Signal-regulatory protein alpha: Difference between revisions

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Revision as of 16:46, 20 September 2018

Signal regulatory protein α (SIRPα) is a regulatory membrane glycoprotein from SIRP family expressed mainly by myeloid cells and also by stem cells or neurons.

SIRPα acts as inhibitory receptor and interacts with a broadly expressed transmembrane protein CD47 also called the "don´t eat me" signal. This interaction negatively controls effector function of innate immune cells such as host cell phagocytosis. SIRPα diffuses laterally on the macrophage membrane and accumulates at a phagocytic synapse to bind CD47 and signal 'self', which inhibits the cytoskeleton-intensive process of phagocytosis by the macrophage.^[1] This is analogous to the self signals provided by MHC class I molecules to NK cells via Ig-like or Ly49 receptors.^[2]^[3] NB. Protein shown to the right is CD47 not SIRP α.

Structure

The cytoplasmic region of SIRPα is highly conserved between rats, mice and humans. Cytoplasmic region contains a number of tyrosine residues, which likely act as ITIMs. Upon CD47 ligation, SIRPα is phosphorylated and recruits phosphatases like SHP1 and SHP2.^[4] The extracellular region contains three Immunoglobulin superfamily domains – single V-set and two C1-set IgSF domains. SIRP β and γ have the similar extracellular structure but different cytoplasmic regions giving contrasting types of signals. SIRP α polymorphisms are found in ligand-binding IgSF V-set domain but it does not affect ligand binding. One idea is that the polymorphism is important to protect the receptor of pathogens binding.^[2]^[5]

Ligands

SIRPα recognizes CD47, an anti-phagocytic signal that distinguishes live cells from dying cells. CD47 has a single Ig-like extracellular domain and five membrane spanning regions. The interaction between SIRPα and CD47 can be modified by endocytosis or cleavage of the receptor, or interaction with surfactant proteins. Surfactant protein A and D are soluble ligands, highly expressed in the lungs, that bind to the same region of SIRPα as CD47 and can therefore competitively block binding.^[5]^[6]

Signalization

The extracellular domain of SIRP α binds to CD47 and transmits intracellular signals through its cytoplasmic domain. CD47-binding is mediated through the NH2-terminal V-like domain of SIRP α. The cytoplasmic region contains four ITIMs that become phosphorylated after binding of ligand. The phosphorylation mediates activation of tyrosine kinase SHP2. SIRP α has been shown to bind also phosphatase SHP1, adaptor protein SCAP2 and FYN-binding protein. Recruitment of SHP phosphatases to the membrane leads to the inhibition of myosin accumulation at the cell surface and results in the inhibition of phagocytosis.^[5]^[6]

Cancer

Cancer cells highly expressed CD47 that activate SIRP α and inhibit macrophage-mediated destruction. In one study, they engineered high-affinity variants of SIRP α that antagonized CD47 on cancer cells and caused increase phagocytosis of cancer cells.^[7] Another study (in mice) found anti-SIRPα antibodies helped macrophages to reduce cancer growth and metastasis, alone and in synergy with other cancer treatments.^[8]^[9]

References

↑ Tsai RK, Discher DE (2008). "Inhibition of "self" engulfment through deactivation of myosin-II at the phagocytic synapse between human cells". J Cell Biol. 180 (5): 988–1003. doi:10.1083/jcb.200708043. PMC 2265407. PMID 18332220.
↑ ^2.0 ^2.1 Barclay AN (2009). "Signal regulatory protein alpha (SIRPalpha)/CD47 interaction and function". Curr Opin Immunol. 21 (1): 47–52. doi:10.1016/j.coi.2009.01.008. PMC 3128989. PMID 19223164.
↑ Stefanidakis M, Newton G, Lee WY, Parkos CA, Luscinskas FW (2008). "Endothelial CD47 interaction with SIRPgamma is required for human T-cell transendothelial migration under shear flow conditions in vitro". Blood. 112 (4): 1280–9. doi:10.1182/blood-2008-01-134429. PMC 2515120. PMID 18524990.
↑ Okazawa, Hideki; Motegi, Sei-ichiro; Ohyama, Naoko; Ohnishi, Hiroshi; Tomizawa, Takeshi; Kaneko, Yoriaki; Oldenborg, Per-Arne; Ishikawa, Osamu; Matozaki, Takashi (2005-02-15). "Negative regulation of phagocytosis in macrophages by the CD47-SHPS-1 system". Journal of Immunology. 174 (4): 2004–2011. doi:10.4049/jimmunol.174.4.2004. ISSN 0022-1767. PMID 15699129.
↑ ^5.0 ^5.1 ^5.2 Barclay AN, Brown MH (2006). "The SIRP family of receptors and immune regulation". Nat Rev Immunol. 6 (6): 457–64. doi:10.1038/nri1859. PMID 16691243.
↑ ^6.0 ^6.1 van Beek EM, Cochrane F, Barclay AN, van den Berg TK (2005). "Signal regulatory proteins in the immune system". J Immunol. 175 (12): 7781–7. doi:10.4049/jimmunol.175.12.7781. PMID 16339510.
↑ Weiskopf K, Ring AM, Ho CC, Volkmer JP, Levin AM, Volkmer AK, et al. (2013). "Engineered SIRPα variants as immunotherapeutic adjuvants to anticancer antibodies". Science. 341 (6141): 88–91. doi:10.1126/science.1238856. PMC 3810306. PMID 23722425.
↑ Potential new cancer treatment activates cancer-engulfing cells. Feb 2017
↑ Yanagita T (2017). "Anti-SIRPα antibodies as a potential new tool for cancer immunotherapy". JCI Insight, 2017; 2 (1). 2. doi:10.1172/jci.insight.89140. PMC 5214103.

Oldenborg PA (2013). "CD47: A Cell Surface Glycoprotein Which Regulates Multiple Functions of Hematopoietic Cells in Health and Disease". ISRN Hematol. 2013: 614619. doi:10.1155/2013/614619. PMC 3564380. PMID 23401787.
Yamauchi T, Takenaka K, Urata S, et al. (2013). "& Akashi, K. (2013). Polymorphic Sirpa is the genetic determinant for NOD-based mouse lines to achieve efficient human cell engraftment". Blood. 121 (8): 1316–1325. doi:10.1182/blood-2012-06-440354.
Oldenborg PA (2004). "Role of CD47 in erythroid cells and in autoimmunity". Leuk. Lymphoma. 45 (7): 1319–27. doi:10.1080/1042819042000201989. PMID 15359629.
Margolis RL, Breschel TS, Li SH, et al. (1996). "Characterization of cDNA clones containing CCA trinucleotide repeats derived from human brain". Somat. Cell Mol. Genet. 21 (4): 279–84. doi:10.1007/BF02255782. PMID 8525433.
Ohnishi H, Kubota M, Ohtake A, et al. (1996). "Activation of protein-tyrosine phosphatase SH-PTP2 by a tyrosine-based activation motif of a novel brain molecule". J. Biol. Chem. 271 (41): 25569–74. doi:10.1074/jbc.271.41.25569. PMID 8810330.
Fujioka Y, Matozaki T, Noguchi T, et al. (1997). "A novel membrane glycoprotein, SHPS-1, that binds the SH2-domain-containing protein tyrosine phosphatase SHP-2 in response to mitogens and cell adhesion". Mol. Cell. Biol. 16 (12): 6887–99. PMC 231692. PMID 8943344.
Sano S, Ohnishi H, Omori A, et al. (1997). "BIT, an immune antigen receptor-like molecule in the brain". FEBS Lett. 411 (2–3): 327–34. doi:10.1016/S0014-5793(97)00724-2. PMID 9271230.
Brooke GP, Parsons KR, Howard CJ (1998). "Cloning of two members of the SIRP alpha family of protein tyrosine phosphatase binding proteins in cattle that are expressed on monocytes and a subpopulation of dendritic cells and which mediate binding to CD4 T cells". Eur. J. Immunol. 28 (1): 1–11. doi:10.1002/(SICI)1521-4141(199801)28:01<1::AID-IMMU1>3.0.CO;2-V. PMID 9485180.
Timms JF, Carlberg K, Gu H, et al. (1998). "Identification of major binding proteins and substrates for the SH2-containing protein tyrosine phosphatase SHP-1 in macrophages". Mol. Cell. Biol. 18 (7): 3838–50. PMC 108968. PMID 9632768.
Veillette A, Thibaudeau E, Latour S (1998). "High expression of inhibitory receptor SHPS-1 and its association with protein-tyrosine phosphatase SHP-1 in macrophages". J. Biol. Chem. 273 (35): 22719–28. doi:10.1074/jbc.273.35.22719. PMID 9712903.
Jiang P, Lagenaur CF, Narayanan V (1999). "Integrin-associated protein is a ligand for the P84 neural adhesion molecule". J. Biol. Chem. 274 (2): 559–62. doi:10.1074/jbc.274.2.559. PMID 9872987.
Ohnishi H, Yamada M, Kubota M, et al. (1999). "Tyrosine phosphorylation and association of BIT with SHP-2 induced by neurotrophins". J. Neurochem. 72 (4): 1402–8. doi:10.1046/j.1471-4159.1999.721402.x. PMID 10098842.
Timms JF, Swanson KD, Marie-Cardine A, et al. (1999). "SHPS-1 is a scaffold for assembling distinct adhesion-regulated multi-protein complexes in macrophages". Curr. Biol. 9 (16): 927–30. doi:10.1016/S0960-9822(99)80401-1. PMID 10469599.
Seiffert M, Cant C, Chen Z, et al. (1999). "Human signal-regulatory protein is expressed on normal, but not on subsets of leukemic myeloid cells and mediates cellular adhesion involving its counterreceptor CD47". Blood. 94 (11): 3633–43. PMID 10572074.
Sano S, Ohnishi H, Kubota M (2000). "Gene structure of mouse BIT/SHPS-1". Biochem. J. 344 (3): 667–75. doi:10.1042/0264-6021:3440667. PMC 1220688. PMID 10585853.
Yang J, Cheng Z, Niu T, et al. (2000). "Structural basis for substrate specificity of protein-tyrosine phosphatase SHP-1". J. Biol. Chem. 275 (6): 4066–71. doi:10.1074/jbc.275.6.4066. PMID 10660565.
Stofega MR, Argetsinger LS, Wang H, et al. (2000). "Negative regulation of growth hormone receptor/JAK2 signaling by signal regulatory protein alpha". J. Biol. Chem. 275 (36): 28222–9. doi:10.1074/jbc.M004238200. PMID 10842184.
Wu CJ, Chen Z, Ullrich A, et al. (2000). "Inhibition of EGFR-mediated phosphoinositide-3-OH kinase (PI3-K) signaling and glioblastoma phenotype by signal-regulatory proteins (SIRPs)". Oncogene. 19 (35): 3999–4010. doi:10.1038/sj.onc.1203748. PMID 10962556.
Latour S, Tanaka H, Demeure C, et al. (2001). "Bidirectional negative regulation of human T and dendritic cells by CD47 and its cognate receptor signal-regulator protein-alpha: down-regulation of IL-12 responsiveness and inhibition of dendritic cell activation". J. Immunol. 167 (5): 2547–54. doi:10.4049/jimmunol.167.5.2547. PMID 11509594.
Deloukas P, Matthews LH, Ashurst J, et al. (2002). "The DNA sequence and comparative analysis of human chromosome 20". Nature. 414 (6866): 865–71. doi:10.1038/414865a. PMID 11780052.

This article incorporates text from the United States National Library of Medicine, which is in the public domain.

[pmid18332220-1] Tsai RK, Discher DE (2008). "Inhibition of "self" engulfment through deactivation of myosin-II at the phagocytic synapse between human cells". J Cell Biol. 180 (5): 988–1003. doi:10.1083/jcb.200708043. PMC 2265407. PMID 18332220.

[pmid19223164-2] 2.0 ^2.1 Barclay AN (2009). "Signal regulatory protein alpha (SIRPalpha)/CD47 interaction and function". Curr Opin Immunol. 21 (1): 47–52. doi:10.1016/j.coi.2009.01.008. PMC 3128989. PMID 19223164.

[pmid18524990-3] Stefanidakis M, Newton G, Lee WY, Parkos CA, Luscinskas FW (2008). "Endothelial CD47 interaction with SIRPgamma is required for human T-cell transendothelial migration under shear flow conditions in vitro". Blood. 112 (4): 1280–9. doi:10.1182/blood-2008-01-134429. PMC 2515120. PMID 18524990.

[4] Okazawa, Hideki; Motegi, Sei-ichiro; Ohyama, Naoko; Ohnishi, Hiroshi; Tomizawa, Takeshi; Kaneko, Yoriaki; Oldenborg, Per-Arne; Ishikawa, Osamu; Matozaki, Takashi (2005-02-15). "Negative regulation of phagocytosis in macrophages by the CD47-SHPS-1 system". Journal of Immunology. 174 (4): 2004–2011. doi:10.4049/jimmunol.174.4.2004. ISSN 0022-1767. PMID 15699129.

[pmid16691243-5] 5.0 ^5.1 ^5.2 Barclay AN, Brown MH (2006). "The SIRP family of receptors and immune regulation". Nat Rev Immunol. 6 (6): 457–64. doi:10.1038/nri1859. PMID 16691243.

[pmid16339510-6] 6.0 ^6.1 van Beek EM, Cochrane F, Barclay AN, van den Berg TK (2005). "Signal regulatory proteins in the immune system". J Immunol. 175 (12): 7781–7. doi:10.4049/jimmunol.175.12.7781. PMID 16339510.

[pmid23722425-7] Weiskopf K, Ring AM, Ho CC, Volkmer JP, Levin AM, Volkmer AK, et al. (2013). "Engineered SIRPα variants as immunotherapeutic adjuvants to anticancer antibodies". Science. 341 (6141): 88–91. doi:10.1126/science.1238856. PMC 3810306. PMID 23722425.

[8] Potential new cancer treatment activates cancer-engulfing cells. Feb 2017

[Yanagita2017-9] Yanagita T (2017). "Anti-SIRPα antibodies as a potential new tool for cancer immunotherapy". JCI Insight, 2017; 2 (1). 2. doi:10.1172/jci.insight.89140. PMC 5214103.

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@@ Line 2: / Line 2: @@
 Signal regulatory protein α (SIRPα) is a regulatory membrane glycoprotein from SIRP family expressed mainly by myeloid cells and also by stem cells or neurons.
-SIRPα acts as inhibitory receptor and interacts with a broadly expressed transmembrane protein [[CD47]] also called the "don´t eat me" signal. This interaction negatively controls effector function of [[Innate immune system|innate immune cells]] such as host cell [[phagocytosis]]. SIRPα diffuses laterally on the [[macrophage]] membrane and accumulates at a phagocytic synapse to bind CD47 and signal 'self', which inhibits the cytoskeleton-intensive process of phagocytosis by the macrophage.<ref name="pmid18332220">{{cite journal| vauthors=Tsai RK, Discher DE| title=Inhibition of "self" engulfment through deactivation of myosin-II at the phagocytic synapse between human cells. | journal=J Cell Biol | year= 2008 | volume= 180 | issue= 5 | pages= 988–1003 | pmid=18332220 | doi= 10.1083/jcb.200708043| pmc= | url=https://www.ncbi.nlm.nih.gov/pubmed/18332220  }}</ref> This is analogous to the self signals provided by [[MHC class I]] molecules to [[NK cells]] via Ig-like or [[Ly49]] receptors.<ref name="pmid19223164">{{cite journal| author=Barclay AN| title=Signal regulatory protein alpha (SIRPalpha)/CD47 interaction and function. | journal=Curr Opin Immunol | year= 2009 | volume= 21 | issue= 1 | pages= 47–52 | pmid=19223164 | doi=10.1016/j.coi.2009.01.008 | pmc=3128989 }}</ref><ref name="pmid18524990">{{cite journal| vauthors=Stefanidakis M, Newton G, Lee WY, Parkos CA, Luscinskas FW| title=Endothelial CD47 interaction with SIRPgamma is required for human T-cell transendothelial migration under shear flow conditions in vitro. | journal=Blood | year= 2008 | volume= 112 | issue= 4 | pages= 1280–9 | pmid=18524990 | doi=10.1182/blood-2008-01-134429 | pmc=2515120 }}</ref> NB. Protein shown to the right is CD47 not SIRP α.
+SIRPα acts as inhibitory receptor and interacts with a broadly expressed transmembrane protein [[CD47]] also called the "don´t eat me" signal. This interaction negatively controls effector function of [[Innate immune system|innate immune cells]] such as host cell [[phagocytosis]]. SIRPα diffuses laterally on the [[macrophage]] membrane and accumulates at a phagocytic synapse to bind CD47 and signal 'self', which inhibits the cytoskeleton-intensive process of phagocytosis by the macrophage.<ref name="pmid18332220">{{cite journal| vauthors=Tsai RK, Discher DE| title=Inhibition of "self" engulfment through deactivation of myosin-II at the phagocytic synapse between human cells. | journal=J Cell Biol | year= 2008 | volume= 180 | issue= 5 | pages= 988–1003 | doi= 10.1083/jcb.200708043| pmc= 2265407| pmid=18332220  }}</ref> This is analogous to the self signals provided by [[MHC class I]] molecules to [[NK cells]] via Ig-like or [[Ly49]] receptors.<ref name="pmid19223164">{{cite journal| author=Barclay AN| title=Signal regulatory protein alpha (SIRPalpha)/CD47 interaction and function. | journal=Curr Opin Immunol | year= 2009 | volume= 21 | issue= 1 | pages= 47–52 | pmid=19223164 | doi=10.1016/j.coi.2009.01.008 | pmc=3128989 }}</ref><ref name="pmid18524990">{{cite journal| vauthors=Stefanidakis M, Newton G, Lee WY, Parkos CA, Luscinskas FW| title=Endothelial CD47 interaction with SIRPgamma is required for human T-cell transendothelial migration under shear flow conditions in vitro. | journal=Blood | year= 2008 | volume= 112 | issue= 4 | pages= 1280–9 | pmid=18524990 | doi=10.1182/blood-2008-01-134429 | pmc=2515120 }}</ref> NB. Protein shown to the right is CD47 not SIRP α.
 ==Structure==
-The cytoplasmic region of SIRPα is highly conserved between rats, mice and humans. Cytoplasmic region contains a number of [[tyrosine]] residues, which likely act as [[Immunoreceptor tyrosine-based inhibitory motif|ITIMs]].  Upon CD47 ligation, SIRPα is phosphorylated and recruits phosphatases like SHP1 and [[PTPN11|SHP2]].<ref>{{Cite journal|last=Okazawa|first=Hideki|last2=Motegi|first2=Sei-ichiro|last3=Ohyama|first3=Naoko|last4=Ohnishi|first4=Hiroshi|last5=Tomizawa|first5=Takeshi|last6=Kaneko|first6=Yoriaki|last7=Oldenborg|first7=Per-Arne|last8=Ishikawa|first8=Osamu|last9=Matozaki|first9=Takashi|date=2005-02-15|title=Negative regulation of phagocytosis in macrophages by the CD47-SHPS-1 system|url=https://www.ncbi.nlm.nih.gov/pubmed/15699129|journal=Journal of Immunology|volume=174|issue=4|pages=2004–2011|issn=0022-1767|pmid=15699129}}</ref> The extracellular region contains three [[Immunoglobulin superfamily]] domains – single V-set and two C1-set [[Immunoglobulin superfamily|IgSF]] domains. SIRP β and γ have the similar extracellular structure but different cytoplasmic regions giving contrasting types of signals. SIRP α polymorphisms are found in ligand-binding [[Immunoglobulin superfamily|IgSF]] V-set domain but it does not affect ligand binding. One idea is that the polymorphism is important to protect the receptor of pathogens binding.<ref name="pmid19223164"/><ref name="pmid16691243">{{cite journal| vauthors=Barclay AN, Brown MH| title=The SIRP family of receptors and immune regulation. | journal=Nat Rev Immunol | year= 2006 | volume= 6 | issue= 6 | pages= 457–64 | pmid=16691243 | doi=10.1038/nri1859 | pmc= | url=https://www.ncbi.nlm.nih.gov/pubmed/16691243  }}</ref>
+The cytoplasmic region of SIRPα is highly conserved between rats, mice and humans. Cytoplasmic region contains a number of [[tyrosine]] residues, which likely act as [[Immunoreceptor tyrosine-based inhibitory motif|ITIMs]].  Upon CD47 ligation, SIRPα is phosphorylated and recruits phosphatases like SHP1 and [[PTPN11|SHP2]].<ref>{{Cite journal|last=Okazawa|first=Hideki|last2=Motegi|first2=Sei-ichiro|last3=Ohyama|first3=Naoko|last4=Ohnishi|first4=Hiroshi|last5=Tomizawa|first5=Takeshi|last6=Kaneko|first6=Yoriaki|last7=Oldenborg|first7=Per-Arne|last8=Ishikawa|first8=Osamu|last9=Matozaki|first9=Takashi|date=2005-02-15|title=Negative regulation of phagocytosis in macrophages by the CD47-SHPS-1 system|journal=Journal of Immunology|volume=174|issue=4|pages=2004–2011|issn=0022-1767|pmid=15699129|doi=10.4049/jimmunol.174.4.2004}}</ref> The extracellular region contains three [[Immunoglobulin superfamily]] domains – single V-set and two C1-set [[Immunoglobulin superfamily|IgSF]] domains. SIRP β and γ have the similar extracellular structure but different cytoplasmic regions giving contrasting types of signals. SIRP α polymorphisms are found in ligand-binding [[Immunoglobulin superfamily|IgSF]] V-set domain but it does not affect ligand binding. One idea is that the polymorphism is important to protect the receptor of pathogens binding.<ref name="pmid19223164"/><ref name="pmid16691243">{{cite journal| vauthors=Barclay AN, Brown MH| title=The SIRP family of receptors and immune regulation. | journal=Nat Rev Immunol | year= 2006 | volume= 6 | issue= 6 | pages= 457–64 | doi=10.1038/nri1859 | pmc= | pmid=16691243  }}</ref>
 == Ligands ==
-SIRPα recognizes [[CD47]], that is an antiphagocytic signal distinguished live cells from dying. CD47 has a single Ig-like extracellular domain and five membrane spanning regions.  Their interaction can be modified also by [[endocytosis]] of the receptor, cleavage or interaction with [[Surfactant protein A|surfactant proteins]]. SIRP α recognize soluble ligands such as [[surfactant protein A]] and [[Surfactant protein D|D]] that bind to the same region as [[CD47]] and block binding of this ligand.<ref name="pmid16691243"/><ref name="pmid16339510">{{cite journal| vauthors=van Beek EM, Cochrane F, Barclay AN, van den Berg TK| title=Signal regulatory proteins in the immune system. | journal=J Immunol | year= 2005 | volume= 175 | issue= 12 | pages= 7781–7 | pmid=16339510 | doi= 10.4049/jimmunol.175.12.7781| pmc= | url=https://www.ncbi.nlm.nih.gov/pubmed/16339510  }}</ref>
+SIRPα recognizes [[CD47]], an anti-phagocytic signal that distinguishes live cells from dying cells. CD47 has a single Ig-like extracellular domain and five membrane spanning regions.  The interaction between SIRPα and CD47 can be modified by [[endocytosis]] or cleavage of the receptor, or interaction with [[Surfactant protein A|surfactant proteins]]. [[Surfactant protein A]] and [[Surfactant protein D|D]] are soluble ligands, highly expressed in the lungs, that bind to the same region of SIRPα as [[CD47]] and can therefore competitively block binding.<ref name="pmid16691243"/><ref name="pmid16339510">{{cite journal| vauthors=van Beek EM, Cochrane F, Barclay AN, van den Berg TK| title=Signal regulatory proteins in the immune system. | journal=J Immunol | year= 2005 | volume= 175 | issue= 12 | pages= 7781–7 | doi= 10.4049/jimmunol.175.12.7781| pmc= | pmid=16339510  }}</ref>
 == Signalization ==
@@ Line 14: / Line 14: @@
 == Cancer ==
-Cancer cells highly expressed [[CD47]] that activate SIRP α and inhibit [[macrophage]]-mediated destruction. In one study, they engineered high-affinity variants of SIRP α that antagonized [[CD47]] on cancer cells and caused increase [[phagocytosis]] of cancer cells.<ref name="pmid23722425">{{cite journal |vauthors=Weiskopf K, Ring AM, Ho CC, Volkmer JP, Levin AM, Volkmer AK, etal | title=Engineered SIRPα variants as immunotherapeutic adjuvants to anticancer antibodies. | journal=Science | year= 2013 | volume= 341 | issue= 6141 | pages= 88–91 | pmid=23722425 | doi=10.1126/science.1238856 | pmc=3810306 }}</ref> Another study (in mice) found anti-SIRPα antibodies helped macrophages to reduce cancer growth and metastasis, alone and in synergy with other cancer treatments.<ref>[https://www.sciencedaily.com/releases/2017/02/170206084054.htm Potential new cancer treatment activates cancer-engulfing cells. Feb 2017]</ref><ref name=Yanagita2017>{{cite journal |title=Anti-SIRPα antibodies as a potential new tool for cancer immunotherapy. |journal=JCI Insight, 2017; 2 (1) |doi=10.1172/jci.insight.89140 |year=2017 |url=https://insight.jci.org/articles/view/89140 |volume=2}}</ref>
+Cancer cells highly expressed [[CD47]] that activate SIRP α and inhibit [[macrophage]]-mediated destruction. In one study, they engineered high-affinity variants of SIRP α that antagonized [[CD47]] on cancer cells and caused increase [[phagocytosis]] of cancer cells.<ref name="pmid23722425">{{cite journal |vauthors=Weiskopf K, Ring AM, Ho CC, Volkmer JP, Levin AM, Volkmer AK, etal | title=Engineered SIRPα variants as immunotherapeutic adjuvants to anticancer antibodies. | journal=Science | year= 2013 | volume= 341 | issue= 6141 | pages= 88–91 | pmid=23722425 | doi=10.1126/science.1238856 | pmc=3810306 }}</ref> Another study (in mice) found anti-SIRPα antibodies helped macrophages to reduce cancer growth and metastasis, alone and in synergy with other cancer treatments.<ref>[https://www.sciencedaily.com/releases/2017/02/170206084054.htm Potential new cancer treatment activates cancer-engulfing cells. Feb 2017]</ref><ref name=Yanagita2017>{{cite journal |title=Anti-SIRPα antibodies as a potential new tool for cancer immunotherapy. |journal=JCI Insight, 2017; 2 (1) |doi=10.1172/jci.insight.89140 |year=2017 |url=https://insight.jci.org/articles/view/89140 |volume=2 |vauthors=Yanagita T|pmc=5214103 }}</ref>
 ==References==
@@ Line 23: / Line 23: @@
 ==Further reading==
 {{refbegin | 2}}
-* {{cite journal |doi=  10.1155/2013/614619 | pmc=3564380 | pmid=23401787 | volume=2013 | title=CD47: A Cell Surface Glycoprotein Which Regulates Multiple Functions of Hematopoietic Cells in Health and Disease | journal=ISRN Hematol | page=614619 | vauthors=Oldenborg PA}}
+* {{cite journal |doi=  10.1155/2013/614619 | pmc=3564380 | pmid=23401787 | volume=2013 | title=CD47: A Cell Surface Glycoprotein Which Regulates Multiple Functions of Hematopoietic Cells in Health and Disease | journal=ISRN Hematol | page=614619 | vauthors=Oldenborg PA | year=2013}}
-* {{cite journal | vauthors = Yamauchi T, Takenaka K, Urata S ''et al'' | year = | title = & Akashi, K. (2013). Polymorphic Sirpa is the genetic determinant for NOD-based mouse lines to achieve efficient human cell engraftment | url = | journal = Blood | volume = 121 | issue = 8| pages = 1316–1325 }}
+* {{cite journal | vauthors = Yamauchi T, Takenaka K, Urata S ''et al'' | year = 2013| title = & Akashi, K. (2013). Polymorphic Sirpa is the genetic determinant for NOD-based mouse lines to achieve efficient human cell engraftment | url = | journal = Blood | volume = 121 | issue = 8| pages = 1316–1325 | doi=10.1182/blood-2012-06-440354}}
 *{{cite journal |author = Oldenborg PA |title = Role of CD47 in erythroid cells and in autoimmunity. |journal = Leuk. Lymphoma |volume = 45 |issue = 7 |pages = 1319–27 |year = 2004 |pmid = 15359629 |doi = 10.1080/1042819042000201989 }}
 *{{cite journal  |vauthors=Margolis RL, Breschel TS, Li SH, etal |title = Characterization of cDNA clones containing CCA trinucleotide repeats derived from human brain. |journal = Somat. Cell Mol. Genet. |volume = 21 |issue = 4 |pages = 279–84 |year = 1996 |pmid = 8525433 |doi = 10.1007/BF02255782 }}

v t e Proteins: clusters of differentiation (see also list of human clusters of differentiation)
1-50	CD1 a-c 1A 1D 1E CD2 CD3 γ δ ε CD4 CD5 CD6 CD7 CD8 a CD9 CD10 CD11 a b c d CD13 CD14 CD15 CD16 A B CD18 CD19 CD20 CD21 CD22 CD23 CD24 CD25 CD26 CD27 CD28 CD29 CD30 CD31 CD32 A B CD33 CD34 CD35 CD36 CD37 CD38 CD39 CD40 CD41 CD42 a b c d CD43 CD44 CD45 CD46 CD47 CD48 CD49 a b c d e f CD50
51-100	CD51 CD52 CD53 CD54 CD55 CD56 CD57 CD58 CD59 CD61 CD62 E L P CD63 CD64 A B C CD66 a b c d e f CD68 CD69 CD70 CD71 CD72 CD73 CD74 CD78 CD79 a b CD80 CD81 CD82 CD83 CD84 CD85 a d e h j k CD86 CD87 CD88 CD89 CD90 CD91 - CD92 CD93 CD94 CD95 CD96 CD97 CD98 CD99 CD100
101-150	CD101 CD102 CD103 CD104 CD105 CD106 CD107 a b CD108 CD109 CD110 CD111 CD112 CD113 CD114 CD115 CD116 CD117 CD118 CD119 CD120 a b CD121 a b CD122 CD123 CD124 CD125 CD126 CD127 CD129 CD130 CD131 CD132 CD133 CD134 CD135 CD136 CD137 CD138 CD140b CD141 CD142 CD143 CD144 CD146 CD147 CD148 CD150
151-200	CD151 CD152 CD153 CD154 CD155 CD156 a b c CD157 CD158 (a d e i k) CD159 a c CD160 CD161 CD162 CD163 CD164 CD166 CD167 a b CD168 CD169 CD170 CD171 CD172 a b g CD174 CD177 CD178 CD179 a b CD180 CD181 CD182 CD183 CD184 CD185 CD186 CD191 CD192 CD193 CD194 CD195 CD196 CD197 CDw198 CDw199 CD200
201-250	CD201 CD202b CD204 CD205 CD206 CD207 CD208 CD209 CDw210 a b CD212 CD213a 1 2 CD217 CD218 (a b) CD220 CD221 CD222 CD223 CD224 CD225 CD226 CD227 CD228 CD229 CD230 CD233 CD234 CD235 a b CD236 CD238 CD239 CD240CE CD240D CD241 CD243 CD244 CD246 CD247 - CD248 CD249
251-300	CD252 CD253 CD254 CD256 CD257 CD258 CD261 CD262 CD263 CD264 CD265 CD266 CD267 CD268 CD269 CD271 CD272 CD273 CD274 CD275 CD276 CD278 CD279 CD280 CD281 CD282 CD283 CD284 CD286 CD288 CD289 CD290 CD292 CDw293 CD294 CD295 CD297 CD298 CD299
301-350	CD300A CD301 CD302 CD303 CD304 CD305 CD306 CD307 CD309 CD312 CD314 CD315 CD316 CD317 CD318 CD320 CD321 CD322 CD324 CD325 CD326 CD328 CD329 CD331 CD332 CD333 CD334 CD335 CD336 CD337 CD338 CD339 CD340 CD344 CD349 CD350