Your search keyword '"Julia Lefler"' showing total 5 results

1. The splanchnic mesenchyme is the tissue of origin for pancreatic fibroblasts during homeostasis and tumorigenesis

Author

Lu Han, Yongxia Wu, Kun Fang, Sean Sweeney, Ulyss K. Roesner, Melodie Parrish, Khushbu Patel, Tom Walter, Julia Piermattei, Anthony Trimboli, Julia Lefler, Cynthia D. Timmers, Xue-Zhong Yu, Victor X. Jin, Michael T. Zimmermann, Angela J. Mathison, Raul Urrutia, Michael C. Ostrowski, and Gustavo Leone

Subjects

Science

Abstract

Cancer-associated fibroblasts (CAFs) are the main component of the stroma in pancreatic cancer, but their tissue of origin remains to be defined. Here the authors perform lineage tracing and single cell RNA sequencing in mice and suggest the splanchnic mesenchyme as the tissue of origin for CAFs.

Published

2023

2. Abstract B013: Exploring the switch II pocket of KRAS(G12D) with mutant-selective monobody inhibitors

Author

Takamitsu Hattori, Padma Akkapeddi, Imran Khan, Akiko Koide, Eliezra Glasser, Gayatri Ketavarapu, Michael Whaby, Mariyam Zuberi, Kai Wen Teng, Julia Lefler, Lorenzo Maso, Injin Bang, Michael C. Ostrowski, John P. O’Bryan, and Shohei Koide

Subjects

Cancer Research, Oncology, Molecular Biology

Abstract

The G12D mutation is among the most common KRAS mutations associated with cancer, in particular pancreatic cancer. Here, we have developed monobodies, small synthetic binding proteins, that are highly selective to KRAS(G12D) over KRAS(wild type) and other oncogenic KRAS mutations, as well as over HRAS(G12D). Crystallographic studies revealed that, similar to other KRAS mutant-selective inhibitors, the initial monobody bound to the S-II pocket, the groove between switch II and alpha 3 helix. Strikingly, the monobody captured a shape of the S-II pocket distinct from previously reported structures. Unlike other G12D-selective polypeptides reported to date, the monobody used its backbone NH group to directly recognize the side chain of RAS Asp12. This feature closely resembles that of a small-molecule KRAS(G12D) inhibitor, MRTX1133. The monobody also directly interacted with H95, a residue not conserved in HRAS. These features rationalize the high selectivity toward the G12D mutant and the KRAS isoform. Structure-guided affinity maturation resulted in monobodies with low nM KD values. Deep mutational scanning of a G12D-specific monobody generated hundreds of functional and nonfunctional single-point mutants, from which we identified crucial residues for binding and those that contributed to the selectivity toward the GTP- and GDP-bound states. When expressed in cells as genetically encoded reagents, these monobodies engaged selectively with KRAS(G12D) and inhibited KRAS(G12D)-mediated signaling and tumorigenesis. These results demonstrate the feasibility of targeting KRAS(G12D) functions using a mutant selective inhibitor and will guide the development of next-generation KRAS(G12D)-selective inhibitors. Citation Format: Takamitsu Hattori, Padma Akkapeddi, Imran Khan, Akiko Koide, Eliezra Glasser, Gayatri Ketavarapu, Michael Whaby, Mariyam Zuberi, Kai Wen Teng, Julia Lefler, Lorenzo Maso, Injin Bang, Michael C. Ostrowski, John P. O’Bryan, Shohei Koide. Exploring the switch II pocket of KRAS(G12D) with mutant-selective monobody inhibitors [abstract]. In: Proceedings of the AACR Special Conference: Targeting RAS; 2023 Mar 5-8; Philadelphia, PA. Philadelphia (PA): AACR; Mol Cancer Res 2023;21(5_Suppl):Abstract nr B013.

Published

2023

3. Abstract 5847: The splanchnic mesenchyme is the main tissue origin of fibroblasts in the pancreas during homeostasis and tumorigenesis

Author

Lu Han, Yongxia Wu, Kun Fang, Sean Sweeney, Ulyss Roesner, Melodie Parrish, Khushbu Patel, Tom Walter, Julia Piermattei, Anthony Trimboli, Julia Lefler, Cynthia Timmers, Xue-Zhong Yu, Victor Jin, Michael Zimmermann, Angela Mathison, Raul Urrutia, Michael Ostrowski, and Gustavo Leone

Subjects

Cancer Research, Oncology

Abstract

In pancreatic ductal adenocarcinoma (PDAC), cancer associated fibroblasts (CAFs) play critical and complex roles in the tumor microenvironment. CAFs are also a major cell type in the desmoplastic stroma in PDAC and may account for half of the entire tumor tissue. Multiple subtypes of CAFs have been suggested, but the tissue origin(s) of CAF subtypes are unknown and genetic tools to robustly target them in vivo are lacking. Here we aimed to examine three potential tissue sources of CAFs: the pancreatic epithelium (through epithelium-to-mesenchyme transition), the bone marrow (through circulation), and the pancreatic mesenchyme or tissue resident fibroblasts (TRFs) in the normal pancreas (through proliferation). We utilized a genetically engineered mouse model of PDAC, where Kras and p53 mutations were engineered in the pancreatic epithelium using an Flp-Frt system. To determine whether the pancreatic epithelium gives rise to CAFs, we permanently labeled the pancreatic epithelium with a GFP reporter and traced their cell descendants by GFP expression. Despite robust GFP labeling of the epithelium, GFP expression was rarely identified in CAFs. To determine whether the bone marrow gives rise to CAFs, we transplanted donor bone marrow carrying a ubiquitously expressed GFP reporter to GFP-negative recipient mice. We found that minimal proportion of pancreatic CAFs were tagged with GFP. Lastly, to determine whether pancreatic TRFs give rise to CAFs, we used an inducible CreER-LoxP system to allow for permanent Tomato labeling in TRF progenitors, the splanchnic mesenchyme, during mid-gestation. Lineage tracing in PDAC showed that the vast majority of CAFs were labeled with Tomato expression, suggesting their splanchnic origin. Furthermore, certain splanchnic gene expression signatures persisted in subsets of CAFs in both the PDAC mouse model and human patient samples. Deletion of one of the splanchnic genes, Gata6, in CAFs resulted in increased tumor burden in the pancreas, suggesting a tumor-restraining role of Gata6 in CAFs. In summary, we found that the pancreatic epithelium and bone marrow contributes to a minimal proportion of CAFs in PDAC. Meanwhile, pancreatic TRFs are derived from the splanchnic mesenchyme during fetal development and they expand to contribute to the vast majority of CAFs in PDAC. Moreover, the persistence of splanchnic signature defines subtypes of CAFs, with a potential tumor-suppressing function. This study provides genetic approaches to robustly target CAFs in vivo, and novel insights into CAF origin, heterogeneity and function in PDAC. Citation Format: Lu Han, Yongxia Wu, Kun Fang, Sean Sweeney, Ulyss Roesner, Melodie Parrish, Khushbu Patel, Tom Walter, Julia Piermattei, Anthony Trimboli, Julia Lefler, Cynthia Timmers, Xue-Zhong Yu, Victor Jin, Michael Zimmermann, Angela Mathison, Raul Urrutia, Michael Ostrowski, Gustavo Leone. The splanchnic mesenchyme is the main tissue origin of fibroblasts in the pancreas during homeostasis and tumorigenesis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 5847.

Published

2023

4. Abstract 3645: The splanchnic mesenchyme is the main tissue origin of fibroblasts in the pancreas during homeostasis and tumorigenesis

Author

Lu Han, Yongxia Wu, Melodie Parrish, Khushbu Patel, Tony Trimboli, Julia Lefler, Xuezhong Yu, Michael Zimmermann, Angela Mathison, Raul Urrutia, Michael Ostrowski, and Gustavo Leone

Subjects

Cancer Research, Oncology

Abstract

In pancreatic ductal adenocarcinoma (PDAC), cancer associated fibroblasts (CAFs) play critical and complex roles in the tumor microenvironment. CAFs are also a major cell type in the desmoplastic stroma in PDAC and may account for half of the entire tumor tissue. Multiple subtypes of CAFs have been suggested, but the tissue origin(s) of CAF subtypes are unknown and genetic tools to robustly target them in vivo are lacking. Here we aimed to examine three potential tissue sources of CAFs: the pancreatic epithelium (through epithelium-to-mesenchyme transition), the bone marrow (through circulation), and the pancreatic tissue resident fibroblasts (TRFs) in the normal pancreas (through proliferation). We utilized a genetically engineered mouse model of PDAC, where Kras and p53 mutations were engineered in the pancreatic epithelium using an Flp-Frt system. To determine whether the pancreatic epithelium gives rise to CAFs, we permanently labeled the pancreatic epithelium with a GFP reporter and traced their cell descendants by GFP expression. Despite robust GFP labeling of the epithelium, GFP expression was rarely identified in CAFs, suggesting little contribution of epithelium to the CAF pool. To determine whether the bone marrow gives rise to CAFs, we transplanted donor bone marrow carrying a ubiquitously expressed GFP reporter allele to GFP-negative recipient mice. We found that only a small portion of pancreatic CAFs were tagged with GFP. Lastly, to determine whether pancreatic TRFs give rise to CAFs, we used an inducible CreER-LoxP system to allow for permanent Tomato labeling in TRFs progenitors, the splanchnic mesenchyme, during mid-gestation. Lineage tracing in PDAC showed that the vast majority of CAFs were labeled with Tomato expression, suggesting their splanchnic origin. Furthermore, certain splanchnic gene expression signatures were persistent in subsets of CAFs in both the PDAC mouse model and human patient samples. In summary, we found that bone marrow contributes to a small portion of CAFs in PDAC, and the pancreatic epithelium contributes even less. Meanwhile, pancreatic TRFs are derived from the splanchnic mesenchyme during fetal development and they expand to contribute to the vast majority of CAFs in PDAC. Moreover, the persistence of splanchnic signature defines subtypes of CAFs. This study provides approaches to robustly target CAFs in vivo, and novel insights into CAF origin and heterogeneity in PDAC. Citation Format: Lu Han, Yongxia Wu, Melodie Parrish, Khushbu Patel, Tony Trimboli, Julia Lefler, Xuezhong Yu, Michael Zimmermann, Angela Mathison, Raul Urrutia, Michael Ostrowski, Gustavo Leone. The splanchnic mesenchyme is the main tissue origin of fibroblasts in the pancreas during homeostasis and tumorigenesis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3645.

Published

2022

5. Pinus ponderosa : A checkered past obscured four species

Author

Ann Willyard, Stephen K. Langer, Hassani H. Karemera, Paula E. Marquardt, Valerie D. Hipkins, Kevin M. Potter, Blake Cooper, Kristen N. Finch, Julia Lefler, Frank W. Telewski, David S. Gernandt, Connor Douglas, Mary F. Mahalovich, Payton Lea, and Austin M. Wofford

Subjects

0106 biological sciences, Paraphyly, Genotype, Plant Science, 010603 evolutionary biology, 01 natural sciences, Intraspecific competition, Gene Frequency, Species Specificity, Phylogenetics, Genetic variation, Genetics, Plastids, Alleles, Phylogeny, Ecology, Evolution, Behavior and Systematics, Principal Component Analysis, Geography, biology, Ecology, fungi, Discriminant Analysis, Genetic Variation, Sequence Analysis, DNA, Pinus, biology.organism_classification, United States, Pinus ponderosa, Phylogeography, Taxon, Haplotypes, Brachyptera, Taxonomy (biology), Microsatellite Repeats, 010606 plant biology & botany

Abstract

Premise of the study Molecular genetic evidence can help delineate taxa in species complexes that lack diagnostic morphological characters. Pinus ponderosa (Pinaceae; subsection Ponderosae) is recognized as a problematic taxon: plastid phylogenies of exemplars were paraphyletic, and mitochondrial phylogeography suggested at least four subdivisions of P. ponderosa. These patterns have not been examined in the context of other Ponderosae species. We hypothesized that putative intraspecific subdivisions might each represent a separate taxon. Methods We genotyped six highly variable plastid simple sequence repeats in 1903 individuals from 88 populations of P. ponderosa and related Ponderosae (P. arizonica, P. engelmannii, and P. jeffreyi). We used multilocus haplotype networks and discriminant analysis of principal components to test clustering of individuals into genetically and geographically meaningful taxonomic units. Key results There are at least four distinct plastid clusters within P. ponderosa that roughly correspond to the geographic distribution of mitochondrial haplotypes. Some geographic regions have intermixed plastid lineages, and some mitochondrial and plastid boundaries do not coincide. Based on relative distances to other species of Ponderosae, these clusters diagnose four distinct taxa. Conclusions Newly revealed geographic boundaries of four distinct taxa (P. benthamiana, P. brachyptera, P. scopulorum, and a narrowed concept of P. ponderosa) do not correspond completely with taxonomies. Further research is needed to understand their morphological and nuclear genetic makeup, but we suggest that resurrecting originally published species names would more appropriately reflect the taxonomy of this checkered classification than their current treatment as varieties of P. ponderosa.

Published

2016