Jump to content

英文维基 | 中文维基 | 日文维基 | 草榴社区

GLI2

From Wikipedia, the free encyclopedia
GLI2
Identifiers
AliasesGLI2, CJS, HPE9, PHS2, THP1, THP2, GLI family zinc finger 2
External IDsOMIM: 165230; MGI: 95728; HomoloGene: 12725; GeneCards: GLI2; OMA:GLI2 - orthologs
Orthologs
SpeciesHumanMouse
Entrez
Ensembl
UniProt
RefSeq (mRNA)

NM_001081125

RefSeq (protein)

NP_005261
NP_001358200
NP_001361282
NP_001361283

NP_001074594

Location (UCSC)Chr 2: 120.74 – 120.99 MbChr 1: 118.76 – 118.98 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

Zinc finger protein GLI2 also known as GLI family zinc finger 2 is a protein that in humans is encoded by the GLI2 gene.[5] The protein encoded by this gene is a transcription factor.[6]

GLI2 belongs to the C2H2-type zinc finger protein subclass of the Gli family. Members of this subclass are characterized as transcription factors which bind DNA through zinc finger motifs. These motifs contain conserved H-C links. Gli family zinc finger proteins are mediators of Sonic hedgehog (Shh) signaling and they are implicated as potent oncogenes in the embryonal carcinoma cell. The protein encoded by this gene localizes to the cytoplasm and activates patched Drosophila homolog (PTCH) gene expression. It is also thought to play a role during embryogenesis.[7]

Isoforms

[edit]

There are four isoforms: Gli2 alpha, beta, gamma and delta.[8]

Structure

[edit]

C-terminal activator and N-terminal repressor regions have been identified in both Gli2 and Gli3.[9] However, the N-terminal part of human Gli2 is much smaller than its mouse or frog homologs, suggesting that it may lack repressor function.

Function

[edit]

Gli2 affects ventroposterior mesodermal development by regulating at least three different genes; Wnt genes involved in morphogenesis, Brachyury genes involved in tissue specification and Xhox3 genes involved in positional information.[10] The anti-apoptotic protein BCL-2 is up regulated by Gli2 and, to a lesser extent, Gli1 – but not Gli3, which may lead to carcinogenesis.[11] Additionally, in the amphibian model organism Xenopus laevis, it has been shown that Gli2 plays a key role in the induction, specification, migration and differentiation of the neural crest.[12] In this context, Gli2 is responding to the Indian Hedgehog signaling pathway.[13]

It has been shown in mouse models that Gli1 can compensate for knocked out Gli2 function when expressed from the Gli2 locus. This suggests that in mouse embryogenesis, Gli1 and Gli2 regulate a similar set of target genes. Mutations do develop later in development suggesting Gli1/Gli2 transcriptional regulation is context dependent.[11] Gli2 and Gli3 are important in the formation and development of lung, trachea and oesophagus tissue during embryo development.[14] Studies have also shown that GLI2 plays a dual role as activator of keratinocyte proliferation and repressor of epidermal differentiation.[15] There is a significant level of crosstalk and functional overlap between the Gli TFs. Gli2 has been shown to compensate for the loss of Gli1 in transgenic Gli1-/- mice which are phenotypically normal.[14] However, loss of Gli3 leads to abnormal patterning and loss of Gli2 affects the development of ventral cell types, most significantly in the floor plate. Gli2 has been shown to compensate for Gli1 ventrally and Gli3 dorsally in transgenic mice.[16] Gli2 null mice embryos develop neural tube defects which, can be rescued by overexpression of Gli1 (Jacob and Briscoe, 2003). Gli1 has been shown to induce the two GLI2 α/β isoforms.

Transgenic double homozygous Gli1-/- and Gli2-/- knockout mice display serious central nervous system and lung defects have small lungs, undescended testes, and a hopping gait as well as an extra postaxial nubbin on the limbs.[17] Gli2-/- and Gli3-/- double homozygous transgenic mice are not viable and do not survive beyond embryonic level.[14][18][19] These studies suggest overlapping roles for Gli1 with Gli2 and Gli2 with Gli3 in embryonic development.

Transgenic Gli1-/- and Gli2-/- mice have a similar phenotype to transgenic Gli1 gain of function mice. This phenotype includes failure to thrive, early death, and a distended gut although no tumors form in transgenic Gli1-/- and Gli2-/- mice. This could suggest that overexpression of human Gli1 in the mouse may have led to a dominant negative rather than a gain-of-function phenotype.[20]

Transgenic mice over-expressing the transcription factor Gli2 under the K5 promoter in cutaneous keratinocytes develop multiple skin tumours on the ears, tail, trunk and dorsal aspect of the paw, resembling those of basal cell carcinoma (BCC). Unlike Gli1 transgenic mice, Gli2 transgenic mice only developed BCC-like tumors. Transgenic mice with N-terminal deletion of Gli2, developed the benign trichoblastomas, cylindromas and hamartomas but rarely developed BCCs.[21] Gli2 is expressed in the interfollicular epidermis and the outer root sheath of hair follicles in normal human skin. This is significant as Shh regulates hair follicle growth and morphogenesis. When inappropriately activated causes hair follicle derived tumors, the most clinically significant being the BCC.[22]

Of the four Gli2 isoforms the expression of Gli2beta mRNA was increased the most in BCCs. Gli2beta is an isoform spliced at the first splicing site which contains a repression domain and consists of an intact activation domain. Overexpression of this Gli2 splice variant may lead to the upregulation of the Shh signalling pathway, thereby inducing BCCs.[8]

Clinical significance

[edit]

Mutations of the GLI2 gene are associated with midline craniofacial anomalies, hypopituitarism, and sometimes holoprosencephaly (https://omim.org/entry/165230, Holoprosencephaly 9, Culler-Jones syndrome) [7]

In human keratinocytes Gli2 activation upregulates a number of genes involved in cell cycle progression including E2F1, CCND1, CDC2 and CDC45L. Gli2 is able to induce G1–S phase progression in contact-inhibited keratinocytes which may drive tumour development.[15]

Although both Gli1 and Gl12 have been implicated it is unclear whether one or both are needed for carcinogenesis. However, due to feed back loops, one may directly or indirectly induce the other.

Cis-regulatory catalog of GLI2

[edit]

Minhas et al. 2015 have recently elucidated a subset of cis-regulatory elements controlling GLI2 expression. They have shown that conserved non-coding elements (CNEs) from the intron of GLI2 gene act as tissue-specific enhancers and reporter gene expression induced by these elements correlates with previously reported endogenous gli2 expression in zebrafish. The regulatory activities of these elements are observed in several embryonic domains, including neural tube and pectoral fin.[23]

References

[edit]
  1. ^ a b c GRCh38: Ensembl release 89: ENSG00000074047Ensembl, May 2017
  2. ^ a b c GRCm38: Ensembl release 89: ENSMUSG00000048402Ensembl, May 2017
  3. ^ "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  4. ^ "Mouse PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
  5. ^ Tanimura A, Dan S, Yoshida M (May 1998). "Cloning of novel isoforms of the human Gli2 oncogene and their activities to enhance tax-dependent transcription of the human T-cell leukemia virus type 1 genome". Journal of Virology. 72 (5): 3958–64. doi:10.1128/JVI.72.5.3958-3964.1998. PMC 109622. PMID 9557682.
  6. ^ Ruppert JM, Kinzler KW, Wong AJ, Bigner SH, Kao FT, Law ML, Seuanez HN, O'Brien SJ, Vogelstein B (August 1988). "The GLI-Kruppel family of human genes". Molecular and Cellular Biology. 8 (8): 3104–13. doi:10.1128/mcb.8.8.3104. PMC 363537. PMID 2850480.
  7. ^ a b "Entrez Gene: GLI family zinc finger 2".
  8. ^ a b Tojo M, Kiyosawa H, Iwatsuki K, Nakamura K, Kaneko F (May 2003). "Expression of the GLI2 oncogene and its isoforms in human basal cell carcinoma". The British Journal of Dermatology. 148 (5): 892–7. doi:10.1046/j.1365-2133.2003.05284.x. PMID 12786818. S2CID 23655947.
  9. ^ Sasaki H, Nishizaki Y, Hui C, Nakafuku M, Kondoh H (September 1999). "Regulation of Gli2 and Gli3 activities by an amino-terminal repression domain: implication of Gli2 and Gli3 as primary mediators of Shh signaling". Development. 126 (17): 3915–24. doi:10.1242/dev.126.17.3915. PMID 10433919.
  10. ^ Brewster R, Mullor JL, Ruiz i Altaba A (October 2000). "Gli2 functions in FGF signaling during antero-posterior patterning". Development. 127 (20): 4395–405. doi:10.1242/dev.127.20.4395. PMID 11003839.
  11. ^ a b Regl G, Kasper M, Schnidar H, Eichberger T, Neill GW, Philpott MP, Esterbauer H, Hauser-Kronberger C, Frischauf AM, Aberger F (November 2004). "Activation of the BCL2 promoter in response to Hedgehog/GLI signal transduction is predominantly mediated by GLI2". Cancer Research. 64 (21): 7724–31. doi:10.1158/0008-5472.CAN-04-1085. PMID 15520176.
  12. ^ Cerrizuela S, Vega-López GA, Palacio MB, Tríbulo C, Aybar MJ (August 2018). "Gli2 is required for the induction and migration of Xenopus laevis neural crest". Mechanisms of Development. 154: 219–239. doi:10.1016/j.mod.2018.07.010. hdl:11336/101714. PMID 30086335.
  13. ^ Agüero TH, Fernández JP, López GA, Tríbulo C, Aybar MJ (April 2012). "Indian hedgehog signaling is required for proper formation, maintenance and migration of Xenopus neural crest". Developmental Biology. 364 (2): 99–113. doi:10.1016/j.ydbio.2012.01.020. hdl:11336/60718. PMID 22309705.
  14. ^ a b c Motoyama J, Liu J, Mo R, Ding Q, Post M, Hui CC (September 1998). "Essential function of Gli2 and Gli3 in the formation of lung, trachea and oesophagus". Nature Genetics. 20 (1): 54–7. doi:10.1038/1711. PMID 9731531. S2CID 195211836.
  15. ^ a b Regl G, Kasper M, Schnidar H, Eichberger T, Neill GW, Ikram MS, Quinn AG, Philpott MP, Frischauf AM, Aberger F (February 2004). "The zinc-finger transcription factor GLI2 antagonizes contact inhibition and differentiation of human epidermal cells". Oncogene. 23 (6): 1263–74. doi:10.1038/sj.onc.1207240. PMID 14691458. S2CID 23702873.
  16. ^ Litingtung Y, Chiang C (October 2000). "Specification of ventral neuron types is mediated by an antagonistic interaction between Shh and Gli3". Nature Neuroscience. 3 (10): 979–85. doi:10.1038/79916. PMID 11017169. S2CID 10102370.
  17. ^ Park HL, Bai C, Platt KA, Matise MP, Beeghly A, Hui CC, Nakashima M, Joyner AL (April 2000). "Mouse Gli1 mutants are viable but have defects in SHH signaling in combination with a Gli2 mutation". Development. 127 (8): 1593–605. doi:10.1242/dev.127.8.1593. PMID 10725236.
  18. ^ Mo R, Freer AM, Zinyk DL, Crackower MA, Michaud J, Heng HH, Chik KW, Shi XM, Tsui LC, Cheng SH, Joyner AL, Hui C (January 1997). "Specific and redundant functions of Gli2 and Gli3 zinc finger genes in skeletal patterning and development". Development. 124 (1): 113–23. doi:10.1242/dev.124.1.113. PMID 9006072.
  19. ^ Hardcastle Z, Mo R, Hui CC, Sharpe PT (August 1998). "The Shh signalling pathway in tooth development: defects in Gli2 and Gli3 mutants". Development. 125 (15): 2803–11. doi:10.1242/dev.125.15.2803. PMID 9655803.
  20. ^ Yang JT, Liu CZ, Villavicencio EH, Yoon JW, Walterhouse D, Iannaccone PM (December 1997). "Expression of human GLI in mice results in failure to thrive, early death, and patchy Hirschsprung-like gastrointestinal dilatation". Molecular Medicine. 3 (12): 826–35. doi:10.1007/bf03401719. PMC 2230283. PMID 9440116.
  21. ^ Sheng H, Goich S, Wang A, Grachtchouk M, Lowe L, Mo R, Lin K, de Sauvage FJ, Sasaki H, Hui CC, Dlugosz AA (September 2002). "Dissecting the oncogenic potential of Gli2: deletion of an NH(2)-terminal fragment alters skin tumor phenotype". Cancer Research. 62 (18): 5308–16. PMID 12235001.
  22. ^ Oro AE, Higgins K (March 2003). "Hair cycle regulation of Hedgehog signal reception". Developmental Biology. 255 (2): 238–48. doi:10.1016/S0012-1606(02)00042-8. PMID 12648487.
  23. ^ Minhas R, Pauls S, Ali S, Doglio L, Khan MR, Elgar G, Abbasi AA (May 2015). "Cis-regulatory control of human GLI2 expression in the developing neural tube and limb bud". Developmental Dynamics. 244 (5): 681–92. doi:10.1002/dvdy.24266. PMID 25715918. S2CID 6566275.
[edit]

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