Your search keyword '"Craig A. Jordan"' showing total 7 results

1. A novel type of monocytic leukemia stem cell revealed by the clinical use of venetoclax-based therapy

Author

Shanshan Pei, Austin E Gillen, Ian T Shelton, Brett M Stevens, Maura Gasparetto, Krysta Engel, Sarah Staggs, Yanan Wang, William Showers, Anagha Inguva, Maria L Amaya, Mohammad Minhajuddin, Amanda Winters, Sweta B Patel, Hunter Tolison, Anna Krug, Tracy N Young, Jeffrey Schowinsky, Christine McMahon, Clayton A Smith, Daniel A Pollyea, and Craig T Jordan

Abstract

The BCL-2 inhibitor venetoclax has recently emerged as an important component of acute myeloid leukemia (AML) therapy. Notably, use of this agent has revealed a previously unrecognized form of pathogenesis characterized by monocytic disease progression. We demonstrate that this form of disease arises from a fundamentally different type of leukemia stem cell (LSC), which we designate as monocytic LSC (m-LSC), that is developmentally and clinically distinct from the more well-described primitive LSC (p-LSC). The m-LSC is distinguished by a unique immunophenotype (CD34-, CD4+, CD11b-, CD14-, CD36-), unique transcriptional state, reliance on purine/pyrimidine metabolism, and selective sensitivity to cladribine. Critically, in some instances m-LSC and p-LSC subtypes can co-reside in the same AML patient and simultaneously contribute to overall tumor complexity. Thus, our findings demonstrate that LSC heterogeneity has direct clinical significance and highlights the need to distinguish and target m-LSCs as a means to improve clinical outcomes with venetoclax-based regimens.Statement of SignificanceThese studies identify and characterize a new type of human acute myeloid leukemia stem cell (LSC) that is responsible for monocytic disease progression in acute myeloid leukemia (AML) patients treated with venetoclax-based regimens. Our studies describe the phenotype, molecular properties, and drug sensitivities of this unique LSC subclass.

Published

2022

2. MuVEH and mitoMuVEH improve discovery of genetic variation from single cells

Author

Monica R. Ransom, Krysta L. Engel, Brett M. Stevens, Craig T. Jordan, and Austin E. Gillen

Abstract

Understanding the genetic underpinnings and clonal structure of malignancies at single-cell resolution is critical to accurately predicting drug response and understanding mechanisms of drug resistance and disease evolution in heterogeneous populations of cells. Here, we introduce an accessible, multiplexable, targeted mutation enrichment approach and end-to-end analysis pipeline called MuVEH (Multiplexed Variant Enrichment by Hybridization) that increases the resolution of variant detection in scRNA-seq analysis. When applied specifically to the mitochondrial chromosome (“mitoMuVEH”), this technique can also be used to reconstruct and trace clonal relationships between individual cells. We applied both approaches to two pairs of primary bone marrow specimens from acute myelogenous leukemia (AML) patients collected at diagnosis and after relapse following Venetoclax+Azacitidine (Ven/Aza) therapy. Used together, MuVEH and mitoMuVEH reveal clonal evolution and changing mutational burden in response to treatment at single-cell resolution in these patients. Ultimately, these approaches have the potential to extract additional biological insights from precious patient samples and provide insight into the contributions clonality and genotype have during disease progression.

Published

2022

3. scraps: an end-to-end pipeline for measuring alternative polyadenylation at high resolution using single-cell RNA-seq

Author

Rui Fu, Kent A. Riemondy, Ryan M. Sheridan, Jay R. Hesselberth, Craig T. Jordan, and Austin E. Gillen

Abstract

Alternative cleavage and polyadenylation (APA) contributes to the diversity of mRNA 3′ ends, affecting post-transcriptional regulation by including or excluding cis-regulatory elements in mRNAs, altering their stability and translational efficiency. While APA analysis has been applied broadly in mixed populations of cells, the heterogeneity of APA among single cells has only recently begun to be explored. We developed an approach we termed scraps (Single Cell RNAPolyA Site Discovery), implemented as a user-friendly, scalable, and reproducible end-to-end workflow, to identify polyadenylation sites at near-nucleotide resolution in single cells using 10X Genomics and other TVN-primed single-cell RNA-seq (scRNA-seq) libraries. Our approach, which performs best with long (>100bp) read 1 sequencing and paired alignment to the genome, is both unbiased relative to existing methods that utilize only read 2 and recovers more sites at higher resolution, despite the reduction in read quality observed on most modern DNA sequencers following homopolymer stretches. For libraries sequenced without long read 1, we implement a fallback approach using read 2-only alignments that performs similarly to our optimal approach, but recovers far fewer polyadenylation sites per experiment. scraps also enables assessment of internal priming capture events, which we demonstrate occur commonly but at higher frequency during apoptotic 3′ RNA decay. We also provide an R package, scrapR, that integrates the results of the scaps pipeline with the popular Seruat single-cell analysis package. Refinement and expanded application of these approaches will further clarify the role of APA in single cells, as well as the effects of internal priming on expression measurements in scRNA-seq libraries.

Published

2022

4. Therapeutic resistance in acute myeloid leukemia cells is mediated by a novel ATM/mTOR pathway regulating oxidative phosphorylation

Author

Hae J Park, Mark A Gregory, Vadym Zaberezhnyy, Andrew Goodspeed, Craig T Jordan, Jeffrey S Kieft, and James DeGregori

Subjects

General Immunology and Microbiology, General Neuroscience, TOR Serine-Threonine Kinases, Apoptosis, General Medicine, General Biochemistry, Genetics and Molecular Biology, Oxidative Phosphorylation, Leukemia, Myeloid, Acute, fms-Like Tyrosine Kinase 3, Drug Resistance, Neoplasm, Cell Line, Tumor, hemic and lymphatic diseases, Mutation, Tumor Microenvironment, Humans, Everolimus, Phosphorylation, Protein Kinase Inhibitors

Abstract

While leukemic cells are susceptible to various therapeutic insults, residence in the bone marrow microenvironment typically confers protection from a wide range of drugs. Thus, understanding the unique molecular changes elicited by the marrow is of critical importance towards improving therapeutic outcomes. In the present study, we demonstrate that aberrant activation of oxidative phosphorylation serves to induce therapeutic resistance in FLT3 mutant human AML cells challenged with FLT3 inhibitor drugs. Importantly, our findings show that AML cells are protected from apoptosis following FLT3 inhibition due to marrow-mediated activation of ATM, which in turn up-regulates oxidative phosphorylation via mTOR signaling. mTOR is required for the bone marrow stroma-dependent maintenance of protein translation, with selective polysome enrichment of oxidative phosphorylation transcripts, despite FLT3 inhibition. To investigate the therapeutic significance of this finding, we tested the mTOR inhibitor everolimus in combination with the FLT3 inhibitor quizartinib in primary human AML xenograft models. While marrow resident AML cells were highly resistant to quizartinib alone, the addition of everolimus induced profound reduction in tumor burden and prevented relapse. Taken together, these data provide a novel mechanistic understanding of marrow-based therapeutic resistance, and a promising strategy for improved treatment of FLT3 mutant AML patients.

Published

2022

5. Microvasculature-on-a-Chip: Bridging the interstitial blood-lymph interface via mechanobiological stimuli

Author

Barbara Bachmann, Heinz Redl, Haddadi Sisakht B, Sarah Spitz, Wolfgang Holnthoner, Wanzenboeck Hd, Michael Harasek, Craig T. Jordan, Patrick Schuller, and Peter Ertl

Subjects

Immune system, Lymphatic system, medicine.anatomical_structure, Interstitial space, Chemistry, In vivo, Drug delivery, Cell, medicine, Lymph, Interstitial fluid flow, Cell biology

Abstract

After decades of simply being referred to as the body’s sewage system, the lymphatic system has recently been recognized as a key player in numerous physiological and pathological processes. As an essential site of immune cell interactions, the lymphatic system is a potential target for next-generation drug delivery approaches in treatments for cancer, infections, and inflammatory diseases. However, the lack of cell-based assays capable of recapitulating the required biological complexity combined with unreliable in vivo animal models currently hamper scientific progress in lymph-targeted drug delivery. To gain more in-depth insight into the blood-lymph interface, we established an advanced chip-based microvascular model to study mechanical stimulation’s importance on lymphatic sprout formation. Our microvascular model’s key feature is the co-cultivation of spatially separated 3D blood and lymphatic vessels under controlled, unidirectional interstitial fluid flow while allowing signaling molecule exchange similar to the in vivo situation. We demonstrate that our microphysiological model recreates biomimetic interstitial fluid flow, mimicking the route of fluid in vivo, where shear stress within blood vessels pushes fluid into the interstitial space, which is subsequently transported to the nearby lymphatic capillaries. Results of our cell culture optimization study clearly show an increased vessel sprouting number, length, and morphological characteristics under dynamic cultivation conditions and physiological relevant mechanobiological stimulation. For the first time, a microvascular on-chip system incorporating microcapillaries of both blood and lymphatic origin in vitro recapitulates the interstitial blood-lymph interface.

Published

2021

6. PU.1 enforces quiescence and limits hematopoietic stem cell expansion during inflammatory stress

Author

Zhonghe Ke, James DeGregori, Jason R. Myers, Robert S. Welner, Eric M. Pietras, Rachel L Gessner, Kelly C. Higa, Dirk Loeffler, Craig T. Jordan, Hideaki Nakajima, Beau M Idler, Taylor S. Mills, Jennifer L. Rabe, Giovanny Hernandez, Nouraiz Ahmed, John M. Ashton, Brett M. Stevens, James S. Chavez, Timm Schroeder, and Hyunmin Kim

Subjects

Hematopoietic stem cell, Inflammation, Cell cycle, Biology, medicine.disease_cause, medicine.disease, Cell Cycle Gene, Cell biology, Leukemia, medicine.anatomical_structure, medicine, medicine.symptom, Carcinogenesis, Psychological repression, Homeostasis

Abstract

SummaryLoss of hematopoietic stem cell (HSC) quiescence and resulting clonal expansion are common initiating events in the development of hematological malignancy. Likewise, chronic inflammation related to aging, disease and/or tissue damage is associated with leukemia progression, though its role in oncogenesis is not clearly defined. Here, we show that PU.1-dependent repression of protein synthesis and cell cycle genes in HSC enforces homeostatic protein synthesis levels and HSC quiescence in response to IL-1 stimulation. These genes are constitutively de-repressed in PU.1-deficient HSC, leading to activation of protein synthesis, loss of quiescence and aberrant expansion of HSC. Taken together, our data identify a mechanism whereby HSC regulate their cell cycle activity and pool size in response to chronic inflammatory stress.

Published

2020

7. Clonal and systemic analysis of long-term hematopoiesis in the mouse

Author

Craig T. Jordan and Ihor R. Lemischka

Subjects

Genetic Markers, Time Factors, Cellular differentiation, medicine.medical_treatment, Stem cell factor, Hematopoietic stem cell transplantation, Biology, Models, Biological, Mice, Genetics, medicine, Animals, Mice, Inbred C3H, Cell growth, Hematopoietic Stem Cell Transplantation, Totipotent, Hematopoietic Stem Cells, Clone Cells, Hematopoiesis, Cell biology, Transplantation, Transplantation, Isogeneic, Haematopoiesis, Retroviridae, Radiation Chimera, Female, Stem cell, Developmental Biology

Abstract

We have analyzed the temporal in vivo fate of 142 individual stem cell clones in 63 reconstituted mice. Long-term sequential analyses of the four major peripheral blood lineages, obtained from animals engrafted with genetically marked stem cells, indicate that developmental behavior is primarily a function of time. As such, the first 4-6 months post-engraftment is characterized by frequent fluctuations in stem cell proliferation and differentiation behavior. Gradually, a stable hematopoietic system emerges, dominated by a small number of totipotent clones. We demonstrate that single stem cell clones are sufficient to maintain hematopoiesis over the lifetime of an animal and suggest that mono- or oligoclonality may be a hallmark of long-term reconstituted systems. A model is proposed, wherein lineage-restricted differentiation and dramatic clonal flux are consequences of mechanisms acting on an expanding pool of totipotent cells and are not indicative of intrinsically distinct stem cell classes.

Published

1990