be to generate insulin-secreting cells that possess the functional phenotype of ß-cells but which are developmentally and immunologically distinct from primary ß-cells and so may evade the immune assault without immunosuppression.
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Potential sources of stem cells |
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TopAbstractIntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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), and if it were possible to isolate and expand these cells in vitro and then differentiate them to adopt a ß-cell phenotype, they would be a potential source of substitute tissue for transplantation. The pancreas is an obvious source tissue and a number of studies have suggested the existence of stem cells within the pancreas that can be induced to adopt some elements of a ß-cell phenotype (Bonner-Weir et al. 2000, Hunziker & Stein 2000, Ramiya et al. 2000, Habener 2001, Zulewski et al. 2001, Abraham et al. 2002, Seaberg et al. 2004). Progenitor cells from tissues other than the pancreas have also received considerable attention. Thus, liver and pancreas have a common embryonic origin, share many phenotype-maintaining transcription factors and both are equipped to respond to circulating glucose concentrations. Furthermore, there is evidence demonstrating trans-differentiation of cells from the liver towards a ß-cell phenotype (Ferber et al. 2000, Susuki et al. 2002, Yang et al. 2002, Horb et al. 2003, Kojima et al. 2003, Tuch et al. 2003). Similarly, it has been reported that stem cells derived from bone marrow can be differentiated in vitro (Jahr & Bretzel 2003) and in vivo (Ianus et al. 2003) into insulin-expressing cells, although these progenitor cells are unlikely to be the highly proliferative haematopoietic stem cells (Lee & Stoffel 2003). However, to date there is no convincing evidence that insulin-producing cells derived from pancreatic stem cells or liver progenitors can be expanded in vitro to clinically useful numbers.
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) are also expressed in populations of neurons (Yang et al. 1999), as are many of the recognised transcription factors that are used to map the development of the ß-cell (Wilson et al. 2003). We have recently demonstrated that rat neural stem cells can be expanded in vitro, and can be induced to express the insulin gene and respond metabolically to nutrients and sulphonylureas (Burns et al. 2003). The ability of neural cells to express the insulin gene is consistent with reports of transient expression of preproinsulin in the fetal brain during development (Devaskar et al. 1993a,b). An alternative source of highly proliferative, pluripotent cells which has received much more attention is ES cells. Derived from the inner cell mass of the blastocyst, these cells have the capacity to differentiate into all three embryonic germ layers in vitro. A large number of reports have now demonstrated that ES cells can differentiate into cells with an insulin-expressing phenotype, either by genetic manipulation or by permitting spontaneous differentiation followed by culture under selective conditions (Soria et al. 2000, Assady et al. 2001, Lumelsky et al. 2001, Hori et al. 2002, Shiroi et al. 2002, Blyszczuk et al. 2003, Moritoh et al. 2003, Miyazaki et al. 2004, Segev et al. 2004, Sipione et al. 2004). In common with studies using tissue stem cells, the cellular identity of these insulin-expressing cells is uncertain and with the lack of specific, easily identifiable markers of a mature ß-cell, the possibility remains that these cells are not fully mature ß-cells but instead are a phenotypically similar population of cells, perhaps of neuroectodermal (Lumelsky et al. 2001, Burns et al. 2003) or extra-embryonic (Houard et al. 2003) origin.
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Stem cell therapy for diabetes |
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TopAbstractIntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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(i) Which stem cells?
Perhaps the most important issue is the choice of the appropriate starting material. Research efforts are currently divided between embryonic and tissue stem cells as potential therapeutic progenitor cells. The proliferative capacity of ES cells is attractive, but their pluripotency may be a disadvantage. Differentiation of pluripotent ES cells generally produces a mixture of many different cell types and, in the absence of reliable selection procedures, this process cannot yet produce the homologous populations of fully differentiated ß-cells required for transplantation therapy. Tissue stem cells are further down the developmental pathway than ES cells, and so may be lineage-restricted to some extent, which may make it easier to drive them down particular developmental lineages. However, this experimental advantage is currently outweighed by the limited replicative potential of tissue stem cell populations in vitro. There may also be more subtle differences in the developmental potential of different stem cell populations. It is becoming evident that ES cell lines, both mouse and human, are not identical in their phenotype, in their culture requirements in vitro, or in their propensity to differentiate down particular lineages. This implies that some cell lines may be more appropriate than others from which to generate ß-cells. If so, we may need to apply differentiation protocols to numerous ES cell lines to determine which line, if any, is the best starting material. The generation of large numbers of different human ES cell lines, and the development of centralised ‘stem cell banks’ to characterise, store and distribute the cells should facilitate this process.
(ii) Do we need to make ß-cells?
The second question is whether we need to recapitulate in vitro the precise developmental pathway that leads to the differentiation of ß-cells in vivo. Many current studies, particularly those using ES cells, try to map their experimental protocols on to the known developmental pathways of pancreatic endocrine cells. However, the complex sequence of developmental events directing duodenal endoderm towards an insulin-expressing ß-cell phenotype in vivo are the result of millions of years of evolutionary selection, driven by environmental pressures rather than by conscious design. There is some evidence that it may be possible to employ conscious design to arrive at the same end-point by a less circuitous route. Thus, it has been suggested that the pathways of ß-cell differentiation in vitro may differ significantly from those in vivo (Houard et al. 2003) and mouse ES cells are reported to differentiate into endocrine cells without PDX-1 (pancreatic duodenal homeobox-1) expression (Moritoh et al. 2003), although this is essential in vivo (Scharfmann 2000). It is also possible that current in vitro differentiation protocols do not generate ß-cells, but, instead, cells that have some phenotypic and functional similarity to authentic ß-cells. For example, it has been suggested that a neural fate is a default pathway for differentiation of ES cells (Tropepe et al. 2001), and the application of culture conditions selective for nestin-positive precursors (Lumelsky et al. 2001) leads to insulin expression in cells with a neuronal phenotype (Sipione et al. 2004). These observations are consistent with our demonstration that neural stem cells can be induced to express mRNAs encoding insulin and elements associated with ß-cell function, since these ectodermally derived cells are unlikely to be authentic ß-cells. An alternative developmental origin for insulin-expressing cells could be the visceral endoderm of the yolk sac (Rau et al. 1989, McGrath & Palis 1997). Visceral endoderm develops initially in a similar manner to embryonic endoderm, and primitive endodermal cells are localised to the periphery of EBs (embryoid bodies) during differentiation of mouse ES cells (Murray & Edgar 2001). It has, therefore, been suggested that the insulin-expressing cells generated during EB formation are from visceral endoderm, since they are located almost exclusively in the outer layer of the EB (Houard et al. 2003). In the absence of specific and highly expressed markers for authentic ß-cells it is difficult to determine unambiguously the origin of insulin-expressing cells generated in vitro from pluripotent progenitor populations. In any event, in our opinion, the precise developmental identity of the cells used for transplantation therapy may not be important so long as they offer an expandable population of cells that fulfils the functional criteria of replacement ß-cells.
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Conclusion |
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TopAbstractIntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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Acknowledgements |
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References |
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TopAbstractIntroductionBeta cells from stem...Minimum requirements for...Potential sources of stem...Stem cell therapy for...ConclusionReferences |
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Received 9 September 2004
Accepted 6 October 2004
Made available online as an Accepted Preprint 18 October 2004
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