Your search keyword '"McIntyre, Rebecca E"' showing total 4 results

1. Gut mucosa dissociation protocols influence cell type proportions and single-cell gene expression levels.

Author

Uniken Venema, Werna T. C., Ramírez-Sánchez, Aarón D., Bigaeva, Emilia, Withoff, Sebo, Jonkers, Iris, McIntyre, Rebecca E., Ghouraba, Mennatallah, Raine, Tim, Weersma, Rinse K., Franke, Lude, Festen, Eleonora A. M., and van der Wijst, Monique G. P.

Subjects

GENE expression, MUCOUS membranes, NEUROGLIA, SYNTHETIC genes, CELL survival, MICROARRAY technology

Abstract

Single-cell RNA sequencing (scRNA-seq) has revolutionized the study of the cellular landscape of organs. Most single-cell protocols require fresh material, which limits sample size per experiment, and consequently, introduces batch effects. This is especially true for samples acquired through complex medical procedures, such as intestinal mucosal biopsies. Moreover, the tissue dissociation procedure required for obtaining single cells is a major source of noise; different dissociation procedures applied to different compartments of the tissue induce artificial gene expression differences between cell subsets. To overcome these challenges, we have developed a one-step dissociation protocol and demonstrated its use on cryopreserved gut mucosal biopsies. Using flow cytometry and scRNA-seq analysis, we compared this one-step dissociation protocol with the current gold standard, two-step collagenase digestion, and an adaptation of a recently published alternative, three-step cold-active Bacillus licheniformus protease digestion. Both cell viability and cell type composition were comparable between the one-step and two-step collagenase dissociation, with the former being more time-efficient. The cold protease digestion resulted in equal cell viability, but better preserves the epithelial cell types. Consequently, to analyze the rarer cell types, such as glial cells, larger total biopsy cell numbers are required as input material. The multi-step protocols affected cell types spanning multiple compartments differently. In summary, we show that cryopreserved gut mucosal biopsies can be used to overcome the logistical challenges and batch effects in large scRNA-seq studies. Furthermore, we demonstrate that using cryopreserved biopsies digested using a one-step collagenase protocol enables large-scale scRNA-seq, FACS, organoid generation and intraepithelial lymphocyte expansion. [ABSTRACT FROM AUTHOR]

Published

2022

2. A high-throughput in vivo micronucleus assay for genome instability screening in mice.

Author

Balmus, Gabriel, Karp, Natasha A, Ng, Bee Ling, Jackson, Stephen P, Adams, David J, and McIntyre, Rebecca E

Published

2015

3. Disruption of mouse Slx4, a regulator of structure-specific nucleases, phenocopies Fanconi anemia.

Author

Crossan, Gerry P., van der Weyden, Louise, Rosado, Ivan V., Langevin, Frederic, Gaillard, Pierre-Henri L, McIntyre, Rebecca E, Gallagher, Ferdia, Kettunen, Mikko I., Lewis, David Y., Brindle, Kevin, Arends, Mark J., Adams, David J., and Patel, Ketan J.

Subjects

ENDONUCLEASES, FANCONI'S anemia, DNA damage, COMPLEMENTATION (Genetics), PROTEIN crosslinking, LABORATORY mice, GENETICS

Abstract

The evolutionarily conserved SLX4 protein, a key regulator of nucleases, is critical for DNA damage response. SLX4 nuclease complexes mediate repair during replication and can also resolve Holliday junctions formed during homologous recombination. Here we describe the phenotype of the Btbd12 knockout mouse, the mouse ortholog of SLX4, which recapitulates many key features of the human genetic illness Fanconi anemia. Btbd12-deficient animals are born at sub-Mendelian ratios, have greatly reduced fertility, are developmentally compromised and are prone to blood cytopenias. Btbd12−/− cells prematurely senesce, spontaneously accumulate damaged chromosomes and are particularly sensitive to DNA crosslinking agents. Genetic complementation reveals a crucial requirement for Btbd12 (also known as Slx4) to interact with the structure-specific endonuclease Xpf-Ercc1 to promote crosslink repair. The Btbd12 knockout mouse therefore establishes a disease model for Fanconi anemia and genetically links a regulator of nuclease incision complexes to the Fanconi anemia DNA crosslink repair pathway. [ABSTRACT FROM AUTHOR]

Published

2011

4. MEK1/2 inhibitor withdrawal reverses acquired resistance driven by BRAFV600E amplification whereas KRASG13D amplification promotes EMT-chemoresistance.

Author

Sale, Matthew J., Balmanno, Kathryn, Saxena, Jayeta, Ozono, Eiko, Wojdyla, Katarzyna, McIntyre, Rebecca E., Gilley, Rebecca, Woroniuk, Anna, Howarth, Karen D., Hughes, Gareth, Dry, Jonathan R., Arends, Mark J., Caro, Pilar, Oxley, David, Ashton, Susan, Adams, David J., Saez-Rodriguez, Julio, Smith, Paul D., and Cook, Simon J.

Abstract

Acquired resistance to MEK1/2 inhibitors (MEKi) arises through amplification of BRAFV600E or KRASG13D to reinstate ERK1/2 signalling. Here we show that BRAFV600E amplification and MEKi resistance are reversible following drug withdrawal. Cells with BRAFV600E amplification are addicted to MEKi to maintain a precise level of ERK1/2 signalling that is optimal for cell proliferation and survival, and tumour growth in vivo. Robust ERK1/2 activation following MEKi withdrawal drives a p57KIP2-dependent G1 cell cycle arrest and senescence or expression of NOXA and cell death, selecting against those cells with amplified BRAFV600E. p57KIP2 expression is required for loss of BRAFV600E amplification and reversal of MEKi resistance. Thus, BRAFV600E amplification confers a selective disadvantage during drug withdrawal, validating intermittent dosing to forestall resistance. In contrast, resistance driven by KRASG13D amplification is not reversible; rather ERK1/2 hyperactivation drives ZEB1-dependent epithelial-to-mesenchymal transition and chemoresistance, arguing strongly against the use of drug holidays in cases of KRASG13D amplification. Colorectal cancer cells can acquire resistance to MEK inhibition due to BRAF or KRAS amplification. Here, the authors show that while MEK inhibitor withdrawal in BRAF mutant cells restores sensitivity to the inhibitor through the loss of BRAF amplification mediated by a p57-dependent mechanism, drug withdrawal from KRAS mutant cells does not restore sensitivity but results in EMT and chemoresistance. [ABSTRACT FROM AUTHOR]

Published

2019