Your search keyword '"Jens Puschhof"' showing total 4 results

1. The microbial genotoxin colibactin exacerbates mismatch repair mutations in colorectal tumors

Author

Michael W. Dougherty, Rafael Valdés-Mas, Kevin M. Wernke, Raad Z. Gharaibeh, Ye Yang, Jason O. Brant, Alberto Riva, Marcus Muehlbauer, Eran Elinav, Jens Puschhof, Seth B. Herzon, and Christian Jobin

Subjects

Colibactin, Escherichia coli, Mutation, Colorectal cancer, Mismatch repair, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Certain Enterobacteriaceae strains contain a 54-kb biosynthetic gene cluster referred to as “pks” encoding the biosynthesis of a secondary metabolite, colibactin. Colibactin-producing E. coli promote colorectal cancer (CRC) in preclinical models, and in vitro induce a specific mutational signature that is also detected in human CRC genomes. Yet, how colibactin exposure affects the mutational landscape of CRC in vivo remains unclear. Here we show that colibactin-producing E. coli-driven colonic tumors in mice have a significantly higher SBS burden and a larger percentage of these mutations can be attributed to a signature associated with mismatch repair deficiency (MMRd; SBS15), compared to tumors developed in the presence of colibactin-deficient E. coli. We found that the synthetic colibactin 742 but not an inactive analog 746 causes DNA damage and induces transcriptional activation of p53 and senescence signaling pathways in non-transformed human colonic epithelial cells. In MMRd colon cancer cells (HCT 116), chronic exposure to 742 resulted in the upregulation of BRCA1, Fanconi anemia, and MMR signaling pathways as revealed by global transcriptomic analysis. This was accompanied by increased T>N single-base substitutions (SBS) attributed to the proposed pks+ E. coli signature (SBS88), reactive oxygen species (SBS17), and mismatch-repair deficiency (SBS44). A significant co-occurrence between MMRd SBS44 and pks-associated SBS88 signature was observed in a large cohort of human CRC patients (n=2,945), and significantly more SBS44 mutations were found when SBS88 was also detected. Collectively, these findings reveal the host response mechanisms underlying colibactin genotoxic activity and suggest that colibactin may exacerbate MMRd-associated mutations.

Published

2023

2. Differentiation and CRISPR-Cas9-mediated genetic engineering of human intestinal organoids

Author

Adriana Martinez-Silgado, Fjodor A. Yousef Yengej, Jens Puschhof, Veerle Geurts, Charelle Boot, Maarten H. Geurts, Maarten B. Rookmaaker, Marianne C. Verhaar, Joep Beumer, and Hans Clevers

Subjects

CRISPR, Cell differentiation, Organoids, Science (General), Q1-390

Abstract

Summary: Intestinal organoids are three-dimensional cultures that resemble key aspects of the epithelium of origin. Here, we describe how to differentiate human small intestinal organoids by combining growth media variations and genetic engineering. We detail the differentiation of human intestinal organoids in the presence and absence of BMP agonists to recapitulate a broader scope of functional cell states found in vivo. Using transient overexpression of the transcription factor Neurogenin-3, we describe the enhancement of differentiation toward rare enteroendocrine cells.For complete details on the use and execution of this protocol, please refer to Beumer et al. (2022). : Publisher’s note: Undertaking any experimental protocol requires adherence to local institutional guidelines for laboratory safety and ethics.

Published

2022

3. Novel Chimeric Gene Therapy Vectors Based on Adeno-Associated Virus and Four Different Mammalian Bocaviruses

Author

Julia Fakhiri, Marc A. Schneider, Jens Puschhof, Megan Stanifer, Verena Schildgen, Stefan Holderbach, Yannik Voss, Jihad El Andari, Oliver Schildgen, Steeve Boulant, Michael Meister, Hans Clevers, Ziying Yan, Jianming Qiu, and Dirk Grimm

Subjects

Genetics, QH426-470, Cytology, QH573-671

Abstract

Parvoviruses are highly attractive templates for the engineering of safe, efficient, and specific gene therapy vectors, as best exemplified by adeno-associated virus (AAV). Another candidate that currently garners increasing attention is human bocavirus 1 (HBoV1). Notably, HBoV1 capsids can cross-package recombinant (r)AAV2 genomes, yielding rAAV2/HBoV1 chimeras that specifically transduce polarized human airway epithelia (pHAEs). Here, we largely expanded the repertoire of rAAV/BoV chimeras, by assembling packaging plasmids encoding the capsid genes of four additional primate bocaviruses, HBoV2–4 and GBoV (Gorilla BoV). Capsid protein expression and efficient rAAV cross-packaging were validated by immunoblotting and qPCR, respectively. Interestingly, not only HBoV1 but also HBoV4 and GBoV transduced pHAEs as well as primary human lung organoids. Flow cytometry analysis of pHAEs revealed distinct cellular specificities between the BoV isolates, with HBoV1 targeting ciliated, club, and KRT5+ basal cells, whereas HBoV4 showed a preference for KRT5+ basal cells. Surprisingly, primary human hepatocytes, skeletal muscle cells, and T cells were also highly amenable to rAAV/BoV transduction. Finally, we adapted our pipeline for AAV capsid gene shuffling to all five BoV isolates. Collectively, our chimeric rAAV/BoV vectors and bocaviral capsid library represent valuable new resources to dissect BoV biology and to breed unique gene therapy vectors. Keywords: adeno-associated virus, AAV, bocavirus, BoV, capsid engineering

Published

2019

4. Novel Chimeric Gene Therapy Vectors Based on Adeno-Associated Virus and Four Different Mammalian Bocaviruses

Author

Megan L. Stanifer, Hans Clevers, Steeve Boulant, Dirk Grimm, Jianming Qiu, Oliver Schildgen, Jens Puschhof, Stefan Holderbach, Verena Schildgen, Michael Meister, Julia Fakhiri, Marc A. Schneider, Ziying Yan, Jihad El Andari, Yannik Voss, and Hubrecht Institute for Developmental Biology and Stem Cell Research

Subjects

0301 basic medicine, lcsh:QH426-470, BoV, viruses, Chimeric gene, adeno-associated virus, Vectors in gene therapy, Biology, medicine.disease_cause, Virus, Article, bocavirus, capsid engineering, 03 medical and health sciences, Transduction (genetics), 0302 clinical medicine, Plasmid, Genetics, medicine, lcsh:QH573-671, Molecular Biology, Gene, Adeno-associated virus, lcsh:Cytology, AAV, Virology, lcsh:Genetics, 030104 developmental biology, Capsid, 030220 oncology & carcinogenesis, Molecular Medicine

Abstract

Parvoviruses are highly attractive templates for the engineering of safe, efficient, and specific gene therapy vectors, as best exemplified by adeno-associated virus (AAV). Another candidate that currently garners increasing attention is human bocavirus 1 (HBoV1). Notably, HBoV1 capsids can cross-package recombinant (r)AAV2 genomes, yielding rAAV2/HBoV1 chimeras that specifically transduce polarized human airway epithelia (pHAEs). Here, we largely expanded the repertoire of rAAV/BoV chimeras, by assembling packaging plasmids encoding the capsid genes of four additional primate bocaviruses, HBoV2–4 and GBoV (Gorilla BoV). Capsid protein expression and efficient rAAV cross-packaging were validated by immunoblotting and qPCR, respectively. Interestingly, not only HBoV1 but also HBoV4 and GBoV transduced pHAEs as well as primary human lung organoids. Flow cytometry analysis of pHAEs revealed distinct cellular specificities between the BoV isolates, with HBoV1 targeting ciliated, club, and KRT5+ basal cells, whereas HBoV4 showed a preference for KRT5+ basal cells. Surprisingly, primary human hepatocytes, skeletal muscle cells, and T cells were also highly amenable to rAAV/BoV transduction. Finally, we adapted our pipeline for AAV capsid gene shuffling to all five BoV isolates. Collectively, our chimeric rAAV/BoV vectors and bocaviral capsid library represent valuable new resources to dissect BoV biology and to breed unique gene therapy vectors. Keywords: adeno-associated virus, AAV, bocavirus, BoV, capsid engineering

Published

2019