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1. Less-deformable erythrocyte subpopulations biomechanically induce endothelial inflammation in sickle cell disease

Author

Caruso, Christina, Cheng, Xiaopo, Michaud, Marina E., Szafraniec, Hannah M., Thomas, Beena E., Fay, Meredith E., Mannino, Robert G., Zhang, Xiao, Sakurai, Yumiko, Li, Wei, Myers, David R., Joiner, Clinton H., Wood, David K., Bhasin, Manoj, Graham, Michael D., and Lam, Wilbur A.

Abstract

•Less-deformable sickle red cells marginate toward blood vessel walls, leading to altered local wall shear stress and endothelial dysfunction.•Pathological biophysical alterations in sickle RBCs cause endothelial dysfunction independently from vaso-occlusion and adhesion.

Published
2024
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2. JAK-STAT inhibition reduces endothelial prothrombotic activation and leukocyte–endothelial proadhesive interactions

Author

Beckman, Joan D., DaSilva, Angelica, Aronovich, Elena, Nguyen, Aithanh, Nguyen, Julia, Hargis, Geneva, Reynolds, David, Vercellotti, Gregory M., Betts, Brian, and Wood, David K.

Abstract

Vascular activation is characterized by increased proinflammatory, pro thrombotic, and proadhesive signaling. Several chronic and acute conditions, including Bcr-abl-negative myeloproliferative neoplasms (MPNs), graft-vs-host disease, and COVID-19 have been noted to have increased activation of the janus kinase (JAK)-signal transducer and downstream activator of transcription (STAT) pathways. Two notable inhibitors of the JAK-STAT pathway are ruxolitinib (JAK1/2 inhibitor) and fedratinib (JAK2 inhibitor), which are currently used to treat MPN patients. However, in some conditions, it has been noted that JAK inhibitors can increase the risk of thromboembolic complications.

Published
2023
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4. Microfluidic methods to advance mechanistic understanding and translational research in sickle cell disease.

Author

Azul, Melissa, Vital, Eudorah F, Lam, Wilbur A, Wood, David K., and Beckman, Joan D.

Abstract

Sickle cell disease (SCD) is caused by a single point mutation in the β-globin gene of hemoglobin, which produces an altered sickle hemoglobin (HbS). The ability of HbS to polymerize under deoxygenated conditions gives rise to chronic hemolysis, oxidative stress, inflammation, and vaso-occlusion. Herein, we review recent findings using microfluidic technologies that have elucidated mechanisms of oxygen-dependent and -independent induction of HbS polymerization and how these mechanisms elicit the biophysical and inflammatory consequences in SCD pathophysiology. We also discuss how validation and use of microfluidics in SCD provides the opportunity to advance development of numerous therapeutic strategies, including curative gene therapies. [ABSTRACT FROM AUTHOR]

Published
2022
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5. An irradiated marrow niche reveals a small noncollagenous protein mediator of homing, dermatopontin

Author

Kramer, Ashley C., Astuti, Yuliana, Elfstrum, Alexis, Lehrke, Michael J., Tolar, Jakub, Blazar, Bruce R., Blake, Amanda L., Taisto, Mandy E., Furcich, Justin W., Nolan, Erin E., Durose, Wilaiwan W., Webber, Beau R., Geisness, Athena, Wood, David K., and Lund, Troy C.

Abstract

Hematopoietic cell homing after hematopoietic cell transplant (HCT) is governed by several pathways involving marrow niche cells that are evoked after pre-HCT conditioning. To understand the factors that play a role in homing, we performed expression analysis on zebrafish marrow niche cells following conditioning. We determined that the noncollagenous protein extracellular matrix related protein dermatopontin (Dpt) was upregulated sevenfold in response to irradiation. Studies in mice revealed DPT induction with radiation and lipopolysaccharide exposure. Interestingly, we found that coincubation of zebrafish or murine hematopoietic cells with recombinant DPT impedes hematopoietic stem and progenitor cell homing by 50% and 86%, respectively. Similarly, this translated into a 24% reduction in long-term engraftment (vs control; P = .01). We found DPT to interact with VLA-4 and block hematopoietic cell–endothelial cell adhesion and transendothelial migration. Finally, a DPT-knockout mouse displayed a 60% increase in the homing of hematopoietic cells vs wild-type mice (P = .03) with a slight improvement in long-term lin−SCA1+cKIT+-SLAM cell engraftment (twofold; P = .04). These data show that the extracellular matrix–related protein DPT increases with radiation and transiently impedes the transendothelial migration of hematopoietic cells to the marrow.

Published
2021
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6. MetAP2 inhibition modifies hemoglobin S to delay polymerization and improves blood flow in sickle cell disease

Author

Demers, Melanie, Sturtevant, Sarah, Guertin, Kevin R., Gupta, Dipti, Desai, Kunal, Vieira, Benjamin F., Li, Wenjing, Hicks, Alexandra, Ismail, Ayman, Gonçalves, Bronner P., Di Caprio, Giuseppe, Schonbrun, Ethan, Hansen, Scott, Musayev, Faik N., Safo, Martin K., Wood, David K., Higgins, John M., and Light, David R.

Abstract

Sickle cell disease (SCD) is associated with hemolysis, vascular inflammation, and organ damage. Affected patients experience chronic painful vaso-occlusive events requiring hospitalization. Hypoxia-induced polymerization of sickle hemoglobin S (HbS) contributes to sickling of red blood cells (RBCs) and disease pathophysiology. Dilution of HbS with nonsickling hemoglobin or hemoglobin with increased oxygen affinity, such as fetal hemoglobin or HbS bound to aromatic aldehydes, is clinically beneficial in decreasing polymerization. We investigated a novel alternate approach to modify HbS and decrease polymerization by inhibiting methionine aminopeptidase 2 (MetAP2), which cleaves the initiator methionine (iMet) from Val1 of α-globin and βS-globin. Kinetic studies with MetAP2 show that βS-globin is a fivefold better substrate than α-globin. Knockdown of MetAP2 in human umbilical cord blood–derived erythroid progenitor 2 cells shows more extensive modification of α-globin than β-globin, consistent with kinetic data. Treatment of human erythroid cells in vitro or Townes SCD mice in vivo with selective MetAP2 inhibitors extensively modifies both globins with N-terminal iMet and acetylated iMet. HbS modification by MetAP2 inhibition increases oxygen affinity, as measured by decreased oxygen tension at which hemoglobin is 50% saturated. Acetyl-iMet modification on βS-globin delays HbS polymerization under hypoxia. MetAP2 inhibitor–treated Townes mice reach 50% total HbS modification, significantly increasing the affinity of RBCs for oxygen, increasing whole blood single-cell RBC oxygen saturation, and decreasing fractional flow velocity losses in blood rheology under decreased oxygen pressures. Crystal structures of modified HbS variants show stabilization of the nonpolymerizing high O2–affinity R2 state, explaining modified HbS antisickling activity. Further study of MetAP2 inhibition as a potential therapeutic target for SCD is warranted.

Published
2021
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7. MetAP2 inhibition modifies hemoglobin S to delay polymerization and improves blood flow in sickle cell disease

Author

Demers, Melanie, Sturtevant, Sarah, Guertin, Kevin R., Gupta, Dipti, Desai, Kunal, Vieira, Benjamin F., Li, Wenjing, Hicks, Alexandra, Ismail, Ayman, Gonçalves, Bronner P., Di Caprio, Giuseppe, Schonbrun, Ethan, Hansen, Scott, Musayev, Faik N., Safo, Martin K., Wood, David K., Higgins, John M., and Light, David R.

Abstract

Sickle cell disease (SCD) is associated with hemolysis, vascular inflammation, and organ damage. Affected patients experience chronic painful vaso-occlusive events requiring hospitalization. Hypoxia-induced polymerization of sickle hemoglobin S (HbS) contributes to sickling of red blood cells (RBCs) and disease pathophysiology. Dilution of HbS with nonsickling hemoglobin or hemoglobin with increased oxygen affinity, such as fetal hemoglobin or HbS bound to aromatic aldehydes, is clinically beneficial in decreasing polymerization. We investigated a novel alternate approach to modify HbS and decrease polymerization by inhibiting methionine aminopeptidase 2 (MetAP2), which cleaves the initiator methionine (iMet) from Val1 of α-globin and βS-globin. Kinetic studies with MetAP2 show that βS-globin is a fivefold better substrate than α-globin. Knockdown of MetAP2 in human umbilical cord blood–derived erythroid progenitor 2 cells shows more extensive modification of α-globin than β-globin, consistent with kinetic data. Treatment of human erythroid cells in vitro or Townes SCD mice in vivo with selective MetAP2 inhibitors extensively modifies both globins with N-terminal iMet and acetylated iMet. HbS modification by MetAP2 inhibition increases oxygen affinity, as measured by decreased oxygen tension at which hemoglobin is 50% saturated. Acetyl-iMet modification on βS-globin delays HbS polymerization under hypoxia. MetAP2 inhibitor–treated Townes mice reach 50% total HbS modification, significantly increasing the affinity of RBCs for oxygen, increasing whole blood single-cell RBC oxygen saturation, and decreasing fractional flow velocity losses in blood rheology under decreased oxygen pressures. Crystal structures of modified HbS variants show stabilization of the nonpolymerizing high O2–affinity R2 state, explaining modified HbS antisickling activity. Further study of MetAP2 inhibition as a potential therapeutic target for SCD is warranted.

Published
2021
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8. An Experimental-Computational Approach to Quantify Blood Rheology in Sickle Cell Disease

Author

Bazzi, Marisa S., Valdez, José M., Barocas, Victor H., and Wood, David K.

Abstract

In sickle cell disease, aberrant blood flow due to oxygen-dependent changes in red cell biomechanics is a key driver of pathology. Most studies to date have focused on the potential role of altered red cell deformability and blood rheology in precipitating vaso-occlusive crises. Numerous studies, however, have shown that sickle blood flow is affected even at high oxygen tensions, suggesting a potentially systemic role for altered blood flow in driving pathologies, including endothelial dysfunction, ischemia, and stroke. In this study, we applied a combined experimental-computation approach that leveraged an experimental platform that quantifies sickle blood velocity fields under a range of oxygen tensions and shear rates. We computationally fitted a continuum model to our experimental data to generate physics-based parameters that capture patient-specific rheological alterations. Our results suggest that sickle blood flow is altered systemically, from the arterial to the venous circulation. We also demonstrated the application of this approach as a tool to design patient-specific transfusion regimens. Finally, we demonstrated that patient-specific rheological parameters can be combined with patient-derived vascular models to identify patients who are at higher risk for cerebrovascular complications such as aneurysm and stroke. Overall, this study highlights that sickle blood flow is altered systemically, which can drive numerous pathologies, and this study demonstrates the potential utility of an experimentally parameterized continuum model as a predictive tool for patient-specific care.

Published
2020
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9. SEMA4C is a novel target to limit osteosarcoma growth, progression, and metastasis

Author

Smeester, Branden A., Slipek, Nicholas J., Pomeroy, Emily J., Bomberger, Heather E., Shamsan, Ghaidan A., Peterson, Joseph J., Crosby, Margaret R., Draper, Garrett M., Becklin, Kelsie L., Rahrmann, Eric P., McCarthy, James B., Odde, David J., Wood, David K., Largaespada, David A., and Moriarity, Branden S.

Abstract

Semaphorins, specifically type IV, are important regulators of axonal guidance and have been increasingly implicated in poor prognoses in a number of different solid cancers. In conjunction with their cognate PLXNB family receptors, type IV members have been increasingly shown to mediate oncogenic functions necessary for tumor development and malignant spread. In this study, we investigated the role of semaphorin 4C (SEMA4C) in osteosarcoma growth, progression, and metastasis. We investigated the expression and localization of SEMA4C in primary osteosarcoma patient tissues and its tumorigenic functions in these malignancies. We demonstrate that overexpression of SEMA4C promotes properties of cellular transformation, while RNAi knockdown of SEMA4C promotes adhesion and reduces cellular proliferation, colony formation, migration, wound healing, tumor growth, and lung metastasis. These phenotypic changes were accompanied by reductions in activated AKT signaling, G1 cell cycle delay, and decreases in expression of mesenchymal marker genes SNAI1, SNAI2, and TWIST1. Lastly, monoclonal antibody blockade of SEMA4C in vitro mirrored that of the genetic studies. Together, our results indicate a multi-dimensional oncogenic role for SEMA4C in metastatic osteosarcoma and more importantly that SEMA4C has actionable clinical potential.

Published
2020
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10. A High-Throughput Workflow to Study Remodeling of Extracellular Matrix-Based Microtissues

Author

Crampton, Alexandra L., Cummins, Katherine A., and Wood, David K.

Abstract

Changes to the cellular microenvironment are an integral characteristic of numerous pathologies, including cancer, fibrosis, and autoimmune disease. Current in vitromethodologies available to study three-dimensional tissue remodeling are ill-suited for high-throughput studies as they are not scalable for large-scale experiments. Combining droplet microfluidics and patterned low-adhesion culture surfaces, we have engineered a workflow to incorporate cell–extracellular matrix (ECM) interactions in a versatile and high-throughput platform that is compatible with existing high-throughput liquid handling systems, enables long-term experiments (>1 month), and is well suited for traditional and novel biological measurements. With our platform, we demonstrate the feasibility of high-throughput ECM remodeling studies with collagen microtissues as one application of a tissue-level function. In this study, we use our workflow to examine ECM remodeling at the tissue, cell, and subcellular levels, leveraging assays ranging from immunohistochemistry and live cell imaging, to proliferation and contraction assays. With our unique culture system, we can track individual constructs over time and evaluate remodeling on several scales for large populations. Finally, we demonstrate the ability to cryopreserve our microtissues while retaining high viability and cell function, an invaluable method that could allow for dissemination and freezing of microtissues after mass production. Using these methods, our ECM-based system becomes a viable platform for modeling diseases characterized by tissue reorganization as well as a scalable method to conduct in vitrocell-based assays for drug screening and high-throughput biological discovery.Impact StatementThe described microtissue–microwell workflow is uniquely suited for high-throughput study of extracellular matrix (ECM) remodeling at the molecular, cellular, and tissue levels and demonstrates possibilities of studying progressive, heterogeneous diseases in a way that is meaningful for drug discovery and development. We outline several assays that can be utilized in studying tissue-level diseases and functions that involve cell–ECM interactions and ECM remodeling (e.g., cancer, fibrosis, wound healing) in pursuit of an improved three-dimensional cell culturing system. Finally, we demonstrate the ability to cryopreserve cells encapsulated in microtissue constructs while remaining highly viable, proliferative, and retaining cell functions that are involved in ECM remodeling.

Published
2019
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12. Extracellular fluid tonicity impacts sickle red blood cell deformability and adhesion

Author

Carden, Marcus A., Fay, Meredith E., Lu, Xinran, Mannino, Robert G., Sakurai, Yumiko, Ciciliano, Jordan C., Hansen, Caroline E., Chonat, Satheesh, Joiner, Clinton H., Wood, David K., and Lam, Wilbur A.

Abstract

Abnormal sickle red blood cell (sRBC) biomechanics, including pathological deformability and adhesion, correlate with clinical severity in sickle cell disease (SCD). Clinical intravenous fluids (IVFs) of various tonicities are often used during treatment of vaso-occlusive pain episodes (VOE), the major cause of morbidity in SCD. However, evidence-based guidelines are lacking, and there is no consensus regarding which IVFs to use during VOE. Further, it is unknown how altering extracellular fluid tonicity with IVFs affects sRBC biomechanics in the microcirculation, where vaso-occlusion takes place. Here, we report how altering extracellular fluid tonicity with admixtures of clinical IVFs affects sRBC biomechanical properties by leveraging novel in vitro microfluidic models of the microcirculation, including 1 capable of deoxygenating the sRBC environment to monitor changes in microchannel occlusion risk and an “endothelialized” microvascular model that measures alterations in sRBC/endothelium adhesion under postcapillary venular conditions. Admixtures with higher tonicities (sodium = 141 mEq/L) affected sRBC biomechanics by decreasing sRBC deformability, increasing sRBC occlusion under normoxic and hypoxic conditions, and increasing sRBC adhesion in our microfluidic human microvasculature models. Admixtures with excessive hypotonicity (sodium = 103 mEq/L), in contrast, decreased sRBC adhesion, but overswelling prolonged sRBC transit times in capillary-sized microchannels. Admixtures with intermediate tonicities (sodium = 111-122 mEq/L) resulted in optimal changes in sRBC biomechanics, thereby reducing the risk for vaso-occlusion in our models. These results have significant translational implications for patients with SCD and warrant a large-scale prospective clinical study addressing optimal IVF management during VOE in SCD.

Published
2017
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13. Extracellular fluid tonicity impacts sickle red blood cell deformability and adhesion

Author

Carden, Marcus A., Fay, Meredith E., Lu, Xinran, Mannino, Robert G., Sakurai, Yumiko, Ciciliano, Jordan C., Hansen, Caroline E., Chonat, Satheesh, Joiner, Clinton H., Wood, David K., and Lam, Wilbur A.

Abstract

Abnormal sickle red blood cell (sRBC) biomechanics, including pathological deformability and adhesion, correlate with clinical severity in sickle cell disease (SCD). Clinical intravenous fluids (IVFs) of various tonicities are often used during treatment of vaso-occlusive pain episodes (VOE), the major cause of morbidity in SCD. However, evidence-based guidelines are lacking, and there is no consensus regarding which IVFs to use during VOE. Further, it is unknown how altering extracellular fluid tonicity with IVFs affects sRBC biomechanics in the microcirculation, where vaso-occlusion takes place. Here, we report how altering extracellular fluid tonicity with admixtures of clinical IVFs affects sRBC biomechanical properties by leveraging novel in vitro microfluidic models of the microcirculation, including 1 capable of deoxygenating the sRBC environment to monitor changes in microchannel occlusion risk and an “endothelialized” microvascular model that measures alterations in sRBC/endothelium adhesion under postcapillary venular conditions. Admixtures with higher tonicities (sodium = 141 mEq/L) affected sRBC biomechanics by decreasing sRBC deformability, increasing sRBC occlusion under normoxic and hypoxic conditions, and increasing sRBC adhesion in our microfluidic human microvasculature models. Admixtures with excessive hypotonicity (sodium = 103 mEq/L), in contrast, decreased sRBC adhesion, but overswelling prolonged sRBC transit times in capillary-sized microchannels. Admixtures with intermediate tonicities (sodium = 111-122 mEq/L) resulted in optimal changes in sRBC biomechanics, thereby reducing the risk for vaso-occlusion in our models. These results have significant translational implications for patients with SCD and warrant a large-scale prospective clinical study addressing optimal IVF management during VOE in SCD.

Published
2017
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14. Deoxygenation Reduces Sickle Cell Blood Flow at Arterial Oxygen Tension

Author

Lu, Xinran, Wood, David K., and Higgins, John M.

Abstract

The majority of morbidity and mortality in sickle cell disease is caused by vaso-occlusion: circulatory obstruction leading to tissue ischemia and infarction. The consequences of vaso-occlusion are seen clinically throughout the vascular tree, from the relatively high-oxygen and high-velocity cerebral arteries to the relatively low-oxygen and low-velocity postcapillary venules. Prevailing models of vaso-occlusion propose mechanisms that are relevant only to regions of low oxygen and low velocity, leaving a wide gap in our understanding of the most important pathologic process in sickle cell disease. Progress toward understanding vaso-occlusion is further challenged by the complexity of the multiple processes thought to be involved, including, but not limited to 1) deoxygenation-dependent hemoglobin polymerization leading to impaired rheology, 2) endothelial and leukocyte activation, and 3) altered cellular adhesion. Here, we chose to focus exclusively on deoxygenation-dependent rheologic processes in an effort to quantify their contribution independent of the other processes that are likely involved in vivo. We take advantage of an experimental system that, to our knowledge, uniquely enables the study of pressure-driven blood flow in physiologic-sized tubes at physiologic hematocrit under controlled oxygenation conditions, while excluding the effects of endothelium, leukocyte activation, adhesion, inflammation, and coagulation. We find that deoxygenation-dependent rheologic processes are sufficient to increase apparent viscosity significantly, slowing blood flow velocity at arterial oxygen tension even without additional contributions from inflammation, adhesion, and endothelial and leukocyte activation. We quantify the changes in apparent viscosity and define a set of functional regimes of sickle cell blood flow personalized for each patient that may be important in further dissecting mechanisms of in vivo vaso-occlusion as well as in assessing risk of patient complications, response to transfusion, and the optimization of experimental therapies in development.

Published
2016
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15. Rapid generation of collagen-based microtissues to study cell–matrix interactions

Author

Brett, Marie-Elena, Crampton, Alexandra L., and Wood, David K.

Abstract

The objective of this study was to create a method for studying cell–matrix interactions in a physiologically relevant 3D protein-based tissue construct that could be scaled up to perform large-scale screens, study cell–matrix interactions on a population basis, or be remodeled by cells to build larger tissues. We have developed an easy-to-use method to miniaturize protein-based tissue constructs that maintains the 3D in vitroenvironment, while alleviating several obstacles associated with larger avascular tissue constructs. In this study, we demonstrate that (i) cells can interact with the 3D environment both while encapsulated or while interacting only with the surface of the microtissues, (ii) encapsulated cells are highly viable and, for the first time, (iii) microtissues on this size scale (~200 μm) can be used to quantify cell contractility. This versatile platform should facilitate large-scale screens in 3D in vitroculture conditions for drug development and high throughput mechanistic biology.

Published
2016
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16. Nanoparticles That Sense Thrombin Activity As Synthetic Urinary Biomarkers of Thrombosis

Author

Lin, Kevin Y., Kwong, Gabriel A., Warren, Andrew D., Wood, David K., and Bhatia, Sangeeta N.

Abstract

Thrombin is a serine protease and regulator of hemostasis that plays a critical role in the formation of obstructive blood clots, or thrombosis, that is a life-threatening condition associated with numerous diseases such as atherosclerosis and stroke. To detect thrombi in living animals, we design and conjugate thrombin-sensitive peptide substrates to the surface of nanoparticles. Following intravenous infusion, these “synthetic biomarkers” survey the host vasculature for coagulation and, in response to substrate cleavage by thrombin, release ligand-encoded reporters into the host urine. To detect the urinary reporters, we develop a companion 96-well immunoassay that utilizes antibodies to bind specifically to the ligands, thus capturing the reporters for quantification. Using a thromboplastin-induced mouse model of pulmonary embolism, we show that urinary biomarker levels differentiate between healthy and thrombotic states and correlate closely with the aggregate burden of clots formed in the lungs. Our results demonstrate that synthetic biomarkers can be engineered to sense vascular diseases remotely from the urine and may allow applications in point-of-care diagnostics.

Published
2013
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17. Single-cell microarray enables high-throughput evaluation of DNA double-strand breaks and DNA repair inhibitors

Author

Weingeist, David M., Ge, Jing, Wood, David K., Mutamba, James T., Huang, Qiuying, Rowland, Elizabeth A., Yaffe, Michael B., Floyd, Scott, and Engelward, Bevin P.

Abstract

A key modality of non-surgical cancer management is DNA damaging therapy that causes DNA double-strand breaks that are preferentially toxic to rapidly dividing cancer cells. Double-strand break repair capacity is recognized as an important mechanism in drug resistance and is therefore a potential target for adjuvant chemotherapy. Additionally, spontaneous and environmentally induced DSBs are known to promote cancer, making DSB evaluation important as a tool in epidemiology, clinical evaluation and in the development of novel pharmaceuticals. Currently available assays to detect double-strand breaks are limited in throughput and specificity and offer minimal information concerning the kinetics of repair. Here, we present the CometChip, a 96-well platform that enables assessment of double-strand break levels and repair capacity of multiple cell types and conditions in parallel and integrates with standard high-throughput screening and analysis technologies. We demonstrate the ability to detect multiple genetic deficiencies in double-strand break repair and evaluate a set of clinically relevant chemical inhibitors of one of the major double-strand break repair pathways, non-homologous end-joining. While other high-throughput repair assays measure residual damage or indirect markers of damage, the CometChip detects physical double-strand breaks, providing direct measurement of damage induction and repair capacity, which may be useful in developing and implementing treatment strategies with reduced side effects.

Published
2013
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20. Robust Pre-Clinical Results and Large-Scale Manufacturing Process for Edit-301: An Autologous Cell Therapy for the Potential Treatment of SCD

Author

De Dreuzy, Edouard, Heath, Jack, Sousa, Patricia, Janoudi, Tusneem, An, Harry, Hansen, Scott, Wood, David K., Albright, Charles F, Teixeira, Sandra, Monesmith, Tamara, Zhang, Kate, and Chang, Kai-Hsin

Abstract

Sickle cell disease (SCD) is an inherited blood disorder affecting approximately 100,000 individuals in the United States. As fetal hemoglobin (HbF) has been shown to be protective against clinical manifestation of SCD, we are developing EDIT-301, an autologous cell therapy comprising CD34+ cells genetically modified using a Cas12a ribonucleoprotein (RNP) to promote HbF expression to treat SCD.

Published
2020
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21. Fluorescence Lifetime Measurement of Prefibrillar Sickle Hemoglobin Oligomers as a Platform for Drug Discovery in Sickle Cell Disease

Author

Vunnam, Nagamani, Hansen, Scott, Been, MaryJane Olivia, Lo, Chih Hung, Pandey, Anil K., Paulsen, Carolyn N., Rohde, John A., Thomas, David D., Sachs, Jonathan N., and Wood, David K.

Abstract

The molecular origin of sickle cell disease (SCD) has been known since 1949, but treatments remain limited. We present the first high-throughput screening (HTS) platform for discovering small molecules that directly inhibit sickle hemoglobin (HbS) oligomerization and improve blood flow, potentially overcoming a long-standing bottleneck in SCD drug discovery. We show that at concentrations far below the threshold for nucleation and rapid polymerization, deoxygenated HbS forms small assemblies of multiple α2β2tetramers. Our HTS platform leverages high-sensitivity fluorescence lifetime measurements that monitor these temporally stable prefibrillar HbS oligomers. We show that this approach is sensitive to compounds that inhibit HbS polymerization with or without modulating hemoglobin oxygen binding affinity. We also report the results of a pilot small-molecule screen in which we discovered and validated several novel inhibitors of HbS oligomerization.

Published
2022
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22. Visualizing Sickle Cell Disease Whole Blood Flow and Viscosity through Modifications to Hemoglobin Levels from a Simple Blood Transfusion

Author

Fibben, Kirby S., Lam, Wilbur A., Zhang, Dan Y., Kemp, Melissa L., Wood, David K., and Eiffrig, Elizabeth

Abstract

Red cell transfusions are an effective part of a clinical care regiment in the treatment of chronic sickle cell disease; however, the understanding of the target hemoglobin levels has not been investigated past the standard hematocrit/hemoglobin (HgB) of 10 g/dL. A simple transfusion of packed red cells can be a beneficial clinical treatment of acute pain crisis or even stroke. Along with other transfusion-based complications, when performing a simple transfusion, the changes in blood velocity as a result of increased blood viscosity from the additional red cells can lead to complications of their own. Because of this, clinical treatment has hesitated to transfuse sickle patients above a HgB of 10 g/dL.

Published
2021
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23. Model-Predicted Clinical Factors Impacting Patient-Specific Response of Sickle Cells to Voxelotor in a Microfluidic Platform

Author

Zhang, Dan Y., Azul, Melissa, Lam, Wilbur A., Wood, David K., and Kemp, Melissa L.

Abstract

Background:Sickle cell disease (SCD) is a group of genetic disorders in which sickle hemoglobin polymerizes under deoxygenation, altering red blood cell (RBC) morphology and behavior. The properties of sickle RBCs contribute to increased viscosity of blood and occurrence of vaso-occlusions, a major aspect of SCD pathophysiology. Voxelotor is a novel FDA-approved treatment for SCD which modulates hemoglobin O 2affinity, and while its known mechanism inhibits sickle polymerization, the impact on other aspects of SCD pathophysiology remain unknown. Thus, despite the new treatment option, highly variable clinical manifestation continues to be a hallmark of sickle cell and there is consequently a need to optimize the use of current therapies based on patient-specific factors. In this work, we leverage datasets generated from a unique microfluidic assay that measures blood flow behavior under varying oxygen tension in conjunction with novel statistical approaches to model and assess sources of variability in sickle blood flow response to voxelotor.

Published
2021
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27. Effects of BCL11A Shmir-Induced Post-Transcriptional Silencing on Hemoglobin Polymer Inhibition in Single Red Blood Cells at Physiologic Oxygen Tension

Author

De Souza, Daniel C., Esrick, Erica B., Hebert, Nicolas, Di Caprio, Giuseppe, Ciuculescu, Marioara, Morris, Emily, Armant, Myriam, Gonçalves, Bronner P., Schonbrun, Ethan, Brendel, Christian, Wood, David K., Bartolucci, Pablo, Williams, David A., and Higgins, John M.

Abstract

Esrick: bluebird bio: Consultancy. Bartolucci: INNOVHEM: Other: Co-founder; F. Hoffmann-La Roche Ltd: Consultancy; Bluebird: Consultancy, Research Funding; Novartis: Consultancy, Membership on an entity's Board of Directors or advisory committees, Other: Lecture fees, Steering committee, Research Funding; GBT: Consultancy; Emmaus: Consultancy; Hemanext: Consultancy; AGIOS: Consultancy; Jazz Pharma: Other: Lecture fees; Fabre Foundation: Research Funding; Addmedica: Consultancy, Other: Lecture fees, Research Funding. Williams: Emerging Therapy Solutions: Membership on an entity's Board of Directors or advisory committees, Other: Chief Scientific Chair; Geneception: Membership on an entity's Board of Directors or advisory committees, Other: Scientific Advisory Board; BioMarin: Membership on an entity's Board of Directors or advisory committees, Other: Insertion Site Advisory Board; Novartis: Membership on an entity's Board of Directors or advisory committees, Other: Steering Committee, Novartis ETB115E2201 (eltrombopag in aplastic anemia). Advisory fees donated to NAPAAC.; Alerion Biosciences: Other: Co-founder (now licensed to Avro Bio, potential for future milestones/royalties); Beam Therapeutics: Membership on an entity's Board of Directors or advisory committees, Other: Scientific Advisory Board; Orchard Therapeutics: Membership on an entity's Board of Directors or advisory committees, Other: Membership on a safety advisory board (SAB): SAB position ended 05/20/2021. Co-founder , Patents & Royalties: Potential for future royalty/milestone income, X-SCID. Provided GMP vector for clinical trial, Research Funding; bluebird bio: Membership on an entity's Board of Directors or advisory committees, Other: Insertion Site Analysis Advisory Board, Patents & Royalties: BCH licensed certain IP relevant to hemoglobinopathies to bluebird bio. The current license includes the potential for future royalty/milestone income. Bluebird has indicated they will not pursue this as a clinical program and BCH is negotiating return of, Research Funding. Higgins: Danaher Diagnostics: Consultancy; Sebia, Inc.: Honoraria.

Published
2021
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28. An irradiated marrow niche reveals a small non-collagenousprotein mediator of homing, dermatopontin

Author

Kramer, Ashley C, Astuti, Yuliana, Elfstrum, Alexis, Lehrke, Michael J., Tolar, Jakub, Blazar, Bruce R., Blake, Amanda L., Taisto, Mandy E., Furcich, Justin W., Nolan, Erin E., Durose, Wilaiwan W, Webber, Beau R., Geisness, Athena, Wood, David K., and Lund, Troy C.

Abstract

Hematopoietic cell homing after hematopoietic cell transplant (HCT) is governed by several pathways involving marrow niche cells that are evoked after pre-HCT conditioning.To understand thefactors that play a role in homing, we performed expression analysis on the zebrafish marrow niche cellsfollowing conditioning. We determined that thenon-collagenous protein extracellular matrix related protein dermatopontin (Dpt)was upregulated seven-fold in response to irradiation.Studies in mice revealed DPT induction both with radiation and lipopolysaccharide exposure.Interestingly, we found that co-incubation of zebrafish or murine hematopoietic cells with rDPT impedes hematopoietic stem and progenitor cell homingby50%and86%, respectively. Similarly,this translated into a 24% reduction inlong term engraftment(versus control, p = 0.01). We found DPT to interact with VLA-4 and block hematopoietic – endothelial cell adhesion and transendothelial migration.Finally, a DPT knockout mouse displayed a 60% increase in homing of hematopoietic cells versus wildtype (p = 0.03) with slight improvement inlong-termLSK-SLAM engraftment (2-fold, p = 0.04). These data show that the extracellular matrix (ECM)-related proteinDPT increases with radiationand transiently impedes the transendothelialmigration of hematopoietic cells to the marrow.

Published
2021
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30. Validation of BCL11A As Therapeutic Target in Sickle Cell Disease: Results from the Adult Cohort of a Pilot/Feasibility Gene Therapy Trial Inducing Sustained Expression of Fetal Hemoglobin Using Post-Transcriptional Gene Silencing

Author

Esrick, Erica B., Achebe, Maureen, Armant, Myriam, Bartolucci, Pablo, Ciuculescu, Marioara Felicia, Daley, Heather, Dansereau, Colleen, Di Caprio, Giuseppe, Goncalves, Bronner, Hebert, Nicolas, Heeney, Matthew M, Higgins, John M., Lehmann, Leslie E., Manis, John P, Negre, Olivier, Nikiforow, Sarah, Schonbrun, Ethan, Wood, David K., and Williams, David A.

Abstract

Achebe: Global Blood Therapeutics: Membership on an entity's Board of Directors or advisory committees; Pharmacosmos: Membership on an entity's Board of Directors or advisory committees; Fulcrum Therapeutics: Membership on an entity's Board of Directors or advisory committees; Bluebird Bio: Membership on an entity's Board of Directors or advisory committees. Bartolucci:Novartis: Membership on an entity's Board of Directors or advisory committees; AddMedica: Honoraria, Membership on an entity's Board of Directors or advisory committees; Roche: Membership on an entity's Board of Directors or advisory committees; HEMANEXT: Membership on an entity's Board of Directors or advisory committees; Global Blood Therapeutics: Membership on an entity's Board of Directors or advisory committees; Agios: Membership on an entity's Board of Directors or advisory committees. Heeney:AstraZeneca: Research Funding; Micelle Biopharma: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; Pfizer: Research Funding; Novartis: Consultancy, Research Funding; Ironwood / Cyclerion: Research Funding; Vertex / Crisper Therapeutics: Other: Data Safety Monitoring Board. Higgins:Sanofi: Consultancy, Research Funding. Nikiforow:Kite/Gilead: Honoraria; Novartis: Honoraria; NKarta: Honoraria. Wood:Sanofi: Consultancy, Research Funding. Williams:Alerion Biosciences: Other: Co-founder; Novartis: Membership on an entity's Board of Directors or advisory committees; Orchard Therapeutics: Membership on an entity's Board of Directors or advisory committees, Other: Co-founder, Patents & Royalties: Potential for future royalty/milestone income, X-SCID., Research Funding; bluebird bio: Patents & Royalties: Licensed certain IP relevant to hemoglobinopathies to bluebird bio. Received payment in the past bluebird bio through a BCH institutional licensing agreement and there is a potential for future royalty/milestone income from this agreement., Research Funding.

Published
2019
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31. Validation of BCL11A As Therapeutic Target in Sickle Cell Disease: Results from the Adult Cohort of a Pilot/Feasibility Gene Therapy Trial Inducing Sustained Expression of Fetal Hemoglobin Using Post-Transcriptional Gene Silencing

Author

Esrick, Erica B., Achebe, Maureen, Armant, Myriam, Bartolucci, Pablo, Ciuculescu, Marioara Felicia, Daley, Heather, Dansereau, Colleen, Di Caprio, Giuseppe, Goncalves, Bronner, Hebert, Nicolas, Heeney, Matthew M, Higgins, John M., Lehmann, Leslie E., Manis, John P, Negre, Olivier, Nikiforow, Sarah, Schonbrun, Ethan, Wood, David K., and Williams, David A.

Abstract

BCL11A regulates the fetal-adult hemoglobin switch by repressing expression at the gamma (γ)-globin locus (Sankaran et al., Science, 2008), and thus it represents an appealing therapeutic target for sickle cell disease (SCD). BCH-BB694 is a lentiviral vector (LVV) encoding a shRNA targeting BCL11A embedded in a microRNA scaffold (shmiR) allowing erythroid-specific knockdown to induce γ-globin expression and concomitantly and coordinately repress β-sickle globin expression (Brendel et al. JCI, 2016). In a pilot and feasibility gene therapy study we are evaluating the safety of infusion of BCH-BB694-transduced autologous CD34+ cells in patients with severe SCD. The study is an IND enabled and IRB approved open label, non-randomized, single center trial (NCT 03282656). We report here data from the full adult cohort which has completed enrollment with > 6 months of follow up in all patients. The adult cohort included three patients >/= 18 years old. Autologous CD34+ cells were collected by plerixafor mobilization and then transduced ex vivowith the BCH-BB694 shmiR lentiviral vector. Cell doses and vector copy number (VCN) are shown in the Table. After testing and release, gene modified cells were infused into subjects who had received busulfan conditioning. There were no Grade 3 or 4 AEs associated with mobilization, collection or infusion. All three adults (age 21-26 years old) demonstrated neutrophil engraftment on day +22 with adverse events consistent with busulfan conditioning. These patients are now 7, 9, and 17 months post infusion. One subject resumed red cell transfusions at 3 months due to pre-existing moyamoya using a pre-defined conservative trigger value of 40% sickle Hb in whole blood and will be detailed separately. There have been no adverse events related to the gene therapy product. VCN has been stable in bone marrow (BM) and peripheral blood (PB) in all cell lineages during the length of the study, with the latest time point studied at 15 months (BCL002) and ranged from 0.45-2.85 copies per cell in erythroid progenitor cells. BCL11A protein levels evaluated by immunoblot in subject BCL002 at 30 days (PB) and 6 months (BM) post-infusion showed highly effective and selective knockdown of BCL11A in erythroid progenitors with no reduction in BCL11A expression in B lymphoid cells. The number of HbF-containing cells (F cells) was assessed by flow cytometry and the kinetics of F cell production was remarkably similar in all subjects. The two untransfused subjects (BCL002 and BCL004) produced 70% F-cells in PB at 3 and 5 months, which has remained stable until the last point assayed (15 months and 7.5 months, respectively) (table). Calculated average HbF per F cell was >10pg in all subjects (table) and quantitative single cell HbF flow analysis showed the majority of F cells had >4pg F/cell, a level that is believed to prevent sickling under physiological oxygen saturation (Rakotoson et al., ASH2017). In both untransfused subjects, total Hb remained stable with evidence of reduced hemolysis by reticulocyte count (slightly elevated) and LDH (normal in one subject, slightly elevated in the other). At the 3-month timepoint before re-starting transfusions, the subject with moyamoya (BCL003) had a pre-transfusion Hb of 11 g/dL with 76% of non-transfused cells containing on average 17pg F/F cell. For all subjects, we estimated the fraction of RBCs containing significant Hb sickle polymers and the amount of polymer in each sickled RBC at physiologic oxygen tension (where 50% of monomeric hemoglobin was oxygen saturated, or the P50) (Di Caprio et al. PNAS 2019, in press). The results for all 3 subjects in this adult cohort showed fewer RBCs with significant Hb polymer than two hydroxyurea-responsive treated comparators and significantly less Hb polymer per sickled RBC than a third highly responsive hydroxyurea-treated comparator. In conclusion, these data demonstrate successful and sustained engraftment in three adult patients treated with LVV-delivered shmiR technology targeting BCL11A. Early results suggest an acceptable safety profile, validation of BCL11A as effective target for HbF induction in humans with high numbers of F cells in circulation containing high levels of HbF per F cell, and mitigation of cellular pathology of SCD.

Published
2019
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32. MetAP2 Inhibition Modifies Hemoglobin S (HbS) to Delay Polymerization and Improve Blood Flow in Sickle Cell Disease

Author

Demers, Melanie, Sturtevant, Sarah, Guertin, Kevin, Gupta, Dipti, Desai, Kunal, Vieira, Benjamin, Hicks, Alexandra, Ismail, Ayman, Nakamura, Yukio, Goncalves, Bronner, Di Caprio, Giuseppe, Schonbrun, Ethan, Hansen, Scott, Safo, Martin K., Wood, David K., Higgins, John M., and Light, David R.

Abstract

Demers: Sanofi: Employment. Sturtevant:Sanofi: Employment. Guertin:Sanofi: Employment. Gupta:Sanofi: Employment. Desai:Sanofi: Employment. Vieira:Sanofi: Employment. Hicks:Sanofi: Employment. Ismail:Sanofi: Employment. Safo:Sanofi: Consultancy, Research Funding; Virginia Commonwealth University: Patents & Royalties. Wood:Sanofi: Consultancy, Research Funding. Higgins:Sanofi: Consultancy, Research Funding. Light:Sanofi: Employment.

Published
2019
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33. MetAP2 Inhibition Modifies Hemoglobin S (HbS) to Delay Polymerization and Improve Blood Flow in Sickle Cell Disease

Author

Demers, Melanie, Sturtevant, Sarah, Guertin, Kevin, Gupta, Dipti, Desai, Kunal, Vieira, Benjamin, Hicks, Alexandra, Ismail, Ayman, Nakamura, Yukio, Goncalves, Bronner, Di Caprio, Giuseppe, Schonbrun, Ethan, Hansen, Scott, Safo, Martin K., Wood, David K., Higgins, John M., and Light, David R.

Abstract

Dilution of HbS with non-sickling hemoglobin or hemoglobin with increased oxygen affinity is clinically beneficial in sickle cell disease. Aldehydes, including 5-HMF, tucaresol or GBT440, modify the N-terminus of HbS by reversible covalent imine formation generating modified forms of HbS that resist polymerization under low oxygen concentrations. In contrast to reversible imine formation by aldehydes, we hypothesize that stable modification of HbS will result from N-terminal retention of the initiator methionine (iMet) and subsequent N-terminal acetylation of the iMet (acetyl-iMet).

Published
2019
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