Approaches to in vitro tissue regeneration with application for human disease modeling and drug development

Reliable in vitro human disease models that capture the complexity of in vivo tissue behaviors are crucial to gain mechanistic insights into human disease and enable the development of treatments that are effective across broad patient populations. The integration of stem cell technologies, tissue engineering, emerging biomaterials strategies and microfabrication processes, as well as computational and systems biology approaches, is enabling new tools to generate reliable in vitro systems to study the molecular basis of human disease and facilitate drug development. In this review, we discuss these recently developed tools and emphasize opportunities and challenges involved in combining these technologies toward regenerative science.National Institute for Biomedical Imaging and Bioengineering (U.S.) (Grant 5R01EB010246-02)National Center for Advancing Translational Sciences (U.S.) (Grant 1UH2TR000496)United States. Defense Advanced Research Projects Agency (Cooperative Agreement W911NF-12-2-0039

Aag-initiated base excision repair promotes ischemia reperfusion injury in liver, brain, and kidney

Inflammation is accompanied by the release of highly reactive oxygen and nitrogen species (RONS) that damage DNA, among other cellular molecules. Base excision repair (BER) is initiated by DNA glycosylases and is crucial in repairing RONS-induced DNA damage; the alkyladenine DNA glycosylase (Aag/Mpg) excises several DNA base lesions induced by the inflammation-associated RONS release that accompanies ischemia reperfusion (I/R). Using mouse I/R models we demonstrate that Aag[superscript −/−] mice are significantly protected against, rather than sensitized to, I/R injury, and that such protection is observed across three different organs. Following I/R in liver, kidney, and brain, Aag[superscript −/−] mice display decreased hepatocyte death, cerebral infarction, and renal injury relative to wild-type. We infer that in wild-type mice, Aag excises damaged DNA bases to generate potentially toxic abasic sites that in turn generate highly toxic DNA strand breaks that trigger poly(ADP-ribose) polymerase (Parp) hyperactivation, cellular bioenergetics failure, and necrosis; indeed, steady-state levels of abasic sites and nuclear PAR polymers were significantly more elevated in wild-type vs. Aag[superscript −/−] liver after I/R. This increase in PAR polymers was accompanied by depletion of intracellular NAD and ATP levels plus the translocation and extracellular release of the high-mobility group box 1 (Hmgb1) nuclear protein, activating the sterile inflammatory response. We thus demonstrate the detrimental effects of Aag-initiated BER during I/R and sterile inflammation, and present a novel target for controlling I/R-induced injury.National Institutes of Health (U.S.) (Grant R01-CA055042)National Institutes of Health (U.S.) (Grant R01-CA149261)National Institutes of Health (U.S.) (Grant P30-ES02109)Ellison Medical Foundatio

Metabolite profiling and pharmacokinetic evaluation of hydrocortisone in a perfused 3D human liver bioreactor

Endotoxin lipopolysaccharide (LPS) is known to cause liver injury primarily involving inflammatory cells such as Kupffer cells, but few in vitro culture models are applicable for investigation of inflammatory effects on drug metabolism. We have developed a 3D human microphysiological hepatocyte-Kupffer-cell coculture system and evaluated the anti-inflammatory effect of glucocorticoids on liver cultures. LPS was introduced to the cultures to elicit an inflammatory response and assessed by the release of pro-inflammatory cytokines, IL6 and TNFα. A sensitive and specific RP-UHPLC-QTOF-MS method was used to evaluate hydrocortisone disappearance and metabolism at near physiological levels. For this, the systems were dosed with 100 nM hydrocortisone and circulated for two days; hydrocortisone was depleted to approximately 30 nM, with first-order kinetics. Phase I metabolites, including tetrahydrocortisone and dihydrocortisol, accounted for 8-10 % of the loss, and 45-52 % was phase II metabolites, including glucuronides of tetrahydrocortisol and tetrahydrocortisone. Pharmacokinetic parameters, i.e., half-life (t1/2), rate of elimination (kel), clearance (CL), and area under the curve (AUC), were 23.03 h, 0.03 h-1, 6.6x10-5 L. h-1 and 1.03 mg/L*h respectively. The ability of the bioreactor to predict the in vivo clearance of hydrocortisone was characterized and the obtained intrinsic clearance values correlated with human data. This system offers a physiologically-relevant tool for investigating hepatic function in an inflamed liver. Endotoxin lipopolysaccharide (LPS) is known to cause liver injury primarily involving inflammatory cells such as Kupffer cells, but few in vitro culture models are applicable for investigation of inflammatory effects on drug metabolism. We have developed a 3D human microphysiological hepatocyte-Kupffer-cell coculture system and evaluated the anti-inflammatory effect of glucocorticoids on liver cultures. LPS was introduced to the cultures to elicit an inflammatory response and assessed by the release of pro-inflammatory cytokines, IL6 and TNFα. A sensitive and specific RP-UHPLC-QTOF-MS method was used to evaluate hydrocortisone disappearance and metabolism at near physiological levels. For this, the systems were dosed with 100 nM hydrocortisone and circulated for two days; hydrocortisone was depleted to approximately 30 nM, with first-order kinetics. Phase I metabolites, including tetrahydrocortisone and dihydrocortisol, accounted for 8-10 % of the loss, and 45-52 % was phase II metabolites, including glucuronides of tetrahydrocortisol and tetrahydrocortisone. Pharmacokinetic parameters, i.e., half-life (t[subscript 1/2]), rate of elimination (k[subscript el]), clearance (CL), and area under the curve (AUC), were 23.03 h, 0.03 h[superscript -1], 6.6x10[superscript -5] L. h-1 and 1.03 mg/L*h respectively. The ability of the bioreactor to predict the in vivo clearance of hydrocortisone was characterized and the obtained intrinsic clearance values correlated with human data. This system offers a physiologically-relevant tool for investigating hepatic function in an inflamed liver.United States. Defense Advanced Research Projects Agency (DARPA-BAA-11-73 Microphysiological Systems W911NF-12-2-0039)National Institutes of Health (U.S.) (5-UH2-TR000496)Massachusetts Institute of Technology. Center for Environmental Health Sciences (P30-ES002109

TLR4-Dependent Secretion by Hepatic Stellate Cells of the Neutrophil-Chemoattractant CXCL1 Mediates Liver Response to Gut Microbiota

Background & Aims The gut microbiota significantly influences hepatic immunity. Little is known on the precise mechanism by which liver cells mediate recognition of gut microbes at steady state. Here we tested the hypothesis that a specific liver cell population was the sensor and we aimed at deciphering the mechanism by which the activation of TLR4 pathway would mediate liver response to gut microbiota. Methods Using microarrays, we compared total liver gene expression in WT versus TLR4 deficient mice. We performed in situ localization of the major candidate protein, CXCL1. With an innovative technique based on cell sorting, we harvested enriched fractions of KCs, LSECs and HSCs from the same liver. The cytokine secretion profile was quantified in response to low levels of LPS (1ng/mL). Chemotactic activity of stellate cell-derived CXCL1 was assayed in vitro on neutrophils upon TLR4 activation. Results TLR4 deficient liver had reduced levels of one unique chemokine, CXCL1 and subsequent decreased of neutrophil counts. Depletion of gut microbiota mimicked TLR4 deficient phenotype, i.e., decreased neutrophils counts in the liver. All liver cells were responsive to low levels of LPS, but hepatic stellate cells were the major source of chemotactic levels of CXCL1. Neutrophil migration towards secretory hepatic stellate cells required the TLR4 dependent secretion of CXCL1. Conclusions Showing the specific activation of TLR4 and the secretion of one major functional chemokine— CXCL1, the homolog of human IL-8-, we elucidate a new mechanism in which Hepatic Stellate Cells play a central role in the recognition of gut microbes by the liver at steady state.National Institute of Allergy and Infectious Diseases (U.S.) (Grant #1R01AI072049

Genetically engineering self-organization of human pluripotent stem cells into a liver bud-like tissue using Gata6

Human induced pluripotent stem cells (hiPSCs) have potential for personalized and regenerative medicine. While most of the methods using these cells have focused on deriving homogenous populations of specialized cells, there has been modest success in producing hiPSC-derived organotypic tissues or organoids. Here we present a novel approach for generating and then co-differentiating hiPSC-derived progenitors. With a genetically engineered pulse of GATA-binding protein 6 (GATA6) expression, we initiate rapid emergence of all three germ layers as a complex function of GATA6 expression levels and tissue context. Within 2 weeks we obtain a complex tissue that recapitulates early developmental processes and exhibits a liver bud-like phenotype, including haematopoietic and stromal cells as well as a neuronal niche. Collectively, our approach demonstrates derivation of complex tissues from hiPSCs using a single autologous hiPSCs as source and generates a range of stromal cells that co-develop with parenchymal cells to form tissues.National Science Foundation (U.S.). Emergent Behaviors of Integrated Cellular Systems (NSF CBET-0939511)Synthetic Biology Engineering Research CenterNational Institutes of Health (U.S.) (P50GM098792)Ernst Schering FoundationSwiss National Science Foundatio