BACKGROUND: KEL1, also known as "K", is one of the most immunogenic red blood cell (RBC) antigens. KEL2, also known as "k," differs from KEL1 by a single amino acid. Anti-Kell system antibodies can lead to significant adverse clinical outcomes in humans, including hemolytic complications in alloimmunized transfusion recipients or in infants of alloimmunized mothers. To provide a platform for in-depth immunologic studies of alloimmunization and subsequent sequelae, we generated transgenic mice expressing the human KEL1 or KEL2 antigens. STUDY DESIGN AND METHODS: Vectors were created in which cDNAs encoding either KEL1 or KEL2 were regulated by an erythroid specific β-globin promoter and enhancer. Pronuclear microinjections were carried out into a C57BL6 background, and founder pups were identified by polymerase chain reaction and screened for expression by flow cytometry. RBC life span and antigen stability were assessed by dye labeling RBCs, transfusing into agammaglobulinemic (µMT) recipients, and tracking by flow cytometry. RESULTS: The expression of either KEL1 or KEL2 is RBC specific and first occurs on early RBC precursors. Both KEL1 and KEL2 RBCs have a normal circulatory life span and stable antigen expression. Expression of KEL1 or KEL2 does not result in altered levels of murine Kell, and resulting RBCs have normal hematologic variables. CONCLUSION: The KEL1 and KEL2 mice represent the first murine system of RBC immunity with antithetical antigens, allowing a more precise modeling of human RBC immunology in general and also a platform for development of novel therapeutics to prevent or minimize the dangers of RBC alloimmunization to the KEL1 and KEL2 antigens in particular.
BACKGROUND: KEL1, also known as "K", is one of the most immunogenic red blood cell (RBC) antigens. KEL2, also known as "k," differs from KEL1 by a single amino acid. Anti-Kell system antibodies can lead to significant adverse clinical outcomes in humans, including hemolytic complications in alloimmunized transfusion recipients or in infants of alloimmunized mothers. To provide a platform for in-depth immunologic studies of alloimmunization and subsequent sequelae, we generated transgenic mice expressing the human KEL1 or KEL2 antigens. STUDY DESIGN AND METHODS: Vectors were created in which cDNAs encoding either KEL1 or KEL2 were regulated by an erythroid specific β-globin promoter and enhancer. Pronuclear microinjections were carried out into a C57BL6 background, and founder pups were identified by polymerase chain reaction and screened for expression by flow cytometry. RBC life span and antigen stability were assessed by dye labeling RBCs, transfusing into agammaglobulinemic (µMT) recipients, and tracking by flow cytometry. RESULTS: The expression of either KEL1 or KEL2 is RBC specific and first occurs on early RBC precursors. Both KEL1 and KEL2 RBCs have a normal circulatory life span and stable antigen expression. Expression of KEL1 or KEL2 does not result in altered levels of murine Kell, and resulting RBCs have normal hematologic variables. CONCLUSION: The KEL1 and KEL2 mice represent the first murine system of RBC immunity with antithetical antigens, allowing a more precise modeling of human RBC immunology in general and also a platform for development of novel therapeutics to prevent or minimize the dangers of RBC alloimmunization to the KEL1 and KEL2 antigens in particular.
Authors: Jeanne E Hendrickson; Maxime Desmarets; Seema S Deshpande; Traci E Chadwick; Christopher D Hillyer; John D Roback; James C Zimring Journal: Transfusion Date: 2006-09 Impact factor: 3.157
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Authors: Heather L Howie; Meghan Delaney; Xiaohong Wang; Lay See Er; Gestur Vidarsson; Tamara C Stegmann; Linda Kapp; Jenna N Lebedev; Yanyun Wu; James P AuBuchon; James C Zimring Journal: Transfusion Date: 2016-09-16 Impact factor: 3.157
Authors: Prabitha Natarajan; Jingchun Liu; Manjula Santhanakrishnan; David R Gibb; Lewis M Slater; Jeanne E Hendrickson Journal: Transfusion Date: 2016-10-13 Impact factor: 3.157
Authors: Sean R Stowell; Kathryn R Girard-Pierce; Nicole H Smith; Kate L Henry; C Maridith Arthur; James C Zimring; Jeanne E Hendrickson Journal: Transfusion Date: 2013-04-29 Impact factor: 3.157
Authors: Sean R Stowell; Kate L Henry; Nicole H Smith; Krystalyn E Hudson; Greg R Halverson; Jaekeun C Park; Ashley M Bennett; Kathryn R Girard-Pierce; C Maridith Arthur; Silvia T Bunting; James C Zimring; Jeanne E Hendrickson Journal: Blood Date: 2013-06-25 Impact factor: 22.113
Authors: Seema R Patel; Ashley Bennett; Kathryn Girard-Pierce; Cheryl L Maier; Satheesh Chonat; Connie M Arthur; Patricia E Zerra; Amanda Mener; Sean R Stowell Journal: Blood Adv Date: 2018-01-23
Authors: David R Gruber; Amanda L Richards; Heather L Howie; Ariel M Hay; Jenna N Lebedev; Xiaohong Wang; James C Zimring; Krystalyn E Hudson Journal: Blood Adv Date: 2020-04-14