Your search keyword '"Raven, Alexander"' showing total 5 results

1. Impairing hepatocyte regeneration to determine the regenerative capacity of the biliary epithelium

Author

Raven, Alexander Philip, Forbes, Stuart, and Ffrench-Constant, Charles

Subjects

616.3, liver, regeneration, liver regeneration, stem cell

Abstract

Liver injury stimulates hepatocyte proliferation, regenerating the liver through self-replication. In cases where there is severe, repetitive, parenchymal damage, as seen in human chronic liver disease, hepatocyte mediated regeneration becomes impaired. In this setting it is currently unclear whether endogenous biliary epithelial cells can repopulate the hepatocyte compartment. This thesis therefore aimed to address this point by lineage tracing the main two liver epithelia populations on a background of impaired hepatocyte regeneration. To impair regeneration, an Itgb1 transgene was specifically deleted, conditionally, from the hepatocyte epithelium. Long-term loss of β1-Integrin alone or with additional injury caused an epithelial ductular reaction of biliary origin. Alongside β1-Integrin ablation, the hepatocyte epithelium was also labelled with a heritable ROSA26LSLtdTomato reporter. Impaired hepatocyte regeneration mediated by β1- integrin ablation resulted in 25% of hepatocytes becoming tdTomato negative (non-hepatocyte derived). To verify that the non-hepatocyte mediated regeneration was originating from the biliary epithelium, anti-Itgb1 RNAi was administrated to K19CreERT LSLtdTomato mice. Resulting in tdTomato positive hepatocytes that had differentiated from the labelled tdTomato positive biliary epithelial cells. In summary, this thesis demonstrates that hepatocyte β1-Integrin ablation combined with toxic damage causes marked ductular reactions and results in a substantial regeneration of functional hepatocytes from the biliary epithelium.

Published

2018

2. Metabolic profiling stratifies colorectal cancer and reveals adenosylhomocysteinase as a therapeutic target

Author

Vande Voorde, Johan, Steven, Rory T., Najumudeen, Arafath K., Ford, Catriona A., Dexter, Alex, Gonzalez-Fernandez, Ariadna, Nikula, Chelsea J., Xiang, Yuchen, Ford, Lauren, Maneta Stavrakaki, Stefania, Gilroy, Kathryn, Zeiger, Lucas B., Pennel, Kathryn, Hatthakarnkul, Phimmada, Elia, Efstathios A., Nasif, Ammar, Murta, Teresa, Manoli, Eftychios, Mason, Sam, Gillespie, Michael, Lannagan, Tamsin R.M., Vlahov, Nikola, Ridgway, Rachel A., Nixon, Colin, Raven, Alexander, Mills, Megan, Athineos, Dimitris, Kanellos, Georgios, Nourse, Craig, Gay, David M., Hughes, Mark, Burton, Amy, Yan, Bin, Sellers, Katherine, Wu, Vincen, De Ridder, Kobe, Shokry, Engy, Huerta Uribe, Alejandro, Clark, William, Clark, Graeme, Kirschner, Kristina, Thienpont, Bernard, Li, Vivian S.W., Maddocks, Oliver D.K., Barry, Simon T., Goodwin, Richard J.A., Kinross, James, Edwards, Joanne, Yuneva, Mariia O., Sumpton, David, Takats, Zoltan, Campbell, Andrew D., Bunch, Josephine, Sansom, Owen J., Vande Voorde, Johan, Steven, Rory T., Najumudeen, Arafath K., Ford, Catriona A., Dexter, Alex, Gonzalez-Fernandez, Ariadna, Nikula, Chelsea J., Xiang, Yuchen, Ford, Lauren, Maneta Stavrakaki, Stefania, Gilroy, Kathryn, Zeiger, Lucas B., Pennel, Kathryn, Hatthakarnkul, Phimmada, Elia, Efstathios A., Nasif, Ammar, Murta, Teresa, Manoli, Eftychios, Mason, Sam, Gillespie, Michael, Lannagan, Tamsin R.M., Vlahov, Nikola, Ridgway, Rachel A., Nixon, Colin, Raven, Alexander, Mills, Megan, Athineos, Dimitris, Kanellos, Georgios, Nourse, Craig, Gay, David M., Hughes, Mark, Burton, Amy, Yan, Bin, Sellers, Katherine, Wu, Vincen, De Ridder, Kobe, Shokry, Engy, Huerta Uribe, Alejandro, Clark, William, Clark, Graeme, Kirschner, Kristina, Thienpont, Bernard, Li, Vivian S.W., Maddocks, Oliver D.K., Barry, Simon T., Goodwin, Richard J.A., Kinross, James, Edwards, Joanne, Yuneva, Mariia O., Sumpton, David, Takats, Zoltan, Campbell, Andrew D., Bunch, Josephine, and Sansom, Owen J.

Abstract

The genomic landscape of colorectal cancer (CRC) is shaped by inactivating mutations in tumour suppressors such as APC, and oncogenic mutations such as mutant KRAS. Here we used genetically engineered mouse models, and multimodal mass spectrometry-based metabolomics to study the impact of common genetic drivers of CRC on the metabolic landscape of the intestine. We show that untargeted metabolic profiling can be applied to stratify intestinal tissues according to underlying genetic alterations, and use mass spectrometry imaging to identify tumour, stromal and normal adjacent tissues. By identifying ions that drive variation between normal and transformed tissues, we found dysregulation of the methionine cycle to be a hallmark of APC-deficient CRC. Loss of Apc in the mouse intestine was found to be sufficient to drive expression of one of its enzymes, adenosylhomocysteinase (AHCY), which was also found to be transcriptionally upregulated in human CRC. Targeting of AHCY function impaired growth of APC-deficient organoids in vitro, and prevented the characteristic hyperproliferative/crypt progenitor phenotype driven by acute deletion of Apc in vivo, even in the context of mutant Kras. Finally, pharmacological inhibition of AHCY reduced intestinal tumour burden in Apc Min/+ mice indicating its potential as a metabolic drug target in CRC.

Published

2023

3. NOTUM from Apc-mutant cells biases clonal competition to initiate cancer

Author

Flanagan, Dustin J, Pentinmikko, Nalle, Luopajärvi, Kalle, Willis, Nicky J, Gilroy, Kathryn, Raven, Alexander P, Mcgarry, Lynn, Englund, Johanna I, Webb, Anna T, Scharaw, Sandra, Nasreddin, Nadia, Hodder, Michael C, Ridgway, Rachel A, Minnee, Emma, Sphyris, Nathalie, Gilchrist, Ella, Najumudeen, Arafath K, Romagnolo, Beatrice, Perret, Christine, Williams, Ann C, Clevers, Hans, Nummela, Pirjo, Lähde, Marianne, Alitalo, Kari, Hietakangas, Ville, Hedley, Ann, Clark, William, Nixon, Colin, Kirschner, Kristina, Jones, E Yvonne, Ristimäki, Ari, Leedham, Simon J, Fish, Paul V, Vincent, Jean-Paul, Katajisto, Pekka, Sansom, Owen J, Flanagan, Dustin J, Pentinmikko, Nalle, Luopajärvi, Kalle, Willis, Nicky J, Gilroy, Kathryn, Raven, Alexander P, Mcgarry, Lynn, Englund, Johanna I, Webb, Anna T, Scharaw, Sandra, Nasreddin, Nadia, Hodder, Michael C, Ridgway, Rachel A, Minnee, Emma, Sphyris, Nathalie, Gilchrist, Ella, Najumudeen, Arafath K, Romagnolo, Beatrice, Perret, Christine, Williams, Ann C, Clevers, Hans, Nummela, Pirjo, Lähde, Marianne, Alitalo, Kari, Hietakangas, Ville, Hedley, Ann, Clark, William, Nixon, Colin, Kirschner, Kristina, Jones, E Yvonne, Ristimäki, Ari, Leedham, Simon J, Fish, Paul V, Vincent, Jean-Paul, Katajisto, Pekka, and Sansom, Owen J

Abstract

The tumour suppressor APC is the most commonly mutated gene in colorectal cancer. Loss of Apc in intestinal stem cells drives the formation of adenomas in mice via increased WNT signalling1, but reduced secretion of WNT ligands increases the ability of Apc-mutant intestinal stem cells to colonize a crypt (known as fixation)2. Here we investigated how Apc-mutant cells gain a clonal advantage over wild-type counterparts to achieve fixation. We found that Apc-mutant cells are enriched for transcripts that encode several secreted WNT antagonists, with Notum being the most highly expressed. Conditioned medium from Apc-mutant cells suppressed the growth of wild-type organoids in a NOTUM-dependent manner. Furthermore, NOTUM-secreting Apc-mutant clones actively inhibited the proliferation of surrounding wild-type crypt cells and drove their differentiation, thereby outcompeting crypt cells from the niche. Genetic or pharmacological inhibition of NOTUM abrogated the ability of Apc-mutant cells to expand and form intestinal adenomas. We identify NOTUM as a key mediator during the early stages of mutation fixation that can be targeted to restore wild-type cell competitiveness and provide preventative strategies for people at a high risk of developing colorectal cancer.

Published

2021

4. Epigenetic remodelling licences adult cholangiocytes for organoid formation and liver regeneration

Author

Aloia, Luigi, McKie, Mikel Alexander, Vernaz, Grégoire, Cordero-Espinoza, Lucía, Aleksieva, Niya, van den Ameele, Jelle, Antonica, Francesco, Font-Cunill, Berta, Raven, Alexander, Aiese Cigliano, Riccardo, Belenguer, German, Mort, Richard L., Brand, Andrea H, Zernicka-Goetz, Magdalena, Forbes, Stuart J, Miska, Eric A, Huch, Meritxell, Aloia, Luigi, McKie, Mikel Alexander, Vernaz, Grégoire, Cordero-Espinoza, Lucía, Aleksieva, Niya, van den Ameele, Jelle, Antonica, Francesco, Font-Cunill, Berta, Raven, Alexander, Aiese Cigliano, Riccardo, Belenguer, German, Mort, Richard L., Brand, Andrea H, Zernicka-Goetz, Magdalena, Forbes, Stuart J, Miska, Eric A, and Huch, Meritxell

Abstract

Following severe or chronic liver injury, adult ductal cells (cholangiocytes) contribute to regeneration by restoring both hepatocytes and cholangiocytes. We recently showed that ductal cells clonally expand as self-renewing liver organoids that retain their differentiation capacity into both hepatocytes and ductal cells. However, the molecular mechanisms by which adult ductal-committed cells acquire cellular plasticity, initiate organoids and regenerate the damaged tissue remain largely unknown. Here, we describe that ductal cells undergo a transient, genome-wide, remodelling of their transcriptome and epigenome during organoid initiation and in vivo following tissue damage. TET1-mediated hydroxymethylation licences differentiated ductal cells to initiate organoids and activate the regenerative programme through the transcriptional regulation of stem-cell genes and regenerative pathways including the YAP-Hippo signalling. Our results argue in favour of the remodelling of genomic methylome/hydroxymethylome landscapes as a general mechanism by which differentiated cells exit a committed state in response to tissue damage.

Published

2019

5. Notch3 drives development and progression of cholangiocarcinoma.

Author

UCL - SSS/IREC-Institut de recherche expérimentale et clinique, UCL - SSS/IREC/GAEN-Pôle d'Hépato-gastro-entérologie, UCL - (SLuc) Service d'anatomie pathologique, Guest, Rachel V, Boulter, Luke, Dwyer, Benjamin J, Kendall, Timothy J, Man, Tak-Yung, Minnis-Lyons, Sarah E, Lu, Wei-Yu, Robson, Andrew J, Gonzalez, Sofia Ferreira, Raven, Alexander, Wojtacha, Davina, Morton, Jennifer P, Komuta, Mina, Roskams, Tania, Wigmore, Stephen J, Sansom, Owen J, Forbes, Stuart J, UCL - SSS/IREC-Institut de recherche expérimentale et clinique, UCL - SSS/IREC/GAEN-Pôle d'Hépato-gastro-entérologie, UCL - (SLuc) Service d'anatomie pathologique, Guest, Rachel V, Boulter, Luke, Dwyer, Benjamin J, Kendall, Timothy J, Man, Tak-Yung, Minnis-Lyons, Sarah E, Lu, Wei-Yu, Robson, Andrew J, Gonzalez, Sofia Ferreira, Raven, Alexander, Wojtacha, Davina, Morton, Jennifer P, Komuta, Mina, Roskams, Tania, Wigmore, Stephen J, Sansom, Owen J, and Forbes, Stuart J

Abstract

The prognosis of cholangiocarcinoma (CC) is dismal. Notch has been identified as a potential driver; forced exogenous overexpression of Notch1 in hepatocytes results in the formation of biliary tumors. In human disease, however, it is unknown which components of the endogenously signaling pathway are required for tumorigenesis, how these orchestrate cancer, and how they can be targeted for therapy. Here we characterize Notch in human-resected CC, a toxin-driven model in rats, and a transgenic mouse model in which p53 deletion is targeted to biliary epithelia and CC induced using the hepatocarcinogen thioacetamide. We find that across species, the atypical receptor NOTCH3 is differentially overexpressed; it is progressively up-regulated with disease development and promotes tumor cell survival via activation of PI3k-Akt. We use genetic KO studies to show that tumor growth significantly attenuates after Notch3 deletion and demonstrate signaling occurs via a noncanonical pathway independent of the mediator of classical Notch, Recombinant Signal Binding Protein for Immunoglobulin Kappa J Region (RBPJ). These data present an opportunity in this aggressive cancer to selectively target Notch, bypassing toxicities known to be RBPJ dependent.

Published

2016