scholarly journals Can new optical techniques for in vivo imaging and flow cytometry of the microcirculation benefit sickle cell disease research?

2011 ◽  
Vol 79A (10) ◽  
pp. 766-774 ◽  
Author(s):  
Stephen P. Morgan
Keyword(s):  
Flow Cytometry ◽  
Sickle Cell Disease ◽  
Sickle Cell ◽  
In Vivo Imaging ◽  
Cell Disease ◽  
Optical Techniques ◽  
Disease Research

Mitophagy Induction Is a Potential Therapeutic Approach for Sickle Cell Disease

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 267-267
Author(s):  
Ramasamy Jagadeeswaran ◽  
Benjamin Alejandro Vazquez ◽  
Vinzon Ibanez ◽  
Maria A Ruiz ◽  
Robert E Molokie ◽  
...  
Keyword(s):  
Flow Cytometry ◽  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Therapeutic Approach ◽  
Research Funding ◽  
Single Point Mutation ◽  
Cell Disease ◽  
Blood Disorder ◽  
In Vivo Treatment

Abstract Sickle cell disease (SCD) is an inherited blood disorder that affects millions of people worldwide. A single point mutation of the sixth amino acid of β-globin causes glutamic acid to be replaced by valine, rendering the hemoglobin susceptible to polymerization when deoxygenated. SCD patients suffer from the wide variety of disease manifestations including chronic hemolytic anemia, inflammation, painful vaso-occlusive crises, multisystem organ damage, and reduced life expectancy. In addition to the HbS polymerization-mediated rigid and fragile sickle-shaped red blood cell (RBC) formation, an excessive formation of intracellular reactive oxygen species (ROS) occurs in SCD red blood cells, which accelerates their hemolysis. This causes the release of ROS, free extracellular hemoglobin, hemin, and inflammatory cytokines that trigger disease progression. We analyzed levels of ROS in SCD patient RBCs and observed a higher fraction of intracellular ROS positive RBC in SCD (HbSS) compared to control (HbAA) RBC of adults [Control (HbAA): 7.1%± 1.4 %, n=11; SCD (HbSS): 25.3 % ± 4.3%, n=9; p<0.0004]. We also made the novel observation that mature RBCs from SCD patients abnormally contain mitochondria as evidenced by flow cytometry analysis of blood samples of 36 SCD patients and 14 normal human control subjects.[Control (HbAA):0.4 % ± 0.04%, n=14; SCD (HbSS): 7.8%± 0.9%, n=30; p<0.0001]. Further subset analysis from SCD patients with HbSC showed mitochondrial retention in their mature RBCs [HbSC: 2.2%± 0.6%,n=6 p<0.01], however to a lesser degree than patients with HbSS. Transmission electron microscopy confirmed the presence of mitochondria in mature RBC of patients with SCD. ROS analysis between mitochondria positive vs. negative fractions showed that mitochondria-positive (TMRM+) RBC fractions have higher levels of ROS compared to mitochondria-negative (TMRM-) RBC fractions. This data strongly suggests that retained mitochondria significantly contribute to the production of ROS in SCD RBCs. Similar to humans, a higher fraction of RBCs of SCD mice (B6;129-Hbatm1(HBA)Tow Hbbtm2(HBG1,HBB*)Tow/J) retain mitochondria compared to control mice RBC [Control (HbAA): 0.29% ± 0.18%; SCD (HbSS): 16.68%± 1.9%, p<0.0001]. While investigating RN-1, a lysine specific demethylase-1 (LSD-1) inhibitor, as a HbF inducing agent, we observed that SCD mice treated with RN-1 showed a reduction in the fraction of RBCs which retain mitochondria. Therefore, we investigated mitophagy-inducing drugs as a possible useful therapeutic approach for SCD by administering mitophagy-inducing agent Sirolimus. SCD mice treated with RN-1 (5mg), or Sirolimus (5mg) had a significant decrease in the fraction of mitochondria containing RBCs (RN1: 4.96± 1.0%, p<0.0005; Sirolimus: 6.4% ± 1.8%, p<0.002). We observed a reduction of ROS in mature RBCs coupled with decreased mitochondrial retention in RBCs after in vivo treatment with RN1 or Sirolimus as measured by co-staining of TMRM, APC-conjugated CD71antibody, and CM-H2DCFDA. We also observed a significant improvement in RBC survival after the in vivo treatment with Sirolimus or RN-1. RBC survival was measured by flow cytometry and calculated biotin positive circulating RBCs after 2 days of in vivo labeling [SCD treated with vehicle control: 40 %± 2.6%; SCD treated with RN1 (2.5mg): 69.9 ± 2.6%, p<0.004; Sirolimus (5mg): 67.5% ± 6.1%, p<0.04]. Based on this data, mitophagy-inducing drugs have the potential to be a novel therapeutic approach for the treatment of SCD patients. Disclosures Jagadeeswaran: Acetylon: Research Funding. DeSimone:EpiDestiny: Consultancy, Other: patents around decitabine and tetrahydrouridine. Lavelle:Acetylon: Research Funding. Rivers:Acetylon: Research Funding.

scholarly journals Engineering, Generation and Preliminary Characterization of a Humanized Porcine Sickle Cell Disease Animal Model

2020 ◽  
Author(s):  
Tobias M. Franks ◽  
Sharie J. Haugabook ◽  
Elizabeth A. Ottinger ◽  
Meghan S. Vermillion ◽  
Kevin M. Pawlik ◽  
...  
Keyword(s):  
Animal Model ◽  
Sickle Cell Disease ◽  
Mouse Models ◽  
Sickle Cell ◽  
Cell Model ◽  
Globin Genes ◽  
Cell Disease ◽  
Small Vessels

AbstractMouse models of sickle cell disease (SCD) that faithfully switch from fetal to adult hemoglobin (Hb) have been important research tools that accelerated advancement towards treatments and cures for SCD. Red blood cells (RBCs) in these animals sickled in vivo, occluded small vessels in many organs and resulted in severe anemia like in human patients. SCD mouse models have been valuable in advancing clinical translation of some therapeutics and providing a better understanding of the pathophysiology of SCD. However, mouse models vary greatly from humans in their anatomy and physiology and therefore have limited application for certain translational efforts to transition from the bench to bedside. These differences create the need for a higher order animal model to continue the advancement of efforts in not only understanding relevant underlying pathophysiology, but also the translational aspects necessary for the development of better therapeutics to treat or cure SCD. Here we describe the development of a humanized porcine sickle cell model that like the SCD mice, expresses human ɑ-, β− and γ-globin genes under the control of the respective endogenous porcine locus control regions (LCR). We also describe our initial characterization of the SCD pigs and plans to make this model available to the broader research community.

scholarly journals Reconstruction of Sickle Cell Disease with Circulating Sickling Red Blood Cells in Novel Humanized Cytokines and Liver Mistrg Mice

Blood ◽  
2020 ◽  
Vol 136 (Supplement 1) ◽  
pp. 29-30
Author(s):  
Yuanbin Song ◽  
Rana Gbyli ◽  
Liang Shan ◽  
Wei Liu ◽  
Yimeng Gao ◽  
...  
Keyword(s):  
Sickle Cell Disease ◽  
Mouse Model ◽  
Red Blood Cells ◽  
Sickle Cell ◽  
Blood Cells ◽  
Red Cell ◽  
Cell Disease ◽  
Ineffective Erythropoiesis ◽  
Cd34 Cells

In vivo models of human erythropoiesis with generation of circulating mature human red blood cells (huRBC) have remained elusive, limiting studies of primary human red cell disorders. In our prior study, we have generated the first combined cytokine-liver humanized immunodeficient mouse model (huHepMISTRG-Fah) with fully mature, circulating huRBC when engrafted with human CD34+ hematopoietic stem and progenitor cells (HSPCs)1. Here we present for the first time a humanized mouse model of human sickle cell disease (SCD) which replicates the hallmark pathophysiologic finding of vaso-occlusion in mice engrafted with primary patient-derived SCD HSPCs. SCD is an inherited blood disorder caused by a single point mutation in the beta-globin gene. Murine models of SCD exclusively express human globins in mouse red blood cells in the background of murine globin knockouts2 which exclusively contain murine erythropoiesis and red cells and thus fail to capture the heterogeneity encountered in patients. To determine whether enhanced erythropoiesis and most importantly circulating huRBC in engrafted huHepMISTRG-Fah mice would be sufficient to replicate the pathophysiology of SCD, we engrafted it with adult SCD BM CD34+ cells as well as age-matched control BM CD34+ cells. Overall huCD45+ and erythroid engraftment in BM (Fig. a, b) and PB (Fig. c, d) were similar between control or SCD. Using multispectral imaging flow cytometry, we observed sickling huRBCs (7-11 sickling huRBCs/ 100 huRBCs) in the PB of SCD (Fig. e) but not in control CD34+ (Fig. f) engrafted mice. To determine whether circulating huRBC would result in vaso-occlusion and associated findings in SCD engrafted huHepMISTRG-Fah mice, we evaluated histological sections of lung, liver, spleen, and kidney from control and SCD CD34+ engrafted mice. SCD CD34+ engrafted mice lungs showed an increase in alveolar macrophages (arrowheads) associated with alveolar hemorrhage and thrombosis (arrows) but not observed control engrafted mice (Fig. g). Spleens of SCD engrafted mice showed erythroid precursor expansion, sickled erythrocytes in the sinusoids (arrowheads), and vascular occlusion and thrombosis (arrows) (Fig. h). Liver architecture was disrupted in SCD engrafted mice with RBCs in sinusoids and microvascular thromboses (Fig. i). Congestion of capillary loops and peritubular capillaries and glomeruli engorged with sickled RBCs was evident in kidneys (Fig. j) of SCD but not control CD34+ engrafted mice. SCD is characterized by ineffective erythropoiesis due to structural abnormalities in erythroid precursors3. As a functional structural unit, erythroblastic islands (EBIs) represent a specialized niche for erythropoiesis, where a central macrophage is surrounded by developing erythroblasts of varying differentiation states4. In our study, both SCD (Fig. k) and control (Fig. l) CD34+ engrafted mice exhibited EBIs with huCD169+ huCD14+ central macrophages surrounded by varying stages of huCD235a+ erythroid progenitors, including enucleated huRBCs (arrows). This implies that huHepMISTRG-Fah mice have the capability to generate human EBIs in vivo and thus represent a valuable tool to not only study the effects of mature RBC but also to elucidate mechanisms of ineffective erythropoiesis in SCD and other red cell disorders. In conclusion, we successfully engrafted adult SCD patient BM derived CD34+ cells in huHepMISTRG-Fah mice and detected circulating, sickling huRBCs in the mouse PB. We observed pathological changes in the lung, spleen, liver and kidney, which are comparable to what is seen in the established SCD mouse models and in patients. In addition, huHepMISTRG-Fah mice offer the opportunity to study the role of the central macrophage in human erythropoiesis in health and disease in an immunologically advantageous context. This novel mouse model could therefore serve to open novel avenues for therapeutic advances in SCD. Reference 1. Song Y, Shan L, Gybli R, et. al. In Vivo reconstruction of Human Erythropoiesis with Circulating Mature Human RBCs in Humanized Liver Mistrg Mice. Blood. 2019;134:338. 2. Ryan TM, Ciavatta DJ, Townes TM. Knockout-transgenic mouse model of sickle cell disease. Science. 1997;278(5339):873-876. 3. Blouin MJ, De Paepe ME, Trudel M. Altered hematopoiesis in murine sickle cell disease. Blood. 1999;94(4):1451-1459. 4. Manwani D, Bieker JJ. The erythroblastic island. Curr Top Dev Biol. 2008;82:23-53. Disclosures Xu: Seattle Genetics: Membership on an entity's Board of Directors or advisory committees. Flavell:Zai labs: Consultancy; GSK: Consultancy.

The placental-umbilical unit in sickle cell disease pregnancy: A model for studying in vivo functional adjustments to hypoxia in humans

2004 ◽  
Vol 35 (11) ◽  
pp. 1353-1359 ◽  
Author(s):  
Paul Trampont ◽  
Martine Roudier ◽  
Anne-Marie Andrea ◽  
Nelly Nomal ◽  
Therese-Marie Mignot ◽  
...  
Keyword(s):  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Cell Disease

The Voronoi diagram for graphs and its application in the Sickle Cell Disease research

2012 ◽  
Vol 3 (5) ◽  
pp. 335-343 ◽  
Author(s):  
M. Zivanic ◽  
O. Daescu ◽  
A. Kurdia ◽  
S.R. Goodman
Keyword(s):  
Sickle Cell Disease ◽  
Voronoi Diagram ◽  
Sickle Cell ◽  
Cell Disease ◽  
Disease Research

scholarly journals In vivo survival studies of 51Cr-labeled methyl acetimidate treated erythrocytes in patients with sickle cell disease

Blood ◽  
1980 ◽  
Vol 56 (6) ◽  
pp. 1041-1047 ◽  
Author(s):  
TG Gabuzda ◽  
TL Chao ◽  
MR Berenfeld ◽  
T Gelbart
Keyword(s):  
Sickle Cell Disease ◽  
Survival Time ◽  
Sickle Cell ◽  
Clinical Testing ◽  
Cell Disease ◽  
Show Evidence ◽  
Survival Studies ◽  
Circulating Antibody

Abstract Studies of the survival time of 51Cr labeled erythrocytes treated in vitro with methyl acetimidate (MAI) were conducted in 13 patients with sickle cell disease in order to assess the suitability of this antisickling agent for more extensive clinical testing. In comparison with previously measured control values (average t1/2 8.4 +/- 1.1 days a), the survival time of the treated erythrocytes in 10 of the patients who were not transfused was initially prolonged (average t1/2 24.4 +/- 4.6 days). However, 5 of the 13 patients studied developed circulating antibody against the MAI treated erythrocytes, markedly reducing the survival time of MAI treated erythrocytes in subsequent studies. Two patients, each challenged 3 times with infused MAI treated erythrocytes, failed to show evidence of antibody production, suggesting that not all subjects become immunized even after repeated exposure. In spite of many other promising properties of MAI as an antisickling agent of potential value, consideration of its use in further clinical testing must depend on successful avoidance of immunization in patients receiving infusions of treated erythrocytes.

Sialic acid in sickle cell disease.

1988 ◽  
Vol 34 (7) ◽  
pp. 1443-1446 ◽  
Author(s):  
G I Ekeke ◽  
G O Ibeh
Keyword(s):  
Sialic Acid ◽  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Age Groups ◽  
Dependent Manner ◽  
Cell Disease ◽  
Concentration Dependent Manner ◽  
Sialic Acid Content ◽  
Age Range

Abstract Neuraminic (sialic) acid concentrations in serum from normal and sickle cell (HbSS) subjects were determined for discrete age groups from childhood through adolescence. Values in sickle cell disease were consistently lower over the entire age range. We further investigated the effect of exogenous sialic acid on the rate of sickling reversion of HbSS erythrocytes and demonstrated that this compound in millimole per liter concentrations could revert pre-sickled erythrocytes to their normal morphology in a concentration-dependent manner. When subjected to partial de-sialation with sialidase (EC 3.2.1.18), the HbSS erythrocytes not only sickled faster upon deoxygenation, they also reverted more slowly on treatment with phenylalanine (a more efficient anti-sickling agent than sialic acid) than did untreated cells. We conclude that, in sickle cell disease, erythrocyte sialic acid content could play a significant role, not only in the control of the sickling rate in vivo, but also, after sickling has occurred, in the rate of recovery from a sickling crisis.

scholarly journals Biologic Complexity in Sickle Cell Disease: Implications for Developing Targeted Therapeutics

2013 ◽  
Vol 2013 ◽  
pp. 1-12 ◽  
Author(s):  
Beatrice E. Gee
Keyword(s):  
Clinical Trials ◽  
Sickle Cell Disease ◽  
Sickle Cell ◽  
Vascular Occlusion ◽  
Current Therapy ◽  
Cell Disease ◽  
Primary Defect ◽  
Relative Contribution ◽  
Hb S

Current therapy for sickle cell disease (SCD) is limited to supportive treatment of complications, red blood cell transfusions, hydroxyurea, and stem cell transplantation. Difficulty in the translation of mechanistically based therapies may be the result of a reductionist approach focused on individual pathways, without having demonstrated their relative contribution to SCD complications. Many pathophysiologic processes in SCD are likely to interact simultaneously to contribute to acute vaso-occlusion or chronic vasculopathy. Applying concepts of systems biology and network medicine, models were developed to show relationships between the primary defect of sickle hemoglobin (Hb S) polymerization and the outcomes of acute pain and chronic vasculopathy. Pathophysiologic processes such as inflammation and oxidative stress are downstream by-products of Hb S polymerization, transduced through secondary pathways of hemolysis and vaso-occlusion. Pain, a common clinical trials endpoint, is also complex and may be influenced by factors outside of sickle cell polymerization and vascular occlusion. Future sickle cell research needs to better address the biologic complexity of both sickle cell disease and pain. The relevance of individual pathways to important sickle cell outcomes needs to be demonstratedin vivobefore investing in expensive and labor-intensive clinical trials.

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