Hydrostatic pressure regulates CYP1A2 expression in human hepatocytes via a mechanosensitive aryl hydrocarbon receptor-dependent pathway

Burton, Lewis; Scaife, Paula J.; Paine, Stuart W.; Mellor, Howard R.; Abernethy, Lynn; Littlewood, Peter; Rauch, Cyril

doi:10.1152/ajpcell.00472.2019

Cited by 10 publications

(5 citation statements)

References 64 publications

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“…Just as cholangiocytes, hepatocytes are mechano-sensitively regulated (Burton et al 2020 ). In hepatocytes and cholangiocytes we found AT1R localized between TJs and AJs, a predestined position to work as mechanosensor.…”

Section: Discussionmentioning

confidence: 99%

Angiotensin II type 1 receptor localizes at the blood–bile barrier in humans and pigs

Pryymachuk

El-Awaad

Piekarek

et al. 2022

Histochem Cell Biol

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Animal models and clinical studies suggest an influence of angiotensin II (AngII) on the pathogenesis of liver diseases via the renin–angiotensin system. AngII application increases portal blood pressure, reduces bile flow, and increases permeability of liver tight junctions. Establishing the subcellular localization of angiotensin II receptor type 1 (AT1R), the main AngII receptor, helps to understand the effects of AngII on the liver. We localized AT1R in situ in human and porcine liver and porcine gallbladder by immunohistochemistry. In order to do so, we characterized commercial anti-AT1R antibodies regarding their capability to recognize heterologous human AT1R in immunocytochemistry and on western blots, and to detect AT1R using overlap studies and AT1R-specific blocking peptides. In hepatocytes and canals of Hering, AT1R displayed a tram-track-like distribution, while in cholangiocytes AT1R appeared in a honeycomb-like pattern; i.e., in liver epithelia, AT1R showed an equivalent distribution to that in the apical junctional network, which seals bile canaliculi and bile ducts along the blood–bile barrier. In intrahepatic blood vessels, AT1R was most prominent in the tunica media. We confirmed AT1R localization in situ to the plasma membrane domain, particularly between tight and adherens junctions in both human and porcine hepatocytes, cholangiocytes, and gallbladder epithelial cells using different anti-AT1R antibodies. Localization of AT1R at the junctional complex could explain previously reported AngII effects and predestines AT1R as a transmitter of tight junction permeability.

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Section: Discussionmentioning

confidence: 99%

Angiotensin II type 1 receptor localizes at the blood–bile barrier in humans and pigs

Pryymachuk

El-Awaad

Piekarek

et al. 2022

Histochem Cell Biol

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“…The mechano core map 9 has been updated with new entities f rom 12 recent (2015-2023) comprehensive review articles [11][12][13][14][15][16][17][18][19][20][21][22] and f ive research articles specif ically related to the review of the role of the aryl hydrocarbon receptor (AhR [23][24][25][26][27] ), which, in addition to its recognized role as a sensor f or endo -and xenobiotics, has recently been recognized as having role in the transduction of mechanical signals, particularly those associated with endothelial f luid shear stress and directional migration. Publications have been manually selected using the keywords "mechanotransduction", "mechanical stimuli", and "mechanical f orce".…”

Section: Construction Of the Mechanotransduction Sbml Pathwaymentioning

confidence: 99%

Mechanotransduction and inflammation: an updated comprehensive representation

Suryiagandhi,

Ma,

Paparozzi

et al. 2024

Preprint

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Mechanotransduction is the process that enables the conversion of mechanical cues into biochemical signaling. While all our cells are well known to be sensitive to such stimuli, the details of the systemic interaction between mechanical input and inflammation are not always well integrated. Often, they are considered and studied in relatively compartmentalized areas, and we therefore argue here that to understand the relationship of mechanical stimuli with inflammation – with high translational potential - it is crucial to offer and analyze a unified view of mechanotransduction. We therefore offer here a pathway representation, recollected with the standard systems biology markup language (SBML) and explored with network biology approaches. We present RAC1 as an exemplar and emerging molecule with potential for medical translation.

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“…We fix numbers of intra-and inter-Layer edges for all experiments, but their SS-to-SS connections are Monte Carlo-sampled for each execution. Having more edges than SSs enables mimicking the wide variety of PV-to-CV flow paths within lobules [24]. Interconnections are essential to enable the same vLiver to achieve previously described isolated perfused liver validation targets for several different drugs [13,14].…”

Section: Plos Onementioning

confidence: 99%

Utilizing virtual experiments to increase understanding of discrepancies involving in vitro-to-in vivo predictions of hepatic clearance

Krishnan

Smith²,

Ropella³

et al. 2022

PLoS ONE

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Predictions of xenobiotic hepatic clearance in humans using in vitro-to-in vivo extrapolation methods are frequently inaccurate and problematic. Multiple strategies are being pursued to disentangle responsible mechanisms. The objective of this work is to evaluate the feasibility of using insights gained from independent virtual experiments on two model systems to begin unraveling responsible mechanisms. The virtual culture is a software analog of hepatocytes in vitro, and the virtual human maps to hepatocytes within a liver within an idealized model human. Mobile objects (virtual compounds) map to amounts of xenobiotics. Earlier versions of the two systems achieved quantitative validation targets for intrinsic clearance (virtual culture) and hepatic clearance (virtual human). The major difference between the two systems is the spatial organization of the virtual hepatocytes. For each pair of experiments (virtual culture, virtual human), hepatocytes are configured the same. Probabilistic rules govern virtual compound movements and interactions with other objects. We focus on highly permeable virtual compounds and fix their extracellular unbound fraction at one of seven values (0.05–1.0). Hepatocytes contain objects that can bind and remove compounds, analogous to metabolism. We require that, for a subset of compound properties, per-hepatocyte compound exposure and removal rates during culture experiments directly predict corresponding measures made during virtual human experiments. That requirement serves as a cross-system validation target; we identify compound properties that enable achieving it. We then change compound properties, ceteris paribus, and provide model mechanism-based explanations for when and why measures made during culture experiments under- (or over-) predict corresponding measures made during virtual human experiments. The results show that, from the perspective of compound removal, the organization of hepatocytes within virtual livers is more efficient than within cultures, and the greater the efficiency difference, the larger the underprediction. That relationship is noteworthy because most in vitro-to-in vivo extrapolation methods abstract away the structural organization of hepatocytes within a liver. More work is needed on multiple fronts, including the study of an expanded variety of virtual compound properties. Nevertheless, the results support the feasibility of the approach and plan.

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Hydrostatic pressure regulates CYP1A2 expression in human hepatocytes via a mechanosensitive aryl hydrocarbon receptor-dependent pathway

Cited by 10 publications

References 64 publications

Angiotensin II type 1 receptor localizes at the blood–bile barrier in humans and pigs

Angiotensin II type 1 receptor localizes at the blood–bile barrier in humans and pigs

Mechanotransduction and inflammation: an updated comprehensive representation

Utilizing virtual experiments to increase understanding of discrepancies involving in vitro-to-in vivo predictions of hepatic clearance

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