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United States divorcee whose marriage to Edward VIII created a constitutional crisis leading to his abdication (同)Mrs. Simpson, Wallis Warfield Simpson, Wallis Warfield Windsor, Duchess of Windsor
Scottish obstetrician and surgeon who pioneered in the use of ether and discovered the anesthetic effects of chloroform (1811-1870) (同)Sir James Young Simpson
a pattern of symptoms indicative of some disease
a complex of concurrent things; "every word has a syndrome of meanings"

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(疾患の徴候となる一群の)症徴候,症候群 / (事件・社会的状態などのパターンを示す)徴候形態

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出典(authority):フリー百科事典『ウィキペディア（Wikipedia）』「2016/09/29 00:59:56」(JST)

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Simpson–Golabi–Behmel syndrome (SGBS), also called Bulldog syndrome, Sara Agers syndrome, Golabi–Rosen syndrome, Simpson dysmorphia syndrome (SDYS) or X-linked dysplasia gigantism syndrome (DGSX),^[1] is a rare inherited congenital disorder that can cause craniofacial, skeletal, cardiac, and renal abnormalities. The syndrome is inherited in an X-linked recessive fashion,^[2] where males express the phenotype and females usually do not. Females that possess one copy of the mutation are considered to be carriers of the syndrome and may express varying degrees of the phenotype.

There are two types of SGBS, each found on a different gene:

Type	OMIM	Gene	Locus
SGBS1	312870	GPC3	Xq26
SGBS2	300209	CXORF5	Xp22

SGBS is also considered to be an overgrowth syndrome (OGS). OGS is characterized by a 2-3 standard deviation increase in weight, height, or head circumference above the average for sex and age. One of the most noted features of OGS is the increased risk of neoplasms in certain OGSs. SGBS in particular has been found to have a 10% tumor predisposition frequency with 94% of cases occurring in the abdominal region, most being malignant. It is common for tumors to be embryonal in type and appear before the age of 10. There are five different types of tumors that patients with SGBS might develop, all intra-abdominal: Wilms tumor, Hepatoblastoma, Hepatocarcinoma, Gonadoblastoma, and Neuroblastoma. The most common types of tumors developed in patients are the Wilms tumor and hepatoblastoma.^[3]

Causes

Although not all causes of SGBS have been identified, one cause of SGBS type I is a mutation of the glypican-3 gene (GPC3) on the X chromosome locus q26.1. This particular gene is widely expressed, especially in tissues derived from the mesoderm during fetal development. The function of this gene is to produce a protein that acts as a cell surface receptor that binds to transcription factors. Binding of the transcription factors allows regulation of cellular responses to growth factors such as members of the hedgehog protein family. When large or small deletions and missense mutations occur along the GPC3 gene, GPC3 can no longer negatively regulate Hedgehog signaling during development, therefore increasing cell proliferation and the risk of developing cancer.^[4] Limb patterning and skeletal development may also go awry when GCP3 mutations inhibit regulations of responses to bone morphogenetic proteins, another type of growth factor.^[5]

It has been suggested that SGBS type II may be caused by duplication of the GPC4 gene, which helps to regulate cell division and growth.^[6]

Also, some patients diagnosed with SGBS do not have any GPC3 or GPC4 deletions or mutations. Possible explanations include promoter mutation or silencing of the GPC3 gene causing reduced expression in these patients.^[7]

Genetics

Simpson–Golabi–Behmel syndrome has an X-linked recessive pattern of inheritance.

The disorder is passed on in an X-linked recessive fashion.

Possible symptoms and associated conditions

Macrosomia
Macroglossia
Advanced bone age
Organomegaly
Neonatal hypoglycemia
Neoplasms
Congenital diaphragmatic hernia (CDH)
"Bulldog" or "coarse" face (protruding jaw and tongue, widened nasal bridge, upturned nasal tip)
Hands and feet are short and broad with dysplatic nails
Cutaneous syndactyly
Polydactyly
Pectus excavatum
Talipes
Vertebral sementation defects
Supernumerary nipples
Structural and conductive cardiac defects
Multicystic dysplastic kidneys
Hypotonia
Seizures
Brain malformations
Developmental disabilities
Mental retardation- can be inexistent or mild to severe

Detection and diagnosis

Detection usually begins with a routine doctor visit when the fundal height is being measured or during an ultrasound examination. When large for gestational age fetuses (LGA) are identified, there may be a possibility of two causes: maternal diabetes or incorrect dates. However, if these two causes are ruled out, an ultrasound is performed to detect for overgrowth and other abnormalities. At this point, it becomes essential for a clinical geneticist to assist in the correct selection of tests and possible diagnosis.^[8]

First signs of SGBS may be observed as early as 16 weeks of gestation. Aids to diagnosing might include the presence of macrosomia, polyhydramnios, elevated maternal serum-α-fetoprotein, cystic hygroma, hydrops fetalis, increased nuchal translucency, craniofacial abnormalities, visceromegaly, renal abnormalities, congenital diaphragmatic hernia, polydactyly, and a single umbilical artery.^[6]

If there is a known mutation in the family, prenatal testing is available. Prenatal testing is also possible by looking for evidence of the mild SGBS phenotype in the mother and the positive SGBS phenotype in male family members. Family members who are positive of SGBS may undergo mutational analysis of genes GCP3, GCP4, and CXORF5. Genomic balance in Xp22 and Xq26 may also be analyzed through array comparative genomic hybridization.^[6]

Due to the high percentage of male deaths during the neonatal period, early detection of tumors is crucial. In order to detect the presence of tumors, screening in SGBS patients should include abdominal ultrasound, urinalysis, and biochemical markers that screen for embryonic tumors.^[8]

Once the infant is born, possibility of hypoglycemia must be assessed along with cardiac, genitalia, liver, and adrenal evaluations. Such tests include chest radiographs, electrocardiogram, echocardiogram, renal sonography, and abdominal sonography to test for possible abnormalities.^[9]

Treatment and management

Since the syndrome is caused by a genetic mutation in the individual's DNA, a cure is not available. Treatment of the symptoms and management of the syndrome, however, is possible.

Depending on the manifestation, surgery, increased intake of glucose, special education, occupational therapy, speech therapy, and physical therapy are some methods of managing the syndrome and associated symptoms.^[10]

Additional information

SGBS is similar to another overgrowth syndrome called Beckwith–Wiedemann syndrome.

SGBS Cells are a unique tool to study the function of Human adipocyte biology. These cells are similar to human primary preadipocytes, and will become a popular model instead of Mouse 3T3-L1 cells to study the secretion and adipokine proﬁle in the future. This cellular tool has been described and developed by Dr. Martin Wabitsch, University of Ulm, Germany.^[11]

References

^ Online 'Mendelian Inheritance in Man' (OMIM) 312870
^ Garganta CL, Bodurtha JN (1992). "Report of another family with Simpson–Golabi–Behmel syndrome and a review of the literature". Am J Med Genet. 44 (2): 129–135. doi:10.1002/ajmg.1320440202. PMID 1456279.
^ Lapunzina, Pablo (15 August 2005). "Risk of tumorigenesis in overgrowth syndromes: A comprehensive review". American Journal of Medical Genetics Part C. 137C (1): 53–71. doi:10.1002/ajmg.c.30064.
^ Slavotinek, Anne M. (15 May 2007). "Single gene disorders associated with congenital diaphragmatic hernia". American Journal of Medical Genetics Part C. 145C (2): 172–183. doi:10.1002/ajmg.c.30125.
^ Debaun, Michael R.; Ess, Jennifer; Saunders, Scott (2001). "Simpson Golabi Behmel Syndrome: Progress toward Understanding the Molecular Basis for Overgrowth, Malformation, and Cancer Predisposition". Molecular Genetics and Metabolism. 72 (4): 279–86. doi:10.1006/mgme.2001.3150. PMID 11286501.
^ ^a ^b ^c Chen, Chih-Ping (1 June 2012). "Prenatal findings and the genetic diagnosis of fetal overgrowth disorders: Simpson-Golabi-Behmel syndrome, Sotos syndrome, and Beckwith-Wiedemann syndrome". Taiwanese Journal of Obstetrics and Gynecology. 51 (2): 186–191. doi:10.1016/j.tjog.2012.04.004. PMID 22795092.
^ Veugelers, M.4; Cat, BD; Muyldermans, SY; Reekmans, G; Delande, N; Frints, S; Legius, E; Fryns, JP; Schrander-Stumpel, C (22 May 2000). "Mutational analysis of the GPC3/GPC4 glypican gene cluster on Xq26 in patients with Simpson-Golabi-Behmel syndrome: identification of loss-of-function mutations in the GPC3 gene". Human Molecular Genetics. 9 (9): 1321–1328. doi:10.1093/hmg/9.9.1321. PMID 10814714.
^ ^a ^b Vora, Neeta; Bianchi, Diana W. (1 October 2009). "Genetic considerations in the prenatal diagnosis of overgrowth syndromes". Prenatal Diagnosis. 29 (10): 923–929. doi:10.1002/pd.2319. PMID 19609940.
^ DeBaun, Michael R.; Ess, Jennifer; Saunders, Scott (1 April 2001). "Simpson Golabi Behmel Syndrome: Progress toward Understanding the Molecular Basis for Overgrowth, Malformation, and Cancer Predisposition". Molecular Genetics and Metabolism. 72 (4): 279–286. doi:10.1006/mgme.2001.3150. PMID 11286501.
^ Golabi, Mahin. "Simpson-Golabi-Behmel Syndrome Type 1". U.S. National Library of Medicine.
^ Wabitsch, Martin (January 2001). "Characterization of a human preadipocyte cell strain with high capacity for adipose differentiation". International journal of obesity and related metabolic disorder. 25 (1): 8–15. PMID 11244452. Retrieved 27 April 2015.

External links

Simpson–Golabi–Behmel syndrome at NIH's Office of Rare Diseases
GeneReview/NCBI/NIH/UW entry on Simpson–Golabi–Behmel Syndrome

UpToDate Contents

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1. ウィルムス腫瘍の症状、診断、および病期分類 presentation diagnosis and staging of wilms tumor
2. ベックウィズ・ヴィーデマン症候群 beckwith wiedemann syndrome
3. 胎児性巨大児 fetal macrosomia
4. 高身長や異常に急激な成長がみられる小児 the child with tall stature and or abnormally rapid growth
5. 妊娠期間に比して大きい新生児 large for gestational age newborn

English Journal

Hypoxia induces a HIF-1α dependent signaling cascade to make a complex metabolic switch in SGBS-adipocytes.

Leiherer A1, Geiger K2, Muendlein A2, Drexel H3.Author information 1Vorarlberg Institute for Vascular Investigation and Treatment (VIVIT), Feldkirch, Austria; Private University of the Principality of Liechtenstein, Triesen, Liechtenstein; Medical Central Laboratories, Feldkirch, Austria.2Vorarlberg Institute for Vascular Investigation and Treatment (VIVIT), Feldkirch, Austria; Private University of the Principality of Liechtenstein, Triesen, Liechtenstein.3Vorarlberg Institute for Vascular Investigation and Treatment (VIVIT), Feldkirch, Austria; Department of Medicine and Cardiology, Academic Teaching Hospital Feldkirch, Feldkirch, Austria; Private University of the Principality of Liechtenstein, Triesen, Liechtenstein; Drexel University College of Medicine, Philadelphia, USA. Electronic address: vivit@lkhf.at.AbstractTo elucidate the complex impact of hypoxia on adipose tissue, resulting in biased metabolism, insulin resistance and finally diabetes we used mature adipocytes derived from a Simpson-Golabi-Behmel syndrome patient for microarray analysis. We found a significantly increased transcription rate of genes involved in glycolysis and a striking association between the pattern of upregulated genes and disease biomarkers for diabetes mellitus and insulin resistance. Although their upregulation turned out to be HIF-1α-dependent, we identified further transcription factors mainly AP-1 components to play also an important role in hypoxia response. Analyzing the regulatory network of mentioned transcription factors and glycolysis targets we revealed a clear hint for directing glycolysis to glutathione and glycogen synthesis. This metabolic switch in adipocytes enables the cell to prevent oxidative damage in the short term but might induce lipogenesis and establish systemic metabolic disorders in the long run.
Molecular and cellular endocrinology.Mol Cell Endocrinol.2014 Mar 5;383(1-2):21-31. doi: 10.1016/j.mce.2013.11.009. Epub 2013 Nov 22.
To elucidate the complex impact of hypoxia on adipose tissue, resulting in biased metabolism, insulin resistance and finally diabetes we used mature adipocytes derived from a Simpson-Golabi-Behmel syndrome patient for microarray analysis. We found a significantly increased transcription rate of gene
PMID 24275182

Up-regulation of Bcl-2 during adipogenesis mediates apoptosis resistance in human adipocytes.

Nagel SA1, Keuper M1, Zagotta I1, Enlund E1, Ruperez AI1, Debatin KM2, Wabitsch M3, Fischer-Posovszky P4.Author information 1Division of Pediatric Endocrinology and Diabetes, Department of Pediatrics and Adolescent Medicine, Ulm University Medical Center, 89075 Ulm, Germany.2Department of Pediatrics and Adolescent Medicine, Ulm University Medical Center, 89075 Ulm, Germany.3Division of Pediatric Endocrinology and Diabetes, Department of Pediatrics and Adolescent Medicine, Ulm University Medical Center, 89075 Ulm, Germany. Electronic address: martin.wabitsch@uniklinik-ulm.de.4Division of Pediatric Endocrinology and Diabetes, Department of Pediatrics and Adolescent Medicine, Ulm University Medical Center, 89075 Ulm, Germany. Electronic address: pamela.fischer@uniklinik-ulm.de.AbstractTargeting apoptotic pathways in adipocytes has been suggested as a pharmacological approach to treat obesity. However, adipocyte apoptosis was identified as a cause for macrophage infiltration into adipose tissue. Previous studies suggest that mature adipocytes are less sensitive to apoptotic stimuli as compared to preadipocytes. Here, we aimed to identify proteins mediating apoptosis resistance in adipocytes. Our data revealed that the anti-apoptotic protein Bcl-2 (B-cell lymphoma 2) is up-regulated during adipogenic differentiation. Bcl-2 overexpression in preadipocytes lowers their apoptosis sensitivity to the level of mature adipocytes. Vice versa Bcl-2 knockdown in adipocytes sensitizes these cells to CD95-induced apoptosis. Taken together, our findings suggest a shift in the balance of pro-apoptotic and anti-apoptotic molecules during adipogenesis resulting in a higher apoptosis resistance. This study sheds new light on the apoptotic process in human fat cells and may constitute a new possible target for the specific regulation of adipose tissue mass.
Molecular and cellular endocrinology.Mol Cell Endocrinol.2014 Jan 25;382(1):368-76. doi: 10.1016/j.mce.2013.10.024. Epub 2013 Oct 26.
Targeting apoptotic pathways in adipocytes has been suggested as a pharmacological approach to treat obesity. However, adipocyte apoptosis was identified as a cause for macrophage infiltration into adipose tissue. Previous studies suggest that mature adipocytes are less sensitive to apoptotic stimul
PMID 24397922

Somatic CTNNB1 mutation in hepatoblastoma from a patient with Simpson-Golabi-Behmel syndrome and germline GPC3 mutation.

Kosaki R, Takenouchi T, Takeda N, Kagami M, Nakabayashi K, Hata K, Kosaki K.Author information Division of Medical Genetics, National Center for Child Health and Development, Tokyo, Japan.AbstractSimpson-Golabi-Behmel syndrome is a rare overgrowth syndrome caused by the GPC3 mutation at Xq26 and is clinically characterized by multiple congenital abnormalities, intellectual disability, pre/postnatal overgrowth, distinctive craniofacial features, macrocephaly, and organomegaly. Although this syndrome is known to be associated with a risk for embryonal tumors, similar to other overgrowth syndromes, the pathogenetic basis of this mode of tumorigenesis remains largely unknown. Here, we report a boy with Simpson-Golabi-Behmel syndrome who had a germline loss-of function mutation in GPC3. At 9 months of age, he developed hepatoblastoma. A comparison of exome analysis results for the germline genome and for the tumor genome revealed a somatic mutation, p.Ile35Ser, within the degradation targeting box of β-catenin. The same somatic mutation in CTNNB1 has been repeatedly reported in hepatoblastoma and other cancers. This finding suggested that the CTNNB1 mutation in the tumor tissue represents a driver mutation and that both the GPC3 and the CTNNB1 mutations contributed to tumorigenesis in a clearly defined sequential manner in the propositus. The current observation of a somatic CTNNB1 mutation in a hepatoblastoma from a patient with a germline GPC3 mutation supports the notion that the mutation in GPC3 may influence one of the initial steps in tumorigenesis and the progression to hepatoblastoma. © 2014 Wiley Periodicals, Inc.
American journal of medical genetics. Part A.Am J Med Genet A.2014 Jan 23. doi: 10.1002/ajmg.a.36364. [Epub ahead of print]
Simpson-Golabi-Behmel syndrome is a rare overgrowth syndrome caused by the GPC3 mutation at Xq26 and is clinically characterized by multiple congenital abnormalities, intellectual disability, pre/postnatal overgrowth, distinctive craniofacial features, macrocephaly, and organomegaly. Although this s
PMID 24459012

Japanese Journal

P2-37-11 Postmortem MRI・部分的病理解剖にてSimpson-Golabi-Behmel syndromeと臨床診断しえた1例(Group 89 胎児・新生児の異常(症例)2,一般演題,公益社団法人日本産科婦人科学会第65回学術講演会)

落合大吾,日原華子,齋藤郁恵,西島翔太,天方朋子,櫻井友義,池田俊之,矢久保和美,福井谷達郎
日本産科婦人科學會雜誌 65(2), 803, 2013-02-01
NAID 110009639148

症例 Simpson-Golabi-Behmel症候群の多発奇形の1例

松井貴浩,櫻井淳
形成外科 53(6), 663-670, 2010-06
NAID 40017164444

Glypican 3遺伝子の変異を示した Simpson-Golabi-Behmel 症候群の1例

國方徹也,岡崎薫,岩瀬孝志,大滝由紀,寺田一也,藤澤由樹,近藤郁子
日本小児科学会雑誌 107(5), 785-788, 2003-05-01
NAID 50000835849

「過成長症候群」

Simpson–Golabi–Behmel syndrome
Classification and external resources
Specialty	medical genetics
ICD-10	Q87.3
ICD-9-CM	759.89
OMIM	312870
DiseasesDB	32640
	[edit on Wikidata]