Chapter 26  Biology of Erythropoiesis, Erythroid Differentiation, and Maturation  320.e3


             99.  Krystal  G:  A  simple  microassay  for  erythropoietin  based  on   123.  Goleva E, Li LB, Eves PT, et al: Increased glucocorticoid receptor beta
                3H-thymidine  incorporation  into  spleen  cells  from  phenylhydrazine   alters steroid response in glucocorticoid-insensitive asthma. Am J Respir
                treated mice. Exp Hematol 11:649, 1983.               Crit Care Med 173:607, 2006.
            100.  Persons DA, Paulson RF, Loyd MR, et al: Fv2 encodes a truncated form   124.  Varricchio L, Masselli E, Alfani E, et al: The dominant negative beta
                of the Stk receptor tyrosine kinase. Nat Genet 23:159, 1999.  isoform of the glucocorticoid receptor is uniquely expressed in erythroid
            101.  Wessely O, Deiner EM, Beug H, et al: The glucocorticoid receptor is   cells expanded from polycythemia vera patients. Blood 118:425, 2011.
                a key regulator of the decision between self-renewal and differentiation   125.  Poletto V, Rosti V, Villani L, et al: A3669G polymorphism of gluco-
                in erythroid progenitors. EMBO J 16:267, 1997.        corticoid  receptor  is  a  susceptibility  allele  for  primary  myelofibrosis
            102.  Yalcin S, Marinkovic D, Mungamuri SK, et al: ROS-mediated ampli-  and contributes to phenotypic diversity and blast transformation. Blood
                fication of AKT/mTOR signalling pathway leads to myeloproliferative   120:3112, 2012.
                syndrome in Foxo3(-/-) mice. EMBO J 29:4118, 2010.  126.  Lazarides E: From genes to structural morphogenesis: the genesis and
            103.  Socolovsky M, Nam H, Fleming MD, et al: Ineffective erythropoiesis in   epigenesis of a red blood cell. Cell 51:345, 1987.
                Stat5a(-/-)5b(-/-) mice due to decreased survival of early erythroblasts.   127.  Anstee DJ: The relationship between blood groups and disease. Blood
                Blood 98:3261, 2001.                                  115:4635, 2010.
            104.  Vannucchi  AM,  Bianchi  L,  Cellai  C,  et al:  Accentuated  response  to   128.  Hudson  KE,  Lin  E,  Hendrickson  JE,  et al:  Regulation  of  primary
                phenylhydrazine  and  erythropoietin  in  mice  genetically  impaired   alloantibody response through antecedent exposure to a microbial T-cell
                for  their  GATA-1  expression  (GATA-1(low)  mice).  Blood  97:3040,   epitope. Blood 115:3989, 2010.
                2001.                                             129.  Mohandas N, Gallagher PG: Red cell membrane: past, present, and
            105.  Sanchez M, Weissman IL, Pallavicini M, et al: Differential amplification   future. Blood 112:3939, 2008.
                of murine bipotent megakaryocytic/erythroid progenitor and precursor   130.  Woods CM, Lazarides E: The erythroid membrane skeleton: expression
                cells during recovery from acute and chronic erythroid stress. Stem Cells   and assembly during erythropoiesis. Annu Rev Med 39:107, 1988.
                24:337, 2006.                                     131.  Hanspal M, Prchal JT, Palek J: Biogenesis of erythrocyte membrane
            106.  Vannucchi AM, Paoletti F, Linari S, et al: Identification and charac-  skeleton in health and disease. Stem Cells 11(Suppl 1):8, 1993.
                terization of a bipotent (erythroid and megakaryocytic) cell precursor   132.  Hakomori S: Blood group ABH and Ii antigens of human erythrocytes:
                from  the  spleen  of  phenylhydrazine-treated  mice.  Blood  95:2559,   chemistry,  polymorphism,  and  their  developmental  change.  Semin
                2000.                                                 Hematol 18:39, 1981.
            107.  Bauer A, Tronche F, Wessely O, et al: The glucocorticoid receptor is   133.  Mohandas N, Narla A: Blood group antigens in health and disease. Curr
                required for stress erythropoiesis. Genes Dev 13:2996, 1999.  Opin Hematol 12:135, 2005.
            108.  Dolznig H, Grebien F, Deiner EM, et al: Erythroid progenitor renewal   134.  Kalfa TA, Pushkaran S, Mohandas N, et al: Rac GTPases regulate the
                versus differentiation: genetic evidence for cell autonomous, essential   morphology and deformability of the erythrocyte cytoskeleton. Blood
                functions of EpoR, Stat5 and the GR. Oncogene 25:2890, 2006.  108:3637, 2006.
            109.  Golde DW, Bersch N, Cline MJ: Potentiation of erythropoiesis in vitro   135.  Palis  J,  Malik  J,  McGrath  KE,  et al:  Primitive  erythropoiesis  in  the
                by dexamethasone. J Clin Invest 57:57, 1976.          mammalian embryo. Int J Dev Biol 54:1011, 2010.
            110.  Gursoy A, Dogruk Unal A, Ayturk S, et al: Polycythemia as the first   136.  Lee JC, Gimm JA, Lo AJ, et al: Mechanism of protein sorting during
                manifestation of Cushing’s disease. J Endocrinol Invest 29:742, 2006.  erythroblast  enucleation:  role  of  cytoskeletal  connectivity.  Blood
            111.  Francke U, Foellmer BE: The glucocorticoid receptor gene is in 5q31-  103:1912, 2004.
                q32 [corrected]. Genomics 4:610, 1989.            137.  Satchwell  TJ,  Hawley  BR,  Bell  AJ,  et al:  The  cytoskeletal  binding
            112.  Otto C, Reichardt HM, Schutz G: Absence of glucocorticoid receptor-  domain of band 3 is required for multiprotein complex formation and
                beta in mice. J Biol Chem 272:26665, 1997.            retention during erythropoiesis. Haematologica 100:133, 2015.
            113.  Theriault A, Boyd E, Harrap SB, et al: Regional chromosomal assign-  138.  Shearstone  JR,  Pop  R,  Bock  C,  et al:  Global  DNA  demethylation
                ment of the human glucocorticoid receptor gene to 5q31. Hum Genet   during mouse erythropoiesis in vivo. Science 334:799, 2011.
                83:289, 1989.                                     139.  Ji  P,  Yeh  V,  Ramirez  T,  et al:  Histone  deacetylase  2  is  required  for
            114.  Zhou J, Cidlowski JA: The human glucocorticoid receptor: one gene,   chromatin condensation and subsequent enucleation of cultured mouse
                multiple proteins and diverse responses. Steroids 70:407, 2005.  fetal erythroblasts. Haematologica 95:2013, 2010.
            115.  Hinds TD, Jr, Ramakrishnan S, Cash HA, et al: Discovery of glucocor-  140.  Ubukawa  K,  Guo  YM,  Takahashi  M,  et al:  Enucleation  of  human
                ticoid receptor-beta in mice with a role in metabolism. Mol Endocrinol   erythroblasts involves non-muscle myosin IIB. Blood 119:1036, 2012.
                24:1715, 2010.                                    141.  Zhang  J,  Kundu  M,  Ney  PA:  Mitophagy  in  mammalian  cells:  the
            116.  Haarman  EG,  Kaspers  GJ,  Pieters  R,  et al:  Glucocorticoid  receptor   reticulocyte model. Methods Enzymol 452:227, 2009.
                alpha, beta and gamma expression vs in vitro glucocorticod resistance   142.  Yoshida H, Kawane K, Koike M, et al: Phosphatidylserine-dependent
                in childhood leukemia. Leukemia 18:530, 2004.         engulfment by macrophages of nuclei from erythroid precursor cells.
            117.  Sanchez-Vega  B,  Krett  N,  Rosen  ST,  et al:  Glucocorticoid  receptor   Nature 437:754, 2005.
                transcriptional isoforms and resistance in multiple myeloma cells. Mol   143.  Li W: Eat-me signals: keys to molecular phagocyte biology and “appe-
                Cancer Ther 5:3062, 2006.                             tite” control. J Cell Physiol 227:1291, 2012.
            118.  Kay  P,  Schlossmacher  G,  Matthews  L,  et al:  Loss  of  glucocorticoid   144.  Krauss SW, Lo AJ, Short SA, et al: Nuclear substructure reorganization
                receptor  expression  by  DNA  methylation  prevents  glucocorticoid   during late-stage erythropoiesis is selective and does not involve caspase
                induced apoptosis in human small cell lung cancer cells. PLoS ONE   cleavage of major nuclear substructural proteins. Blood 106:2200, 2005.
                6:e24839, 2011.                                   145.  Soni S, Bala S, Gwynn B, et al: Absence of erythroblast macrophage
            119.  Kumsta R, Moser D, Streit F, et al: Characterization of a glucocorticoid   protein (Emp) leads to failure of erythroblast nuclear extrusion. J Biol
                receptor gene (GR, NR3C1) promoter polymorphism reveals function-  Chem 281:20181, 2006.
                ality and extends a haplotype with putative clinical relevance. Am J Med   146.  Chasis JA, Mohandas N: Erythroblastic islands: niches for erythropoi-
                Genet B Neuropsychiatr Genet 150B:476, 2009.          esis. Blood 112:470, 2008.
            120.  Krupoves A, Mack D, Deslandres C, et al: Variation in the glucocor-  147.  Bordon Y: Macrophages: bloody regulators. Nat Rev Immunol 13:307,
                ticoid receptor gene (NR3C1) may be associated with corticosteroid   2013.
                dependency and resistance in children with Crohn’s disease. Pharmaco-  148.  de Back DZ, Kostova EB, van Kraaij M, et al: Of macrophages and red
                genet Genomics 21:454, 2011.                          blood cells; a complex love story. Front Physiol 5:9, 2014.
            121.  DeRijk R, de Kloet ER: Corticosteroid receptor genetic polymorphisms   149.  McGrath KE: Red cell island dances: switching hands. Blood 123:3847,
                and stress responsivity. Endocrine 28:263, 2005.      2014.
            122.  van  Rossum  EF,  Binder  EB,  Majer  M,  et al:  Polymorphisms  of  the   150.  Falchi  M,  Varricchio  L,  Martelli  F,  et al:  Dexamethasone  targeted
                glucocorticoid  receptor  gene  and  major  depression.  Biol  Psychiatry   directly  to  macrophages  induces  macrophage  niches  that  promote
                59:681, 2006.                                         erythroid expansion. Haematologica 100:178, 2015.