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Granulopoiesis

January 01, 1970

Granulopoiesis (or granulocytopoiesis) is a part of haematopoiesis, that leads to the production of granulocytes. A granulocyte, also referred to as a polymorphonuclear leukocyte (PMN), is a type of white blood cell that has multi lobed nuclei, usually containing three lobes, and has a significant amount of cytoplasmic granules within the cell.[1] Granulopoiesis takes place in the bone marrow.[2] It leads to the production of three types of mature granulocytes: neutrophils (most abundant, making up to 60% of all white blood cells), eosinophils (up to 4%) and basophils (up to 1%).[3]

Diagram of human haematopoiesis, showing all types of granulocyte precursors.

Stages of granulocyte development edit

Granulopoiesis is often divided into two parts;

1) Granulocyte lineage determination and

2) Committed granulopoiesis.

Granulocyte lineage determination edit

Granulopoiesis, as well as the rest of haematopoiesis, begins from a haematopoietic stem cells. These are multipotent cells that reside in the bone marrow niche and have the ability to give rise to all haematopoietic cells, as well as the ability of self renewal.[4] They give rise to either a common lymphoid progenitor (CLP, a progenitor for all lymphoid cells) or a common myeloid progenitor, CMP, an oligopotent progenitor cell, that gives rise to the myeloid part of the haematopoietic tree.[1] The first stage of the myeloid lineage is a granulocyte - monocyte progenitor (GMP), still an oligopotent progenitor, which then develops into unipotent cells that will later on form a population of granulocytes, as well as a population of monocytes. The first unipotent cell in granulopoiesis is a myeloblast.[5]

Committed granulopoiesis edit

Committed granulopoiesis consists of maturation stages of unipotent cells. The first cell that starts to resemble a granulocyte is a myeloblast. It is characterized by large oval nucleus that takes up most of the space in the cell and very little cytoplasm. The next developmental stage, a promyelocyte, still has a large oval nucleus, but there is more cytoplasm in the cell at this point, also cytoplasmic granules are beginning to form. The development of granules continues with the next stage, a myelocyte. At this point, the nucleus is starting to shrink. At the stage of a metamyelocyte the cell nucleus is becoming kidney-shaped and it becomes even more bent in the stage of a band cell. The maturation is finished with the emergence of a segmented nucleus that is specific for a mature granulocyte.[1][5][6]

Regulation of granulopoiesis edit

Transcriptional regulation edit

The maturation of granulocytic precursors is tightly regulated at transcriptional level. Granulocyte lineage determination is regulated by expression of C/EBPα, which is necessary for the transition from CMPs to GMPs and levels of PU.1, that drive the differentation from GMPs to monocytes (high PU.1 levels) or to granulocytes (low PU.1 levels).[1][7] Committed granulopoiesis is regulated by C/EBPε and GFI-1, these two transcriptional factors are important for terminal granulocyte differentiation. Other transcriptional factors that regulate granulopoiesis are: CBF, MYB, SMAD4 and HOX genes.[1][8][9]

Regulation by cytokines edit

Granulopoiesis is also regulated by cytokines to a certain extent. The main cytokines driving granulopoiesis are: GM-CSF (formation of GMPs from CMPs), G-CSF (commitment to the granulocyte lineage, formation of myeloblasts from GMPs), IL-3 (enhances the production of GM-CSF and G-CSF) and SCF.[10][11] These are secreted by other haematopoietic cells in the bone marrow or at the site of inflammation as well as epithelial and endothelial cells.[2][12]

Types of granulopoiesis edit

Steady state granulopoiesis edit

Steady state granulopoiesis is a term used to describe the normal daily production of granulocytes. Granulocytes are short lived cells (their lifespan is between 6 and 8 hours) with a high cell turnover. The number of granulocytes produced every day is between 5 and 10 x 1010.[13] The master regulator of steady state granulopoiesis is C/EBPα. It restricts the cell cycle of immature cells by inhibition of CDK2 and CDK4 and promotes granulocytic differentiation.[14] Steady state production of granulocytes is activated after the engulfment of apoptotic granulocytes by tissue macrophages.[15]

Emergency granulopoiesis edit

Emergency granulopoiesis is a fundamental hematopoietic mechanism activated during acute infections or inflammatory conditions, leading to a swift increase in granulocyte production, especially neutrophils, in the bone marrow. This process is essential for enhancing the innate immune system's capability to confront pathogen invasions effectively.[16][17][18] Hematopoietic stem cells (HSCs) undergo significant transcriptional reprogramming in response to emergency conditions, transitioning from a lymphoid-biased state towards a myeloid-biased identity, thereby aligning the hematopoietic system's output with the urgent demand for granulocytes.[19]

Under normal conditions, steady-state granulopoiesis maintains granulocyte levels to meet physiological needs. However, after a major insult, typically a bacterial infection, the hematopoietic program switches from steady-state to emergency granulopoiesis. This switch is mediated by a transition from C/EBPα to C/EBPβ, the primary transcriptional regulator of emergency granulopoiesis. C/EBPβ enhances the production of granulocytes by promoting the progression of the cell cycle of myeloid progenitors at an accelerated rate, thereby generating a sufficient amount of new granulocytes to combat the insult.[20][14]

The transcription factor CCAAT/enhancer binding protein β (C/EBPβ) is a critical regulator in this context, significantly influencing granulocyte lineage commitment and proliferation, especially noted during candidemia-induced scenarios.[21]

The genetic backdrop plays a crucial role in the dynamics of emergency granulopoiesis, as demonstrated by studies in TP53 haploinsufficient models, particularly in FANCC−/− mice, highlighting the intricate interplay between genetic predispositions and the granulopoietic response. [22]Additionally, recent advances have highlighted the importance of both direct and indirect pathogen sensing mechanisms. HSPCs are equipped with pathogen recognition receptors (PRRs) like Toll-like receptors (TLRs), enabling them to initiate myeloid differentiation and proliferation upon detecting pathogen-associated molecular patterns (PAMPs).[18]

Neutrophils, as primary effector cells of the innate immune defense, originate from HSCs through a series of differentiation stages. The emergency granulopoiesis significantly accelerates this differentiation process, ensuring a rapid replenishment of neutrophil populations in response to systemic inflammatory stimuli, thus maintaining immune homeostasis.[23]

The clinical significance of understanding emergency granulopoiesis extends beyond basic science, influencing therapeutic strategies against infectious diseases and immune deficiencies. Balancing rapid neutrophil mobilization against the risk of immune dysregulation is critical, as imbalances can lead to severe conditions like acute respiratory distress syndrome and sepsis-induced organ dysfunctions. [23][14]

References edit

  1. ^ a b c d e Cowland JB, Borregaard N (September 2016). "Granulopoiesis and granules of human neutrophils". Immunological Reviews. 273 (1): 11–28. doi:10.1111/imr.12440. PMID 27558325. S2CID 28294497.
  2. ^ a b Morrison SJ, Scadden DT (January 2014). "The bone marrow niche for haematopoietic stem cells". Nature. 505 (7483): 327–34. Bibcode:2014Natur.505..327M. doi:10.1038/nature12984. PMC 4514480. PMID 24429631.
  3. ^ Blumenreich MS (1990). "The White Blood Cell and Differential Count". In Walker HK, Hall WD, Hurst JW (eds.). Clinical Methods: The History, Physical, and Laboratory Examinations (3rd ed.). Butterworths. ISBN 978-0-409-90077-4. PMID 21250104. Retrieved 2020-01-23.
  4. ^ Ng, Ashley P.; Alexander, Warren S. (2017-02-06). "Haematopoietic stem cells: past, present and future". Cell Death Discovery. 3 (1): 17002. doi:10.1038/cddiscovery.2017.2. ISSN 2058-7716. PMC 5292770. PMID 28180000.
  5. ^ a b Doulatov S, Notta F, Laurenti E, Dick JE (February 2012). "Hematopoiesis: a human perspective". Cell Stem Cell. 10 (2): 120–36. doi:10.1016/j.stem.2012.01.006. PMID 22305562.
  6. ^ Wahed A, Dasgupta A (2015-01-01). "Chapter 2 - Bone Marrow Examination and Interpretation". In Wahed A, Dasgupta A (eds.). Hematology and Coagulation. Elsevier. pp. 15–29. ISBN 978-0-12-800241-4. Retrieved 2020-01-26.
  7. ^ Friedman, Alan D. (April 2015). "C/EBPα in normal and malignant myelopoiesis". International Journal of Hematology. 101 (4): 330–341. doi:10.1007/s12185-015-1764-6. ISSN 1865-3774. PMC 4696001. PMID 25753223.
  8. ^ Ward AC, Loeb DM, Soede-Bobok AA, Touw IP, Friedman AD (June 2000). "Regulation of granulopoiesis by transcription factors and cytokine signals". Leukemia. 14 (6): 973–90. doi:10.1038/sj.leu.2401808. PMID 10865962. S2CID 39411894.
  9. ^ Tsukada, Junichi; Yoshida, Yasuhiro; Kominato, Yoshihiko; Auron, Philip E. (April 2011). "The CCAAT/enhancer (C/EBP) family of basic-leucine zipper (bZIP) transcription factors is a multifaceted highly-regulated system for gene regulation". Cytokine. 54 (1): 6–19. doi:10.1016/j.cyto.2010.12.019. PMID 21257317.
  10. ^ Tsuji T, Sugimoto K, Yanai T, Takashita E, Mori KJ (1994). "Induction of granulocyte-macrophage colony-stimulating factor (GM-CSF) and granulocyte colony-stimulating factor (G-CSF) expression in bone marrow and fractionated marrow cell populations by interleukin 3 (IL-3): IL-3-mediated positive feedback mechanisms of granulopoiesis". Growth Factors. 11 (1): 71–9. doi:10.3109/08977199409015052. PMID 7530467.
  11. ^ Bendall, Linda J.; Bradstock, Kenneth F. (2014-08-01). "G-CSF: From granulopoietic stimulant to bone marrow stem cell mobilizing agent". Cytokine & Growth Factor Reviews. Special Issue: Cytokines and cytokine receptors as Immunotherapeutics. 25 (4): 355–367. doi:10.1016/j.cytogfr.2014.07.011. ISSN 1359-6101. PMID 25131807.
  12. ^ Kawahara R (2007-01-01). "xPharm: The Comprehensive Pharmacology Reference". In Enna SJ, Bylund DB (eds.). Leukopoiesis. Elsevier. pp. 1–5. ISBN 978-0-08-055232-3. Retrieved 2020-01-26.
  13. ^ Summers C, Rankin SM, Condliffe AM, Singh N, Peters AM, Chilvers ER (August 2010). "Neutrophil kinetics in health and disease". Trends in Immunology. 31 (8): 318–24. doi:10.1016/j.it.2010.05.006. PMC 2930213. PMID 20620114.
  14. ^ a b c Manz MG, Boettcher S (May 2014). "Emergency granulopoiesis". Nature Reviews. Immunology. 14 (5): 302–14. doi:10.1038/nri3660. PMID 24751955. S2CID 26683941.
  15. ^ Lawrence SM, Corriden R, Nizet V (June 2018). "The Ontogeny of a Neutrophil: Mechanisms of Granulopoiesis and Homeostasis". Microbiology and Molecular Biology Reviews. 82 (1). doi:10.1128/MMBR.00057-17. PMC 5813886. PMID 29436479.
  16. ^ Manz, Markus G.; Boettcher, Steffen (May 2014). "Emergency granulopoiesis". Nature Reviews Immunology. 14 (5): 302–314. doi:10.1038/nri3660. ISSN 1474-1733. PMID 24751955. S2CID 26683941.
  17. ^ Kondo, Motonari; Wagers, Amy J.; Manz, Markus G.; Prohaska, Susan S.; Scherer, David C.; Beilhack, Georg F.; Shizuru, Judith A.; Weissman, Irving L. (April 2003). "Biology of Hematopoietic Stem Cells and Progenitors: Implications for Clinical Application". Annual Review of Immunology. 21 (1): 759–806. doi:10.1146/annurev.immunol.21.120601.141007. ISSN 0732-0582. PMID 12615892.
  18. ^ a b Paudel, Sagar; Ghimire, Laxman; Jin, Liliang; Jeansonne, Duane; Jeyaseelan, Samithamby (2022-09-05). "Regulation of emergency granulopoiesis during infection". Frontiers in Immunology. 13. doi:10.3389/fimmu.2022.961601. ISSN 1664-3224. PMC 9485265. PMID 36148240.
  19. ^ Vanickova, Karolina; Milosevic, Mirko; Ribeiro Bas, Irina; Burocziova, Monika; Yokota, Asumi; Danek, Petr; Grusanovic, Srdjan; Chiliński, Mateusz; Plewczynski, Dariusz; Rohlena, Jakub; Hirai, Hideyo; Rohlenova, Katerina; Alberich-Jorda, Meritxell (December 2023). "Hematopoietic stem cells undergo a lymphoid to myeloid switch in early stages of emergency granulopoiesis". The EMBO Journal. 42 (23): e113527. doi:10.15252/embj.2023113527. ISSN 0261-4189. PMC 10690458. PMID 37846891.
  20. ^ Hasan, Shirin; Naqvi, Afsar R.; Rizvi, Asim (2018). "Transcriptional Regulation of Emergency Granulopoiesis in Leukemia". Frontiers in Immunology. 9: 481. doi:10.3389/fimmu.2018.00481. ISSN 1664-3224. PMC 5858521. PMID 29593731.
  21. ^ Satake, Sakiko; Hirai, Hideyo; Hayashi, Yoshihiro; Shime, Nobuaki; Tamura, Akihiro; Yao, Hisayuki; Yoshioka, Satoshi; Miura, Yasuo; Inaba, Tohru; Fujita, Naohisa; Ashihara, Eishi; Imanishi, Jiro; Sawa, Teiji; Maekawa, Taira (2012-11-01). "C/EBPβ Is Involved in the Amplification of Early Granulocyte Precursors during Candidemia-Induced "Emergency" Granulopoiesis". The Journal of Immunology. 189 (9): 4546–4555. doi:10.4049/jimmunol.1103007. ISSN 0022-1767. PMID 23024276.
  22. ^ Hu, Liping; Huang, Weiqi; Bei, Ling; Broglie, Larisa; Eklund, Elizabeth A. (2018-03-15). "TP53 Haploinsufficiency Rescues Emergency Granulopoiesis in FANCC −/− Mice". The Journal of Immunology. 200 (6): 2129–2139. doi:10.4049/jimmunol.1700931. ISSN 0022-1767. PMC 5834788. PMID 29427417.
  23. ^ a b Malengier-Devlies, Bert; Metzemaekers, Mieke; Wouters, Carine; Proost, Paul; Matthys, Patrick (2021-12-13). "Neutrophil Homeostasis and Emergency Granulopoiesis: The Example of Systemic Juvenile Idiopathic Arthritis". Frontiers in Immunology. 12. doi:10.3389/fimmu.2021.766620. ISSN 1664-3224. PMC 8710701. PMID 34966386.

January 01, 1970
granulopoiesis, granulocytopoiesis, part, haematopoiesis, that, leads, production, granulocytes, granulocyte, also, referred, polymorphonuclear, leukocyte, type, white, blood, cell, that, multi, lobed, nuclei, usually, containing, three, lobes, significant, am. Granulopoiesis or granulocytopoiesis is a part of haematopoiesis that leads to the production of granulocytes A granulocyte also referred to as a polymorphonuclear leukocyte PMN is a type of white blood cell that has multi lobed nuclei usually containing three lobes and has a significant amount of cytoplasmic granules within the cell 1 Granulopoiesis takes place in the bone marrow 2 It leads to the production of three types of mature granulocytes neutrophils most abundant making up to 60 of all white blood cells eosinophils up to 4 and basophils up to 1 3 Diagram of human haematopoiesis showing all types of granulocyte precursors Contents 1 Stages of granulocyte development 1 1 Granulocyte lineage determination 1 2 Committed granulopoiesis 2 Regulation of granulopoiesis 2 1 Transcriptional regulation 2 2 Regulation by cytokines 3 Types of granulopoiesis 3 1 Steady state granulopoiesis 3 2 Emergency granulopoiesis 4 ReferencesStages of granulocyte development editGranulopoiesis is often divided into two parts 1 Granulocyte lineage determination and2 Committed granulopoiesis Granulocyte lineage determination edit Granulopoiesis as well as the rest of haematopoiesis begins from a haematopoietic stem cells These are multipotent cells that reside in the bone marrow niche and have the ability to give rise to all haematopoietic cells as well as the ability of self renewal 4 They give rise to either a common lymphoid progenitor CLP a progenitor for all lymphoid cells or a common myeloid progenitor CMP an oligopotent progenitor cell that gives rise to the myeloid part of the haematopoietic tree 1 The first stage of the myeloid lineage is a granulocyte monocyte progenitor GMP still an oligopotent progenitor which then develops into unipotent cells that will later on form a population of granulocytes as well as a population of monocytes The first unipotent cell in granulopoiesis is a myeloblast 5 Committed granulopoiesis edit Committed granulopoiesis consists of maturation stages of unipotent cells The first cell that starts to resemble a granulocyte is a myeloblast It is characterized by large oval nucleus that takes up most of the space in the cell and very little cytoplasm The next developmental stage a promyelocyte still has a large oval nucleus but there is more cytoplasm in the cell at this point also cytoplasmic granules are beginning to form The development of granules continues with the next stage a myelocyte At this point the nucleus is starting to shrink At the stage of a metamyelocyte the cell nucleus is becoming kidney shaped and it becomes even more bent in the stage of a band cell The maturation is finished with the emergence of a segmented nucleus that is specific for a mature granulocyte 1 5 6 Regulation of granulopoiesis editTranscriptional regulation edit The maturation of granulocytic precursors is tightly regulated at transcriptional level Granulocyte lineage determination is regulated by expression of C EBPa which is necessary for the transition from CMPs to GMPs and levels of PU 1 that drive the differentation from GMPs to monocytes high PU 1 levels or to granulocytes low PU 1 levels 1 7 Committed granulopoiesis is regulated by C EBPe and GFI 1 these two transcriptional factors are important for terminal granulocyte differentiation Other transcriptional factors that regulate granulopoiesis are CBF MYB SMAD4 and HOX genes 1 8 9 Regulation by cytokines edit Granulopoiesis is also regulated by cytokines to a certain extent The main cytokines driving granulopoiesis are GM CSF formation of GMPs from CMPs G CSF commitment to the granulocyte lineage formation of myeloblasts from GMPs IL 3 enhances the production of GM CSF and G CSF and SCF 10 11 These are secreted by other haematopoietic cells in the bone marrow or at the site of inflammation as well as epithelial and endothelial cells 2 12 Types of granulopoiesis editSteady state granulopoiesis edit Steady state granulopoiesis is a term used to describe the normal daily production of granulocytes Granulocytes are short lived cells their lifespan is between 6 and 8 hours with a high cell turnover The number of granulocytes produced every day is between 5 and 10 x 1010 13 The master regulator of steady state granulopoiesis is C EBPa It restricts the cell cycle of immature cells by inhibition of CDK2 and CDK4 and promotes granulocytic differentiation 14 Steady state production of granulocytes is activated after the engulfment of apoptotic granulocytes by tissue macrophages 15 Emergency granulopoiesis edit Emergency granulopoiesis is a fundamental hematopoietic mechanism activated during acute infections or inflammatory conditions leading to a swift increase in granulocyte production especially neutrophils in the bone marrow This process is essential for enhancing the innate immune system s capability to confront pathogen invasions effectively 16 17 18 Hematopoietic stem cells HSCs undergo significant transcriptional reprogramming in response to emergency conditions transitioning from a lymphoid biased state towards a myeloid biased identity thereby aligning the hematopoietic system s output with the urgent demand for granulocytes 19 Under normal conditions steady state granulopoiesis maintains granulocyte levels to meet physiological needs However after a major insult typically a bacterial infection the hematopoietic program switches from steady state to emergency granulopoiesis This switch is mediated by a transition from C EBPa to C EBPb the primary transcriptional regulator of emergency granulopoiesis C EBPb enhances the production of granulocytes by promoting the progression of the cell cycle of myeloid progenitors at an accelerated rate thereby generating a sufficient amount of new granulocytes to combat the insult 20 14 The transcription factor CCAAT enhancer binding protein b C EBPb is a critical regulator in this context significantly influencing granulocyte lineage commitment and proliferation especially noted during candidemia induced scenarios 21 The genetic backdrop plays a crucial role in the dynamics of emergency granulopoiesis as demonstrated by studies in TP53 haploinsufficient models particularly in FANCC mice highlighting the intricate interplay between genetic predispositions and the granulopoietic response 22 Additionally recent advances have highlighted the importance of both direct and indirect pathogen sensing mechanisms HSPCs are equipped with pathogen recognition receptors PRRs like Toll like receptors TLRs enabling them to initiate myeloid differentiation and proliferation upon detecting pathogen associated molecular patterns PAMPs 18 Neutrophils as primary effector cells of the innate immune defense originate from HSCs through a series of differentiation stages The emergency granulopoiesis significantly accelerates this differentiation process ensuring a rapid replenishment of neutrophil populations in response to systemic inflammatory stimuli thus maintaining immune homeostasis 23 The clinical significance of understanding emergency granulopoiesis extends beyond basic science influencing therapeutic strategies against infectious diseases and immune deficiencies Balancing rapid neutrophil mobilization against the risk of immune dysregulation is critical as imbalances can lead to severe conditions like acute respiratory distress syndrome and sepsis induced organ dysfunctions 23 14 References edit a b c d e Cowland JB Borregaard N September 2016 Granulopoiesis and granules of human neutrophils Immunological Reviews 273 1 11 28 doi 10 1111 imr 12440 PMID 27558325 S2CID 28294497 a b Morrison SJ Scadden DT January 2014 The bone marrow niche for haematopoietic stem cells Nature 505 7483 327 34 Bibcode 2014Natur 505 327M doi 10 1038 nature12984 PMC 4514480 PMID 24429631 Blumenreich MS 1990 The White Blood Cell and Differential Count In Walker HK Hall WD Hurst JW eds Clinical Methods The History Physical and Laboratory Examinations 3rd ed Butterworths ISBN 978 0 409 90077 4 PMID 21250104 Retrieved 2020 01 23 Ng Ashley P Alexander Warren S 2017 02 06 Haematopoietic stem cells past present and future Cell Death Discovery 3 1 17002 doi 10 1038 cddiscovery 2017 2 ISSN 2058 7716 PMC 5292770 PMID 28180000 a b Doulatov S Notta F Laurenti E Dick JE February 2012 Hematopoiesis a human perspective Cell Stem Cell 10 2 120 36 doi 10 1016 j stem 2012 01 006 PMID 22305562 Wahed A Dasgupta A 2015 01 01 Chapter 2 Bone Marrow Examination and Interpretation In Wahed A Dasgupta A eds Hematology and Coagulation Elsevier pp 15 29 ISBN 978 0 12 800241 4 Retrieved 2020 01 26 Friedman Alan D April 2015 C EBPa in normal and malignant myelopoiesis International Journal of Hematology 101 4 330 341 doi 10 1007 s12185 015 1764 6 ISSN 1865 3774 PMC 4696001 PMID 25753223 Ward AC Loeb DM Soede Bobok AA Touw IP Friedman AD June 2000 Regulation of granulopoiesis by transcription factors and cytokine signals Leukemia 14 6 973 90 doi 10 1038 sj leu 2401808 PMID 10865962 S2CID 39411894 Tsukada Junichi Yoshida Yasuhiro Kominato Yoshihiko Auron Philip E April 2011 The CCAAT enhancer C EBP family of basic leucine zipper bZIP transcription factors is a multifaceted highly regulated system for gene regulation Cytokine 54 1 6 19 doi 10 1016 j cyto 2010 12 019 PMID 21257317 Tsuji T Sugimoto K Yanai T Takashita E Mori KJ 1994 Induction of granulocyte macrophage colony stimulating factor GM CSF and granulocyte colony stimulating factor G CSF expression in bone marrow and fractionated marrow cell populations by interleukin 3 IL 3 IL 3 mediated positive feedback mechanisms of granulopoiesis Growth Factors 11 1 71 9 doi 10 3109 08977199409015052 PMID 7530467 Bendall Linda J Bradstock Kenneth F 2014 08 01 G CSF From granulopoietic stimulant to bone marrow stem cell mobilizing agent Cytokine amp Growth Factor Reviews Special Issue Cytokines and cytokine receptors as Immunotherapeutics 25 4 355 367 doi 10 1016 j cytogfr 2014 07 011 ISSN 1359 6101 PMID 25131807 Kawahara R 2007 01 01 xPharm The Comprehensive Pharmacology Reference In Enna SJ Bylund DB eds Leukopoiesis Elsevier pp 1 5 ISBN 978 0 08 055232 3 Retrieved 2020 01 26 Summers C Rankin SM Condliffe AM Singh N Peters AM Chilvers ER August 2010 Neutrophil kinetics in health and disease Trends in Immunology 31 8 318 24 doi 10 1016 j it 2010 05 006 PMC 2930213 PMID 20620114 a b c Manz MG Boettcher S May 2014 Emergency granulopoiesis Nature Reviews Immunology 14 5 302 14 doi 10 1038 nri3660 PMID 24751955 S2CID 26683941 Lawrence SM Corriden R Nizet V June 2018 The Ontogeny of a Neutrophil Mechanisms of Granulopoiesis and Homeostasis Microbiology and Molecular Biology Reviews 82 1 doi 10 1128 MMBR 00057 17 PMC 5813886 PMID 29436479 Manz Markus G Boettcher Steffen May 2014 Emergency granulopoiesis Nature Reviews Immunology 14 5 302 314 doi 10 1038 nri3660 ISSN 1474 1733 PMID 24751955 S2CID 26683941 Kondo Motonari Wagers Amy J Manz Markus G Prohaska Susan S Scherer David C Beilhack Georg F Shizuru Judith A Weissman Irving L April 2003 Biology of Hematopoietic Stem Cells and Progenitors Implications for Clinical Application Annual Review of Immunology 21 1 759 806 doi 10 1146 annurev immunol 21 120601 141007 ISSN 0732 0582 PMID 12615892 a b Paudel Sagar Ghimire Laxman Jin Liliang Jeansonne Duane Jeyaseelan Samithamby 2022 09 05 Regulation of emergency granulopoiesis during infection Frontiers in Immunology 13 doi 10 3389 fimmu 2022 961601 ISSN 1664 3224 PMC 9485265 PMID 36148240 Vanickova Karolina Milosevic Mirko Ribeiro Bas Irina Burocziova Monika Yokota Asumi Danek Petr Grusanovic Srdjan Chilinski Mateusz Plewczynski Dariusz Rohlena Jakub Hirai Hideyo Rohlenova Katerina Alberich Jorda Meritxell December 2023 Hematopoietic stem cells undergo a lymphoid to myeloid switch in early stages of emergency granulopoiesis The EMBO Journal 42 23 e113527 doi 10 15252 embj 2023113527 ISSN 0261 4189 PMC 10690458 PMID 37846891 Hasan Shirin Naqvi Afsar R Rizvi Asim 2018 Transcriptional Regulation of Emergency Granulopoiesis in Leukemia Frontiers in Immunology 9 481 doi 10 3389 fimmu 2018 00481 ISSN 1664 3224 PMC 5858521 PMID 29593731 Satake Sakiko Hirai Hideyo Hayashi Yoshihiro Shime Nobuaki Tamura Akihiro Yao Hisayuki Yoshioka Satoshi Miura Yasuo Inaba Tohru Fujita Naohisa Ashihara Eishi Imanishi Jiro Sawa Teiji Maekawa Taira 2012 11 01 C EBPb Is Involved in the Amplification of Early Granulocyte Precursors during Candidemia Induced Emergency Granulopoiesis The Journal of Immunology 189 9 4546 4555 doi 10 4049 jimmunol 1103007 ISSN 0022 1767 PMID 23024276 Hu Liping Huang Weiqi Bei Ling Broglie Larisa Eklund Elizabeth A 2018 03 15 TP53 Haploinsufficiency Rescues Emergency Granulopoiesis in FANCC Mice The Journal of Immunology 200 6 2129 2139 doi 10 4049 jimmunol 1700931 ISSN 0022 1767 PMC 5834788 PMID 29427417 a b Malengier Devlies Bert Metzemaekers Mieke Wouters Carine Proost Paul Matthys Patrick 2021 12 13 Neutrophil Homeostasis and Emergency Granulopoiesis The Example of Systemic Juvenile Idiopathic Arthritis Frontiers in Immunology 12 doi 10 3389 fimmu 2021 766620 ISSN 1664 3224 PMC 8710701 PMID 34966386 Retrieved from https en wikipedia org w index php title Granulopoiesis amp oldid 1205240893, wikipedia, wiki, book, books, library,

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