寺谷 工

The specific features of the plasticity of adult stem cells are largely unknown. Recently, we demonstrated the hepatic differentiation of human adipose tissue-derived mesenchymal stem cells (AT-MSCs). To identify the genes responsible for hepatic differentiation, we examined the gene expression profiles of AT-MSC-derived hepatocytes (AT-MSC-Hepa) using several microarray methods. The resulting sets of differentially expressed genes (1639 clones) were comprehensively analyzed to identify the pathways expressed in AT-MSC-Hepa. Clustering analysis revealed a striking similarity of gene clusters between AT-MSC-Hepa and the whole liver, indicating that AT-MSC-Hepa were similar to liver with regard to gene expression. Further analysis showed that enriched categories of genes and signaling pathways such as complementary activation and the blood clotting cascade in the AT-MSC-Hepa were relevant to liver-specific functions. Notably, decreases in Twist and Snail expression indicated that mesenchymal-to-epithelial transition occurred in the differentiation of AT-MSCs into hepatocytes. Our data show a similarity between AT-MSC-Hepa and the liver, suggesting that AT-MSCs are modulated by their environmental conditions, and that AT-MSC-Hepa may be useful in basic studies of liver function as well as in the development of stem cell-based therapy.

Many studies on stem cell plasticity are challenging the concept that stem cells contain an intrinsically predefined, unidirectional differentiation program. This means that the developmental fate of a stem cell is dependent on the general potential of the cell (pre-determined stem cell fate) as well as on microenvironmental cues, such as stimuli from growth factors (stem cell niche). Here, we reviewed reports that examined the hepatocyte differentiation ability of stem cells from two different sources: embryonic stem cells and adult stem cells. All of those stem cells revealed the ability to give rise to hepatocyte-like cells using different induction strategies. However, it is still not clear which of those stem cells would be the best source for hepatocyte replacement or which would be the best protocol. We herein present the current knowledge regarding available protocols and factors used in order to obtain functional hepatocytes from stem cells.

UNLABELLED: Recent observations indicate that several stem cells can differentiate into hepatocytes; thus, cell-based therapy is a potential alternative to liver transplantation. The goal of the present study was to examine the in vitro hepatic differentiation potential of adipose tissue-derived mesenchymal stem cells (AT-MSCs). We used AT-MSCs from different age patients and found that, after incubation with specific growth factors (hepatocyte growth factor [HGF], fibroblast growth factor [FGF1], FGF4) the CD105(+) fraction of AT-MSCs exhibited high hepatic differentiation ability in an adherent monoculture condition. CD105(+) AT-MSC-derived hepatocyte-like cells revealed several liver-specific markers and functions, such as albumin production, low-density lipoprotein uptake, and ammonia detoxification. More importantly, CD105(+) AT-MSC-derived hepatocyte-like cells, after transplantation into mice incorporated into the parenchyma of the liver. CONCLUSION: Adipose tissue is a source of multipotent stem cells that can be easily isolated, selected, and induced into mature, transplantable hepatocytes. The fact that they are easy to procure ex vivo in large numbers makes them an attractive tool for clinical studies in the context of establishing an alternative therapy for liver dysfunction.

OBJECTIVES: To clarify the gene expression patterns of fatty acid-binding protein (FABP) and evaluate it as a potential marker for the diagnosis of renal cell carcinoma (RCC). RCC is the most common renal neoplasm. METHODS: The expression of eight FABP genes in normal human tissues, tumor cell lines, and surgically resected RCC tissues (n = 54) was evaluated by reverse transcriptase-polymerase chain reaction. Additionally, the gene expression of FABPs in the urine of healthy volunteers (n = 12) and patients with RCC (n = 5) was investigated. RESULTS: In these results, the carcinoma tissues but not the noncancerous (normal) parts of the kidney samples resected from patients with RCC expressed the transcript for brain-type FABP (B-FABP), indicating that expression of the B-FABP gene is a novel marker for RCC. Furthermore, the B-FABP cDNA fragment was not amplified by reverse transcriptase-polymerase chain reaction in the urine samples of healthy donors or patients with RCC after surgical operation. However, B-FABP cDNA was amplified in the patients' urine samples collected before surgery. CONCLUSIONS: This novel method can be used as a powerful ancillary in the diagnosis of RCC.

This study aimed to analyze expression of S100A10, annexin II and B-FABP genes in renal cell carcinoma (RCC) and their potential value as tumor markers. Furthermore, any correlation between the gene expression and prognostic indicators of RCC was analyzed. Expression of each gene was estimated by RT-PCR in the non-neoplastic (normal) and tumorous parts of resected kidney samples. Also, each antigen was immunostained in RCC and normal kidney tissues. Expression of the S100A10 gene averaged 2.5-fold higher in the tumor than that in the normal tissues (n = 47), after standardization against that of beta-actin. However, expression of annexin II, a natural ligand of S100A10, was only 1.64-fold higher. In the tissue sections of RCC, S100A10 and annexin II were immunostained in membranes. In the normal renal epithelia, however, both antigens were stained in the Bowman's capsule and the tubules from Henle's loop through the collecting duct system, but not in the proximal tubules, from where most RCC are derived. In contrast, expression of the B-FABP gene was 20-fold higher in the tumor. No B-FABP was immunohistochemically detected in normal kidney sections, but it was stained in the cytoplasm of RCC tissue sections. S100A10 and B-FABP genes were overexpressed regardless of nuclear grade and stage of RCC. Immunopositivity in RCC tissues (n = 13) was 100% for S100A10 and annexin II, and 70% for B-FABP; however, no clear relationship was observed in either antigen with nuclear grade and stage. It was found that all three performed well as RCC markers. B-FABP was most specific to RCC, as it was expressed little in normal kidney tissues.

It appears that the adult pancreas has limited regenerative ability following beta cell destruction by streptozotocin (STZ). However, it is not clear if this limitation is due to an inability to respond to, rather than an absence of, regenerative stimuli. In this study we aimed to uncouple the regenerative signal from the regenerative response by using an exogenous stem cell source to detect regenerative stimuli produced by the STZ-injured pancreas at physiological blood glucose levels. Adult nude mice received 150 mg/kg STZ and 1x10(6) J1 mouse embryonic stem (ES) cells by i.p. injection. Permanent beta cell depletion of 50% was estimated from the ratio of beta:alpha cells in pancreata from STZ-treated mice compared with control animals after 24 days. Transplanted ES cells homed to the STZ-injured pancreas and formed tumours. Immunocytochemical analysis of pancreas-associated ES tumours revealed foci containing insulin/PDX-1 double-positive and glucagon-positive/PDX-1-negative cell clusters associated with PDX-1-positive columnar lumenal epithelium and extensive alpha-amylase-positive pancreatic acini comprising approximately 0.1% of ES tumour volume. These data indicate that (1) the adult pancreas produces a milieu of regenerative stimuli following beta cell destruction, and (2) this is not dependent on hyperglycaemic conditions; (3) these regenerative stimuli appear to recapitulate the signalling pathways of embryonic development, since both exocrine and endocrine lineages are produced from PDX-1-positive precursor epithelium. This model will be useful for characterising the regenerative mechanisms in the adult pancreas.

Hepatic differentiation at the molecular level is poorly understood, mainly because of the lack of a suitable model. Recently, using adherent monoculture conditions, we demonstrated the direct differentiation of hepatocytes from embryonic stem (ES) cells. In this study, we exploited the direct differentiation model to compare the gene expression profiles of ES cell-derived hepatocytes with adult mouse liver using DNA microarray technology. The results showed that the ES cell-derived hepatocyte gene expression pattern is very similar to adult mouse liver. Through further analysis of gene ontology categories for the 232 most radically altered genes, we found that the significant categories related to hepatic function. Furthermore, through the use of small interfering RNA technology in vitro, hepatocyte nuclear factor 3beta/FoxA2 was identified as having an essential role in hepatic differentiation. These results demonstrate that ES cell-derived hepatocytes recapitulate the gene expression profile of adult mouse liver to a significant degree and indicate that our direct induction system progresses via endoderm differentiation. In conclusion, our system closely mimics in vivo hepatic differentiation at the transcriptional level and could, therefore, be useful for studying the molecular basis of hepatocyte differentiation per se.

Silencing of gene expression by small interfering RNAs (siRNAs) is rapidly becoming a powerful tool for genetic analysis and represents a potential strategy for therapeutic product development. However, there are no reports of systemic delivery for siRNAs toward treatment of bone-metastatic cancer. Accordingly, we report here that i.v. injection of GL3 luciferase siRNA complexed with atelocollagen showed effective reduction of luciferase expression from bone-metastatic prostate tumor cells developed in mouse thorax, jaws, and/or legs. We also show that the siRNA/atelocollagen complex can be efficiently delivered to tumors 24 h after injection and can exist intact at least for 3 days. Furthermore, atelocollagen-mediated systemic administration of siRNAs such as enhancer of zeste homolog 2 and phosphoinositide 3'-hydroxykinase p110-alpha-subunit, which were selected as candidate targets for inhibition of bone metastasis, resulted in an efficient inhibition of metastatic tumor growth in bone tissues. In addition, upregulation of serum IL-12 and IFN-alpha levels was not associated with the in vivo administration of the siRNA/atelocollagen complex. Thus, for treatment of bone metastasis of prostate cancer, an atelocollagen-mediated systemic delivery method could be a reliable and safe approach to the achievement of maximal function of siRNA.

The molecules responsible for hepatic differentiation from embryonic stem (ES) cells have yet to be elucidated. Here we have identified growth factors that allow direct hepatic fate-specification from ES cells by using simple adherent monolayer culture conditions. ES cell-derived hepatocytes showed liver-specific characteristics, including several metabolic activities, suggesting that ES cells can differentiate into functional hepatocytes without the requirement for embryoid body (EB) formation, in vivo transplantation, or a coculture system. Most importantly, transplantation of ES cell-derived hepatocytes in mice with cirrhosis showed significant therapeutic effects. In conclusion, this novel system for hepatic fate specification will help elucidate the precise molecular mechanisms of hepatic differentiation in vitro and could represent an attractive approach for developing stem cell therapies for treatment of hepatic disease in humans. Supplementary material for this article can be found on the HEPATOLOGY website ( http://www.interscience.wiley.com/jpages/0270-9139/suppmat/index.html).

This study investigated the three-dimensional culture of hepatocytes differentiated from mouse embryonic stem (ES) cells with a porous hyaluronan (HA) sponge support. Hepatocytes were immobilized within the pores of the support. Spheroids could be observed within the support, each containing between 20 and 50 hepatocytes. To examine the liver-specific functions of the hepatocytes in the culture, the levels of albumin secreted into the medium were analyzed. The secretion of albumin was stable over the course of 32 days, longer than that in both conventional monolayer and collagen sponge cultures. To elucidate further the liver-specific functions of hepatocytes embedded in the HA sponge, metabolic activities of the hepatocytes were examined for their ability to eliminate ammonia from culture media and the synthesis of urea nitrogen. While rates of ammonia removal and urea nitrogen synthesis were similar to those in both conventional monolayer and in collagen sponge cultures, these functions were maintained for longer duration in cells embedded in the HA sponge. These results demonstrate that the porous HA sponge is an effective support for the in vitro culture of ES-derived hepatocytes used for both basic and applied studies for cell transplantation.

Mouse embryonic stem (ES) cells are capable of differentiating into any adult animal cell type. Although in vivo method has been achieved to acquire abundant functional hepatocytes from ES cells through liver regenerating animals, the underlying mechanisms are poorly understood. Therefore, establishment of an in vitro system for the desired control of hepatic commitment of ES cells has been desired. Here we have identified growth factors that allow direct hepatic fate-specification from ES cells using simple adherent monoculture conditions. ES-cell-derived hepatocytes exhibited liver-specific characteristics including several metabolic activities. Furthermore, transplantation of ES-cell-derived hepatocytes showed significant therapeutic effects in mice with liver cirrhosis. Thus, this novel system will help elucidate the precise molecular mechanisms of hepatic commitment and will be potentially useful as an attractive source for stem cell therapies.

Embryonic stem (ES) cells provide a unique source for tissue regeneration. We examined whether mouse ES cells can efficiently differentiate into transplantable hepatocytes. ES cells were implanted into mouse livers 24 hours after carbon tetrachloride intoxication; ES-derived cells with several hepatocyte-cell-markers were generated. They were able to grow in vitro and showed morphology consistent with typical mature hepatocytes and expressed hepatocyte-specific genes. After transplantation into the carbon tetrachloride-injured mouse liver, ES-derived green fluorescent protein-positive cells were incorporated into liver tissue and rescued mice from hepatic injury. No teratoma formation was observed in the transplant recipients. In conclusion, ES cells can provide a valuable tool for studying the molecular basis for differentiation of hepatocytes and form the basis for cell therapies.

Reverse transcription--polymerase chain reaction (RT-PCR) identified the expression of calcium-binding protein S100A5 in the noncancerous parts of resected samples from renal cell carcinoma (RCC) patients (n = 7) but not in the carcinoma lesions. Rabbit anti-S100A5 antibody immunohistochemically detected the antigen in the thick ascending limb of Henle, distal convoluted tubule, and collecting duct system. No apparent immunopositivity was observed in the glomerulus, proximal tubules, interstitial cells, or RCC cells. Thus, it was suggested that S100A5 protein plays an inherent functional role to the post-thick ascending limb of Henle portion in the nephron. Further, the carcinomas tested were originated probably not in the S100A5-positive distal epithelium but in the -negative epithelium of proximal tubules. Then, total RNA was extracted by phenol/chloroform from 1 ml urine of healthy volunteers, and S100A5 was amplified by RT-PCR from all samples (n = 12), indicating that the transcript of S100A5 is detectable even in the cells released into urine.

Expression of 16 S100 family calcium-binding protein genes was evaluated by PCR in ten human tissue cDNA libraries. Six to 12 S100 genes were expressed in a tissue-specific manner. Then, the expression in the surgically resected renal cell carcinoma (RCC) and a cultured RCC cell line was studied by RT-PCR. Although eight to nine S100 genes were transcribed in the normal kidney library and non-cancerous part of resected kidney tumors, S100A1 and S100A10 genes were not expressed. However, these genes were newly expressed in the RCC lesions (n=7) and the RCC cell line, indicating that expression of S100A1 and S100A10 genes is accompanied by RCC.