Notch proteins

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Notch proteins are a family of type 1 transmembrane proteins that form a core component of the Notch signaling pathway, which is highly conserved in animals. The Notch extracellular domain mediates interactions with DSL family ligands, allowing it to participate in juxtacrine signaling. The Notch intracellular domain acts as a transcriptional activator when in complex with CSL family transcription factors. Members of this type 1 transmembrane protein family share several core structures, including an extracellular domain consisting of multiple epidermal growth factor (EGF)-like repeats and an intracellular domain transcriptional activation domain (TAD). Notch family members operate in a variety of different tissues and play a role in a variety of developmental processes by controlling cell fate decisions. Much of what is known about Notch function comes from studies done in Caenorhabditis elegans (C.elegans) and Drosophila melanogaster. Human homologs have also been identified, but details of Notch function and interactions with its ligands are not well known in this context.

Notch (LNR) domain
Structure of a prototype LNR module from human Notch 1[1]
Identifiers
SymbolNotch
PfamPF00066
InterProIPR000800
SMARTSM00004
PROSITEPS50258
OPM superfamily462
OPM protein5kzo
Membranome19
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

Discovery

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Notch was discovered in a mutant Drosophila in March 1913 in the lab of Thomas Hunt Morgan.[2] This mutant emerged after several generations of crossing out and back-crossing beaded winged flies with wild type flies and was first characterized by John S. Dexter.[3] The most frequently observed phenotype in Notch mutant flies is the appearance of a concave serration at the most distal end of the wings, for which the gene is named, accompanied by the absence of marginal bristles.[4][5] This mutant was found to be a sex-linked dominant on the X chromosome that could only be observed in heterozygous females as it was lethal in males and homozygous females.[2] The first Notch allele was established in 1917 by C.W. Metz and C.B. Bridges.[6] In the late 1930s, studies of fly embryogenesis done by Donald F. Poulson provided the first indication of Notch's role in development.[7] Notch-8 mutant males exhibited a lack of the inner germ layers, the endoderm and mesoderm, that resulted in failure to undergo later morphogenesis embryonic lethality. Later studies in early Drosophila neurogenesis provided some of the first indications of Notch's roll in cell-cell signaling, as the nervous system in Notch mutants was developed by sacrificing hypodermal cells.[8]

Starting in the 1980s researchers began to gain further insights into Notch function through genetic and molecular experiments. Genetic screens conducted in Drosophila led to the identification of several proteins that play a central role in Notch signaling, including Enhancer of split,[8] Master mind, Delta,[9] Suppressor of Hairless (CSL),[10] and Serrate.[11] At the same time, the Notch gene was successfully sequenced[12][13] and cloned,[14][15] providing insights into the molecular architecture of Notch proteins and led to identification of Notch homologs in Caenorhabditis elegans (C. elegans)[16][17][18] and eventually in mammals.

In the early 1990s Notch was increasingly implicated as the receptor of a previously unknown intercellular signal pathway[19][20] in which the Notch intercellular domain (NICD) is transported to the nucleus where it acts as a transcription factor to directly regulate target genes.[21][22][23] The release of the NICD was found to be as a result of proteolytic cleavage of the transmembrane protein through the actions of the γ-secretase complex catalytic subunit Presenilin. This was a significant interaction as Presenilin is implicated in the development of Alzheimer's disease.[24] This and further research into the mechanism of Notch signaling led to research that would further connect Notch to a wide range of human diseases.

Structure

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Drosophila contain a single Notch protein, C. elegans contain two redundant notch paralogs, Lin-12[25] and GLP-1,[18][26] and humans have four Notch variants, Notch 1-4. Although variations exist between homologs, there are a set of highly conserved structures found in all Notch family proteins. The protein can broadly be split into the Notch extracellular domain (NECD) and Notch intracellular domain (NICD) joined together by a single-pass transmembrane domain (TM).

The NECD contains 36 EGF repeats in Drosophila,[13] 28-36 in humans, and 13 and 10 in C. elegans Lin-12 and GLP-1 respectively.[27] These repeats are heavily modified through O-glycoslyation[28] and the addition of specific O-linked glycans has been shown to be necessary for proper function. The EGF repeats are followed by three cysteine-rich Lin-12/Notch Repeats (LNR) and a heterodimerization (HD) domain. Together the LNR and HD compose the negative regulatory region adjacent to the cell membrane and help prevent signaling in the absence of ligand binding.

NICD acts as a transcription factor that is released after ligand binding triggers its cleavage. It contains a nuclear localization sequence (NLS) that mediates its translocation to the nucleus, where it forms a transcriptional complex along with several other transcription factors. Once in the nucleus, several ankyrin repeats and the RAM domain interactions between the NICD and CSL proteins to form a transcriptional activation complex.[29] In humans, an additional PEST domain plays a role in NICD degradation.[30]

Function

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The Notch signaling pathway. Notch interacts with its ligands Delta or Serrate, leading to cleavage of the NICD which can then interact with Su(H) to form a transcriptional complex.

Notch family members play a role in a variety of developmental processes by controlling cell fate decisions. The Notch signaling network is an evolutionarily conserved intercellular signaling pathway that regulates interactions between physically adjacent cells. In Drosophila, notch interaction with its cell-bound ligands (delta, serrate) establishes an intercellular signaling pathway that plays a key role in development. This protein functions as a receptor for membrane bound ligands, and may play multiple roles during development.[31] A deficiency can be associated with bicuspid aortic valve.[32]

There is evidence that activated Notch 1 and Notch 3 promote differentiation of progenitor cells into astroglia.[33] Notch 1, then activated before birth, induces radial glia differentiation,[34] but postnatally induces the differentiation into astrocytes.[35] One study shows that Notch-1 cascade is activated by Reelin in an unidentified way.[36] Reelin and Notch1 cooperate in the development of the dentate gyrus, according to another.[37]

Ligand interactions

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Jagged/Serrate protein
Identifiers
SymbolDSL
PfamPF01414
InterProIPR026219
Membranome76
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

Notch signaling is triggered via direct cell-to-cell contact, mediated by interactions between the Notch receptor protein in the signal receiving cell and a ligand in an adjacent signal transmitting cell. These type 1 single-pass transmembrane proteins fall into the Delta/Serrate/Lag-2 (DSL) family of proteins which is named after the three canonical Notch ligands.[19] Delta and Serrate are found in Drosophila while Lag-2 is found in C. elegans. Humans contain 3 Delta homologs, Delta-like 1, 3, and 4, as well as two Serrate homologs, Jagged 1 and 2. Notch proteins consist of a relatively short intracellular domain and a large extracellular domain with one or more EGF motifs and a N-terminal DSL-binding motif. EGF repeats 11-12 on the Notch extracellular domain have been shown to be necessary and sufficient for trans signaling interactions between Notch and its ligands.[38] Additionally, EGF repeats 24-29 have been implicated in inhibition of cis interactions between Notch and ligands co-expressed in the same cell.[39]

Proteolysis

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In order for a signaling event to occur, the Notch protein must be cleaved at several sites. In humans, Notch is first cleaved in the NRR domain by furin while being processed in the trans-Golgi network before being presented on the cell surface as a heterodimer.[40][41] Drosophila Notch does not require this cleavage for signaling to occur,[42] and there is some evidence that suggests that LIN-12 and GLP-1 are cleaved at this site in C. elegans.

Release of the NICD is achieved after an additional two cleavage events to Notch. Binding of Notch to a DSL ligand results in a conformational change that exposes a cleavage site in the NECD. Enzymatic proteolysis at this site is carried out by a A Disintegrin and Metalloprotease domain (ADAM) family protease. This protein is called Kuzbanian in Drosophila,[43][44] sup-17 in C. elegans,[45] and ADAM10 in humans.[46][47] After proteolytic cleavage, the released NECD is endocytosed into the signal transmitting cell, leaving behind only a small extracellular portion of Notch. This truncated Notch protein can then be recognized by a γ-secretase that cleaves the third site found in the TM domain.[48]

Human homologs

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Notch-1

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Notch-2

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Notch-2 (Neurogenic locus notch homolog protein 2) is a protein that in humans is encoded by the NOTCH2 gene.[49]

NOTCH2 is associated with Alagille syndrome[50] and Hajdu–Cheney syndrome.[51]

Notch-3

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Notch-4

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See also

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Notes

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  1. ^ Vardar D, North CL, Sanchez-Irizarry C, Aster JC, Blacklow SC (June 2003). "Nuclear magnetic resonance structure of a prototype Lin12-Notch repeat module from human Notch1". Biochemistry. 42 (23): 7061–7. doi:10.1021/bi034156y. PMID 12795601.
  2. ^ a b Morgan TH, Bridges CB (1916). Sex-linked inheritance in Drosophila. NCSU Libraries. Washington, Carnegie Institution of Washington.
  3. ^ Dexter JS (December 1914). "The Analysis of a Case of Continuous Variation in Drosophila by a Study of Its Linkage Relations". The American Naturalist. 48 (576): 712–758. doi:10.1086/279446. hdl:2027/nnc1.cu56096100.
  4. ^ Mohr OL (May 1919). "Character Changes Caused by Mutation of an Entire Region of a Chromosome in Drosophila". Genetics. 4 (3): 275–82. doi:10.1093/genetics/4.3.275. PMC 1200460. PMID 17245926.
  5. ^ Lindsley DL, Zimm GG (2012-12-02). The Genome of Drosophila Melanogaster. Academic Press. ISBN 9780323139847.
  6. ^ Metz CW, Bridges CB (December 1917). "Incompatibility of Mutant Races in Drosophila". Proceedings of the National Academy of Sciences of the United States of America. 3 (12): 673–8. Bibcode:1917PNAS....3..673M. doi:10.1073/pnas.3.12.673. PMC 1091355. PMID 16586764.
  7. ^ Poulson DF (March 1937). "Chromosomal Deficiencies and the Embryonic Development of Drosophila Melanogaster". Proceedings of the National Academy of Sciences of the United States of America. 23 (3): 133–7. Bibcode:1937PNAS...23..133P. doi:10.1073/pnas.23.3.133. PMC 1076884. PMID 16588136.
  8. ^ a b Lehmann R, Jiménez F, Dietrich U, Campos-Ortega JA (March 1983). "On the phenotype and development of mutants of early neurogenesis inDrosophila melanogaster". Wilhelm Roux's Archives of Developmental Biology. 192 (2): 62–74. doi:10.1007/BF00848482. PMID 28305500. S2CID 25602190.
  9. ^ Lehmann R, Dietrich U, Jiménez F, Campos-Ortega JA (July 1981). "Mutations of early neurogenesis inDrosophila". Wilhelm Roux's Archives of Developmental Biology. 190 (4): 226–229. doi:10.1007/BF00848307. PMID 28305572. S2CID 21814447.
  10. ^ Fortini ME, Artavanis-Tsakonas S (October 1994). "The suppressor of hairless protein participates in notch receptor signaling". Cell. 79 (2): 273–82. doi:10.1016/0092-8674(94)90196-1. PMID 7954795. S2CID 40771329.
  11. ^ Fleming RJ, Scottgale TN, Diederich RJ, Artavanis-Tsakonas S (December 1990). "The gene Serrate encodes a putative EGF-like transmembrane protein essential for proper ectodermal development in Drosophila melanogaster". Genes & Development. 4 (12A): 2188–201. doi:10.1101/gad.4.12a.2188. PMID 2125287.
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  29. ^ Tamura K, Taniguchi Y, Minoguchi S, Sakai T, Tun T, Furukawa T, Honjo T (December 1995). "Physical interaction between a novel domain of the receptor Notch and the transcription factor RBP-J kappa/Su(H)". Current Biology. 5 (12): 1416–23. doi:10.1016/S0960-9822(95)00279-X. hdl:2433/202204. PMID 8749394. S2CID 18442572.
  30. ^ Weng AP, Ferrando AA, Lee W, Morris JP, Silverman LB, Sanchez-Irizarry C, et al. (October 2004). "Activating mutations of NOTCH1 in human T cell acute lymphoblastic leukemia". Science. 306 (5694): 269–71. Bibcode:2004Sci...306..269W. doi:10.1126/science.1102160. PMID 15472075. S2CID 24049536.
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  33. ^ Tanigaki K, Nogaki F, Takahashi J, Tashiro K, Kurooka H, Honjo T (January 2001). "Notch1 and Notch3 instructively restrict bFGF-responsive multipotent neural progenitor cells to an astroglial fate". Neuron. 29 (1): 45–55. doi:10.1016/S0896-6273(01)00179-9. hdl:2433/150564. PMID 11182080. S2CID 17047028.
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  35. ^ Chambers CB, Peng Y, Nguyen H, Gaiano N, Fishell G, Nye JS (March 2001). "Spatiotemporal selectivity of response to Notch1 signals in mammalian forebrain precursors". Development. 128 (5): 689–702. doi:10.1242/dev.128.5.689. PMID 11171394.
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  50. ^ Samejima H, Torii C, Kosaki R, Kurosawa K, Yoshihashi H, Muroya K, Okamoto N, Watanabe Y, Kosho T, Kubota M, Matsuda O, Goto M, Izumi K, Takahashi T, Kosaki K (2007). "Screening for Alagille syndrome mutations in the JAG1 and NOTCH2 genes using denaturing high-performance liquid chromatography". Genetic Testing. 11 (3): 216–27. doi:10.1089/gte.2006.0519. PMID 17949281.
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References

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This article incorporates text from the public domain Pfam and InterPro: IPR000800