Aarati R. Ranade scite author profile

Mice that could be highly repopulated with human hepatocytes would have many potential uses in drug development and research applications. The best available model of liver humanization, the uroplasminogen-activator transgenic model, has major practical limitations. To provide a broadly useful hepatic xenorepopulation system, we generated severely immunodeficient, fumarylacetoacetate hydrolase (Fah)-deficient mice. After pretreatment with a urokinaseexpressing adenovirus, these animals could be highly engrafted (up to 90%) with human hepatocytes from multiple sources, including liver biopsies. Furthermore, human cells could be serially transplanted from primary donors and repopulate the liver for at least four sequential rounds. The expanded cells displayed typical human drug metabolism. This system provides a robust platform to produce high-quality human hepatocytes for tissue culture. It may also be useful for testing the toxicity of drug metabolites and for evaluating pathogens dependent on human liver cells for replication.The liver is the principal site for the metabolism of xenobiotic compounds, including medical drugs. Because many hepatic enzymes are species specific, it is necessary to evaluate the metabolism of candidate pharmaceuticals using cultured primary human hepatocytes 1,2 . Today, hepatocytes are isolated primarily from cadaveric organs and then shipped to the location where testing will be performed. The condition (viability and state of differentiation) of hepatocytes from cadaveric sources is highly variable, and many cell preparations are of marginal quality. The availability of high-quality human hepatocytes is further hampered by the fact that they cannot be substantially expanded in tissue culture 3,4 . Hepatocytes from readily available mammalian species, such as the mouse, are not suitable for drug testing because they have a different complement of metabolic enzymes and

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Maintenance of Human Hepatocyte FunctionIn Vitroby Liver-Derived Extracellular Matrix Gels

Sellaro

Ranade

Faulk

et al. 2010

Tissue Engineering Part A

255

217

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Tissue engineering and regenerative medicine (TE&RM) approaches to treating liver disease have the potential to provide temporary support with biohybrid-liver-assist devices or long-term therapy by replacing the diseased liver with functional constructs. A rate-limiting step for TE&RM strategies has been the loss of hepatocytespecific functions after hepatocytes are isolated from their highly specialized in vivo microenvironment and placed in in vitro culture systems. The identification of a biologic substrate that can maintain a functional hepatocyte differentiation profile during in vitro culture would advance potential TE&RM therapeutic strategies. The present study compared two different biologic substrates for their ability to support human hepatocyte function in vitro: porcine-liver-derived extracellular matrix (PLECM) or Matrigel TM . Because Matrigel has been shown to be the most useful matrix for static, traditional hepatocyte culture, we directly compared PLECM with Matrigel in each experiment. Albumin secretion, hepatic transport activity, and ammonia metabolism were used to determine hepatocyte function. Hepatocytes cultured between two layers of PLECM or Matrigel showed equally high levels of albumin expression and secretion, ammonia metabolism, and hepatic transporter expression and function. We conclude that like Matrigel, PLECM represents a favorable substrate for in vitro culture of human hepatocytes.

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Hepatic differentiation of amniotic epithelial cells

et al. 2011

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Hepatocyte transplantation to treat liver disease is largely limited by the availability of useful cells. Amniotic epithelial cells (hAECs) from term human placenta express surface markers and genes characteristic of embryonic stem cells and have the ability to differentiate into all three germ layers, including tissues of endodermal origin (i.e. liver). Thus, hAECs could provide a source of stem cell-derived hepatocytes for transplantation. We investigated the differentiation of hAECs in vitro and after transplantation into the liver of SCID/Beige mice. Moreover, we tested the ability of rat amniotic epithelial cells (rAECs) to replicate and differentiate upon transplantation into a syngenic model of liver repopulation. In vitro results indicate that the presence of extracellular matrix proteins together with a cocktail of growth factors, cytokines and hormones are required for differentiation of hAECs into hepatocyte-like cells. Differentiated hAECs expressed hepatocyte markers at levels comparable to those of fetal hepatocytes. They were able to metabolize ammonia, testosterone and 17α-hydroxyprogesterone caproate, and expressed inducible fetal cytochromes. After transplantation into the liver of Retrorsine (RS) treated SCID/beige mice, naïve hAECs differentiated into hepatocyte-like cells which expressed mature liver genes such as cytochromes, plasma proteins, transporters and other hepatic enzymes at levels equal to adult liver tissue. When transplanted in a syngenic animal pretreated with RS, rAECs were able to engraft and generate a progeny of cells with morphology and protein expression typical of mature hepatocytes. Conclusion amniotic epithelial cells possess the ability to differentiate into cells with characteristics of functional hepatocytes, in vitro and in vivo, thus representing a useful and non controversial source of cells for transplantation.

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MicroRNA‐328 is associated with (non‐small) cell lung cancer (NSCLC) brain metastasis and mediates NSCLC migration

Arora

Ranade

Tran

et al. 2011

Intl Journal of Cancer

153

126

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Brain metastasis (BM) can affect ~25% of non-small cell lung cancer (NSCLC) patients during their lifetime. Efforts to characterize patients that will develop BM have been disappointing. microRNAs (miRNAs) regulate the expression of target mRNAs. miRNAs play a role in regulating a variety of targets and, consequently, multiple pathways, which make them a powerful tool for early detection of disease, risk assessment, and prognosis. We investigated miRNAs that may serve as biomarkers to differentiate between NSCLC patients with and without BM. miRNA microarray profiling was performed on samples from clinically matched NSCLC from seven patients with BM (BM+) and six without BM (BM−). Using t-test and further qRT-PCR validation, eight miRNAs were confirmed to be significantly differentially-expressed. Of these, expression of miR-328 and miR-330-3p were able to correctly classify BM+ vs. BM− patients. This classifier was used on a validation cohort (n=15) and it correctly classified 12/15 patients. Gene expression analysis comparing A549 parental and A549 cells stably transfected to over-express miR-328 (A549–328) identified several significantly differentially-expressed genes. PRKCA was one of the genes over-expressed in A549–328 cells. Additionally, A549–328 cells had significantly increased cell migration compared to A549 cells, which was significantly reduced upon PRKCA knockdown. In summary, miR-328 has a role in conferring migratory potential to NSCLC cells working in part through PRKCA and with further corroboration in additional independent cohorts, these miRNAs may be incorporated into clinical treatment decision making to stratify NSCLC patients at higher risk for developing BM.

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MicroRNA 92a-2*: A Biomarker Predictive for Chemoresistance and Prognostic for Survival in Patients with Small Cell Lung Cancer

Ranade

Cherba

Sridhar

et al. 2010

Journal of Thoracic Oncology

115

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Aarati R. Ranade

Robust expansion of human hepatocytes in Fah−/−/Rag2−/−/Il2rg−/− mice

Maintenance of Human Hepatocyte FunctionIn Vitroby Liver-Derived Extracellular Matrix Gels

Hepatic differentiation of amniotic epithelial cells

MicroRNA‐328 is associated with (non‐small) cell lung cancer (NSCLC) brain metastasis and mediates NSCLC migration

MicroRNA 92a-2*: A Biomarker Predictive for Chemoresistance and Prognostic for Survival in Patients with Small Cell Lung Cancer

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