GLI3 Gene: Comparison
Please note this is a comparison between Version 2 by Dean Liu and Version 1 by Dean Liu.

GLI family zinc finger 3

  • genes

1. Normal Function

The GLI3 gene belongs to a family of genes that are involved in the normal shaping (patterning) of many tissues and organs during the early stages of development before birth. To carry out this role, proteins produced from genes in the GLI family attach to specific regions of DNA and help control whether particular genes are turned on or off (gene expression). GLI proteins are called transcription factors on the basis of this action.

Proteins in the GLI family function in the same molecular pathway as a protein called Sonic Hedgehog. This pathway is essential for early development. It plays a role in cell growth, cell specialization, and the patterning of structures such as the brain and limbs. Depending on signals from Sonic Hedgehog, the GLI3 protein can either turn on (activate) or turn off (repress) other genes. Researchers are working to identify the genes targeted by the GLI3 protein during development.

2. Health Conditions Related to Genetic Changes

2.1. Acrocallosal sSyndrome

At least two mutations in the GLI3 gene have been reported in people with features of acrocallosal syndrome, a rare condition characterized by certain brain abnormalities, extra fingers and toes (polydactyly), and distinctive facial features, including widely spaced eyes (hypertelorism) and a prominent forehead. These signs and symptoms overlap significantly with those of Greig cephalopolysyndactyly syndrome (described below), so acrocallosal syndrome resulting from GLI3 gene mutations is sometimes considered a severe form of that condition.

At least two mutations in the GLI3 gene have been reported in people with features of acrocallosal syndrome, a rare condition characterized by certain brain abnormalities, extra fingers and toes (polydactyly), and distinctive facial features, including widely spaced eyes (hypertelorism) and a prominent forehead. These signs and symptoms overlap significantly with those of Greig cephalopolysyndactyly syndrome (described below), so acrocallosal syndrome resulting from GLI3 gene mutations is sometimes considered a severe form of that condition.

The GLI3 gene mutations that cause acrocallosal syndrome change single protein building blocks (amino acids) in a particular region of the GLI3 protein, which disrupts the protein's function. The malfunctioning protein likely alters the expression of certain genes during early development. The role of the GLI3 protein in brain and limb patterning may help explain why mutations lead to brain abnormalities, polydactyly, and the other features of acrocallosal syndrome.

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2.2. Greig cephalopolysyndactyly sSyndrome

At least 120 mutations in the GLI3 gene have been identified in people with Greig cephalopolysyndactyly syndrome, which is a rare condition characterized by polydactyly, hypertelorism, a broad forehead, and an unusually large head (macrocephaly). The genetic changes associated with Greig cephalopolysyndactyly syndrome include insertions or deletions of a small amount of DNA and changes in single DNA building blocks (base pairs) in critical regions of the gene. This condition can also be caused by chromosomal abnormalities involving the region of chromosome 7 that contains the GLI3 gene. The genetic changes that cause Greig cephalopolysyndactyly syndrome prevent one copy of the gene in each cell from producing any functional GLI3 protein. As a result, only half the normal amount of this protein is available to control the expression of target genes during early development. It remains unclear how a reduced amount of the GLI3 protein disrupts development of the limbs, head, and face and causes the specific features of Greig cephalopolysyndactyly syndrome.

At least 120 mutations in the GLI3 gene have been identified in people with Greig cephalopolysyndactyly syndrome, which is a rare condition characterized by polydactyly, hypertelorism, a broad forehead, and an unusually large head (macrocephaly). The genetic changes associated with Greig cephalopolysyndactyly syndrome include insertions or deletions of a small amount of DNA and changes in single DNA building blocks (base pairs) in critical regions of the gene. This condition can also be caused by chromosomal abnormalities involving the region of chromosome 7 that contains the GLI3 gene. The genetic changes that cause Greig cephalopolysyndactyly syndrome prevent one copy of the gene in each cell from producing any functional GLI3 protein. As a result, only half the normal amount of this protein is available to control the expression of target genes during early development. It remains unclear how a reduced amount of the GLI3 protein disrupts development of the limbs, head, and face and causes the specific features of Greig cephalopolysyndactyly syndrome.

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2.3. Pallister-Hall sSyndrome

More than 40 mutations in the GLI3 gene have been found to cause Pallister-Hall syndrome, a rare condition whose major features include polydactyly, an abnormal growth in the brain called a hypothalamic hamartoma, and a malformation of the airway called a bifid epiglottis. Most of the mutations that cause Pallister-Hall syndrome occur near the middle of the gene, creating a premature stop signal in the instructions for making the GLI3 protein. As a result, cells produce an unusually short version of the protein. Unlike the full-length GLI3 protein, which can turn target genes on or off, the short protein can only repress the expression of target genes. Although this change clearly disrupts embryonic development, it is not known how the altered function of the GLI3 protein leads to the varied signs and symptoms of Pallister-Hall syndrome.

More About This Health Condition

More than 40 mutations in the GLI3 gene have been found to cause Pallister-Hall syndrome, a rare condition whose major features include polydactyly, an abnormal growth in the brain called a hypothalamic hamartoma, and a malformation of the airway called a bifid epiglottis. Most of the mutations that cause Pallister-Hall syndrome occur near the middle of the gene, creating a premature stop signal in the instructions for making the GLI3 protein. As a result, cells produce an unusually short version of the protein. Unlike the full-length GLI3 protein, which can turn target genes on or off, the short protein can only repress the expression of target genes. Although this change clearly disrupts embryonic development, it is not known how the altered function of the GLI3 protein leads to the varied signs and symptoms of Pallister-Hall syndrome.More About This Health Condition

2.4. Other dDisorders

Mutations in the GLI3 gene have been found in people who have polydactyly without the other features of acrocallosal syndrome, Greig cephalopolysyndactyly syndrome, or Pallister-Hall syndrome (described above). These cases are described as isolated or nonsyndromic because the polydactyly occurs without other signs and symptoms. GLI3 gene mutations can cause several forms of isolated polydactyly. These include postaxial polydactyly type A (PAP-A) and type A/B (PAP-A/B), which are characterized by an extra digit next to the little finger or the small toe. GLI3 gene mutations can also cause preaxial polydactyly type IV (PPD-IV), which is characterized by extra digits next to the thumb or big toe (hallux) and fused skin between some fingers and toes (cutaneous syndactyly). PPD-IV also can include extra digits in other positions on the hands or feet. The pattern of polydactyly seen with PPD-IV is similar to that of Greig cephalopolysyndactyly syndrome, and some researchers suggest that PPD-IV may be a very mild form of that syndrome.

Mutations in the GLI3 gene have been found in people who have polydactyly without the other features of acrocallosal syndrome, Greig cephalopolysyndactyly syndrome, or Pallister-Hall syndrome (described above). These cases are described as isolated or nonsyndromic because the polydactyly occurs without other signs and symptoms. GLI3 gene mutations can cause several forms of isolated polydactyly. These include postaxial polydactyly type A (PAP-A) and type A/B (PAP-A/B), which are characterized by an extra digit next to the little finger or the small toe. GLI3 gene mutations can also cause preaxial polydactyly type IV (PPD-IV), which is characterized by extra digits next to the thumb or big toe (hallux) and fused skin between some fingers and toes (cutaneous syndactyly). PPD-IV also can include extra digits in other positions on the hands or feet. The pattern of polydactyly seen with PPD-IV is similar to that of Greig cephalopolysyndactyly syndrome, and some researchers suggest that PPD-IV may be a very mild form of that syndrome.

3. Other Names for This Gene

  • ACLS
  • GCPS
  • GLI-Kruppel family member GLI3 (Greig cephalopolysyndactyly syndrome)
  • GLI3_HUMAN
  • oncogene GLI3
  • PPDIV
  • zinc finger protein GLI3
  • ACLS

  • GCPS

  • PAP-A
  • oncogene GLI3

  • PAPA
  • PAPA1
  • PAPB
  • PHS
  • GLI-Kruppel family member GLI3 (Greig cephalopolysyndactyly syndrome)

  • GLI3_HUMAN

  • PAP-A

  • PAPA

  • PAPA1

  • PAPB

  • PHS

  • PPDIV

  • zinc finger protein GLI3

References

  1. Biesecker LG, Johnston J. Syndromic and non-syndromic GLI3 phenotypes. ClinGenet. 2005 Sep;68(3):284; author reply 285.
  2. Biesecker LG, Johnston JJ. Greig Cephalopolysyndactyly Syndrome. 2001 Jul 9[updated 2020 May 7]. In: Adam MP, Ardinger HH, Pagon RA, Wallace SE, Bean LJH,Stephens K, Amemiya A, editors. GeneReviews® [Internet]. Seattle (WA): Universityof Washington, Seattle; 1993-2020. Available fromhttp://www.ncbi.nlm.nih.gov/books/NBK1446/
  3. Biesecker LG. Pallister-Hall Syndrome. 2000 May 25 [updated 2017 May 18]. In: Adam MP, Ardinger HH, Pagon RA, Wallace SE, Bean LJH, Stephens K, Amemiya A,editors. GeneReviews® [Internet]. Seattle (WA): University of Washington,Seattle; 1993-2020. Available from http://www.ncbi.nlm.nih.gov/books/NBK1465/
  4. Démurger F, Ichkou A, Mougou-Zerelli S, Le Merrer M, Goudefroye G, DelezoideAL, Quélin C, Manouvrier S, Baujat G, Fradin M, Pasquier L, Megarbané A, FaivreL, Baumann C, Nampoothiri S, Roume J, Isidor B, Lacombe D, Delrue MA, Mercier S, Philip N, Schaefer E, Holder M, Krause A, Laffargue F, Sinico M, Amram D, AndréG, Liquier A, Rossi M, Amiel J, Giuliano F, Boute O, Dieux-Coeslier A, JacquemontML, Afenjar A, Van Maldergem L, Lackmy-Port-Lis M, Vincent-Delorme C, Chauvet ML,Cormier-Daire V, Devisme L, Geneviève D, Munnich A, Viot G, Raoul O, Romana S,Gonzales M, Encha-Razavi F, Odent S, Vekemans M, Attie-Bitach T. New insightsinto genotype-phenotype correlation for GLI3 mutations. Eur J Hum Genet. 2015Jan;23(1):92-102. doi: 10.1038/ejhg.2014.62.
  5. Elson E, Perveen R, Donnai D, Wall S, Black GC. De novo GLI3 mutation inacrocallosal syndrome: broadening the phenotypic spectrum of GLI3 defects andoverlap with murine models. J Med Genet. 2002 Nov;39(11):804-6.
  6. Johnston JJ, Olivos-Glander I, Killoran C, Elson E, Turner JT, Peters KF,Abbott MH, Aughton DJ, Aylsworth AS, Bamshad MJ, Booth C, Curry CJ, David A,Dinulos MB, Flannery DB, Fox MA, Graham JM, Grange DK, Guttmacher AE, HannibalMC, Henn W, Hennekam RC, Holmes LB, Hoyme HE, Leppig KA, Lin AE, Macleod P,Manchester DK, Marcelis C, Mazzanti L, McCann E, McDonald MT, Mendelsohn NJ,Moeschler JB, Moghaddam B, Neri G, Newbury-Ecob R, Pagon RA, Phillips JA, Sadler LS, Stoler JM, Tilstra D, Walsh Vockley CM, Zackai EH, Zadeh TM, Brueton L, BlackGC, Biesecker LG. Molecular and clinical analyses of Greig cephalopolysyndactyly and Pallister-Hall syndromes: robust phenotype prediction from the type andposition of GLI3 mutations. Am J Hum Genet. 2005 Apr;76(4):609-22.
  7. Johnston JJ, Sapp JC, Turner JT, Amor D, Aftimos S, Aleck KA, Bocian M,Bodurtha JN, Cox GF, Curry CJ, Day R, Donnai D, Field M, Fujiwara I, Gabbett M,Gal M, Graham JM, Hedera P, Hennekam RC, Hersh JH, Hopkin RJ, Kayserili H, KiddAM, Kimonis V, Lin AE, Lynch SA, Maisenbacher M, Mansour S, McGaughran J, MehtaL, Murphy H, Raygada M, Robin NH, Rope AF, Rosenbaum KN, Schaefer GB, Shealy A,Smith W, Soller M, Sommer A, Stalker HJ, Steiner B, Stephan MJ, Tilstra D,Tomkins S, Trapane P, Tsai AC, Van Allen MI, Vasudevan PC, Zabel B, Zunich J,Black GC, Biesecker LG. Molecular analysis expands the spectrum of phenotypesassociated with GLI3 mutations. Hum Mutat. 2010 Oct;31(10):1142-54. doi:10.1002/humu.21328.
  8. Kang S, Graham JM Jr, Olney AH, Biesecker LG. GLI3 frameshift mutations cause autosomal dominant Pallister-Hall syndrome. Nat Genet. 1997 Mar;15(3):266-8.
  9. Kang S, Rosenberg M, Ko VD, Biesecker LG. Gene structure and allelicexpression assay of the human GLI3 gene. Hum Genet. 1997 Dec;101(2):154-7.
  10. Radhakrishna U, Bornholdt D, Scott HS, Patel UC, Rossier C, Engel H, BottaniA, Chandal D, Blouin JL, Solanki JV, Grzeschik KH, Antonarakis SE. The phenotypicspectrum of GLI3 morphopathies includes autosomal dominant preaxial polydactylytype-IV and postaxial polydactyly type-A/B; No phenotype prediction from theposition of GLI3 mutations. Am J Hum Genet. 1999 Sep;65(3):645-55.
  11. Speksnijder L, Cohen-Overbeek TE, Knapen MF, Lunshof SM, Hoogeboom AJ, van denOuwenland AM, de Coo IF, Lequin MH, Bolz HJ, Bergmann C, Biesecker LG, WillemsPJ, Wessels MW. A de novo GLI3 mutation in a patient with acrocallosal syndrome. Am J Med Genet A. 2013 Jun;161A(6):1394-400. doi: 10.1002/ajmg.a.35874.
  12. Wild A, Kalff-Suske M, Vortkamp A, Bornholdt D, König R, Grzeschik KH. Pointmutations in human GLI3 cause Greig syndrome. Hum Mol Genet. 1997Oct;6(11):1979-84.
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