DiagnosisClinical DiagnosisThe diagnosis of Shprintzen-Goldberg syndrome (SGS) is suspected in individuals with a combination of the following major characteristics:Craniosynostosis, usually involving the coronal, sagittal, or lambdoid suturesCraniofacial findings Dolichocephaly with or without scaphocephaly Tall or prominent forehead Ocular proptosis Widely spaced eyesDownslanted palpebral fissuresMalar flattening High narrow palate with prominent palatine ridges Micrognathia and/or retrognathia Apparently low-set and posteriorly rotated earsSkeletal findings Dolichostenomelia Arachnodactyly Camptodactyly Pes planusPectus excavatum or carinatum Scoliosis Joint hypermobility or contracturesFoot malpositionCardiovascular findings Mitral valve prolapse Mitral regurgitation/incompetence Aortic regurgitationDilatation of the aortic rootNeurologic anomalies Delayed motor and cognitive milestones Mild-to-moderate intellectual disabilityBrain anomalies Hydrocephalus Dilatation of the lateral ventricles Chiari 1 malformationRadiographic findings Craniosynostosis C1-C2 abnormality Wide anterior fontanel Thin ribs 13 pairs of ribs Square-shaped vertebral bodies OsteopeniaOtherArterial tortuosityOther aneurysmBroad/bifid uvulaCleft palateClub foot deformityDural ectasiaHerniasLoss of subcutaneous fatMyopiaMolecular Genetic TestingGene. SKI is the only gene in which mutations are known to cause Shprintzen-Goldberg syndrome. Table 1. Summary of Molecular Genetic Testing Used in Shprintzen-Goldberg syndromeView in own windowGene ¹ Test MethodMutations Detected ^{2Mutation Detection Frequency by Test Method 3Test AvailabilitySKISequence analysisSequence variants 4See footnote 5ClinicalDeletion/duplication analysis 6Exonic or whole-gene deletionsUnknown, none reported 71. See Table A. Genes and Databases for chromosome locus and protein name.2. See Molecular Genetics for information on allelic variants. 3. The ability of the test method used to detect a mutation that is present in the indicated gene4. Examples of mutations detected by sequence analysis may include small intragenic deletions/insertions and missense, nonsense, and splice site mutations; typically, exonic or whole-gene deletions/duplications are not detected. For issues to consider in interpretation of sequence analysis results, click here.5. Carmignac et al [2012], Doyle et al [2012]6. Testing that identifies deletions/duplications not readily detectable by sequence analysis of the coding and flanking intronic regions of genomic DNA; included in the variety of methods that may be used are: quantitative PCR, long-range PCR, multiplex ligation-dependent probe amplification (MLPA), and chromosomal microarray (CMA) that includes this gene/chromosome segment.7. No deletions or duplications involving SKI as causative of Shprintzen-Goldberg syndrome have been reported. (Note: By definition, deletion/duplication analysis identifies rearrangements that are not identifiable by sequence analysis of genomic DNA.)Testing Strategy Confirming/establishing the diagnosis in a proband. The condition is suspected based on clinical findings. Genetic testing may confirm the diagnosis.Sequence analysis of SKI should be pursued first.If no pathogenic mutation in SKI is found through sequence analysis, deletion/duplication analysis can be considered.Prenatal diagnosis and preimplantation genetic diagnosis (PGD) for at-risk pregnancies require prior identification of the disease-causing mutation in the family.Genetically Related (Allelic) DisordersNo other phenotypes are known to be associated with mutations in SKI.}

Natural HistoryThe clinical and molecular characterization of 29 individuals with Shprintzen-Goldberg syndrome (SGS) has been reported [Carmignac et al 2012, Doyle et al 2012]. The syndrome is characterized by craniosynostosis, dolichocephaly, distinctive craniofacial features, skeletal changes, hypotonia, intellectual disability, aortic root dilatation, valvular anomalies, and neurologic and brain anomalies (see Clinical Diagnosis). Minimal subcutaneous fat, abdominal wall defects, myopia, and cryptorchidism in males are other characteristic findings. Of note, lens dislocation does not appear to be a feature of SGS.Both males and females may be affected.The majority of individuals with Shprintzen-Goldberg syndrome are born at term by spontaneous vaginal delivery, with birth weight greater than 3 kg, birth length greater than 46 cm, and head circumference within the normal range.Motor and cognitive milestones are delayed and mild-to-moderate intellectual disability appears to be invariable. Although normal intelligence was reported in one man followed from infancy to adulthood, he had academic difficulties and attended a special school [Stoll 2002].Aortic root dilatation was present in three of 19 affected individuals reported by Carmignac et al [2012] and also in a small proportion of the individuals with SGS reported by Greally et al [1998] and Robinson et al [2005]. In the report of Doyle et al [2012] however, eight of ten individuals with SGS and confirmed mutations in SKI had aortic root dilatation ± mitral valve prolapse/incompetence. Surgery at age 16 years for aortic dilatation (aortic root dilatation with Z score = 7.014) was reported in one individual with molecularly confirmed SGS [Carmignac et al 2012]. This individual also had vertebrobasilar and internal carotid tortuosity and a dilated pulmonary artery root. Among the affected individuals with molecularly confirmed SGS reported by Doyle et al [2012] one had arterial tortuosity and two had splenic artery aneurysm, one with spontaneous rupture. In addition to the characteristic skeletal findings, cloverleaf skull [Saal et al 1995], bathrocephaly, abruptly sloping orbital roofs, disharmonic maturation of ossification centers, dislocation of the radial head, anterior subluxation of the wrists, thin proximally placed thumbs, phalangeal hypotubulation and sclerosis, hip subluxation, femur fracture, genu recurvatum, talipes equinovarus, metatarsus adductus, congenital bowing of the ribs and long bones, and hypoplastic hooked clavicles have also been reported [Adès et al 1995].Other findings include respiratory distress [Hassed et al 1997], strabismus, choanal atresia, hypoplasia of the corpus callosum [Saal et al 1995], intestinal malrotation, anteriorly placed anus, mild cerebral atrophy [Adès et al 1995], abdominal hernia [Stoll 2002,Robinson et al 2005], dural ectasia, cleft palate, and broad/bifid uvula [Doyle et al 2012].

Genotype-Phenotype CorrelationsNo genotype-phenotype correlation can be made at this time.

Differential DiagnosisThe phenotype of Shprintzen-Goldberg syndrome (SGS) is distinctive but shows some overlap with Loeys-Dietz syndrome (LDS) and Marfan syndrome (MFS). Distinguishing features of SGS include hypotonia and intellectual disability, which are rare findings in individuals with LDS and MFS, but appear to be invariably present in those with SGS. Some of the radiographic findings in SGS are distinctive and are rarely found in individuals with either LDS or MFS (e.g., C1/C2 abnormality, 13 pairs of ribs, square-shaped vertebral bodies, Chiari1 malformation). In addition, aortic root dilatation is less frequent is SGS than in LDS or MFS but, when present, it can be severe [Carmignac et al 2012]. One of the hallmarks of LDS is the occurrence of arterial tortuosity and aneurysms in arteries other than the aorta. Arterial tortuosity was found in two individuals with SGS; a further two individuals with SGS were found to have splenic artery aneurysm [Carmignac et al 2012, Doyle et al 2012]. Loeys-Dietz syndrome (LDS) may be difficult to differentiate clinically from SGS. LDS is characterized by vascular findings (cerebral, thoracic, and abdominal arterial aneurysms and/or dissections) and skeletal manifestations (pectus excavatum or pectus carinatum, scoliosis, joint laxity, arachnodactyly, talipes equinovarus). Approximately 75% of affected individuals have LDS type I with craniofacial manifestations (widely spaced eyes, bifid uvula/cleft palate, craniosynostosis); approximately 25% have LDS type II with cutaneous manifestations (velvety and translucent skin; easy bruising; widened, atrophic scars). LDSI and LDSII form a clinical continuum. The natural history of LDS is characterized by aggressive arterial aneurysms (mean age at death 26.1 years) and high incidence of pregnancy-related complications including death and uterine rupture. A minority of affected individuals have developmental delay [Loeys & Dietz 2008]. Mutations in TGFBR1, TGFBR2, TGFB2, and SMAD3 have been identified in individuals with Loeys-Dietz syndrome [Loeys et al 2005, Adès et al 2006, Stheneur et al 2008, Tug et al 2010]. LDS is inherited in an autosomal dominant manner. Adès et al [2005] and Loeys et al [2005] found no mutations in TGFBR1 and TGFBR2 in their cohort of patients with SGS.The phenotype of the individual described by van Steensel et al [2008] included craniosynostosis, scoliosis, pectus excavatum, a mucous pseudocleft of the palate, posterior rotation of the ears, dilatation of the ascending aorta, and normal development. A mutation in TGFBR2 was found in this individual; thus, despite the absence of arterial tortuosity, it appears to be more likely that this individual had LDS rather than SGS.Stheneur et al [2008] reported on the phenotype of individuals with aTGFBR1 or TGFBR2 mutation: one person referred with a diagnosis of SGS because of craniosynostosis, widely spaced eyes, retrognathia, malar flattening, and developmental delay was found to have a TGFBR1 mutation.Marfan syndrome is a systemic disorder of connective tissue with a high degree of clinical variability. Cardinal manifestations involve the ocular, skeletal, and cardiovascular systems. Myopia is the most common ocular feature; displacement of the lens from the center of the pupil, seen in approximately 60% of affected individuals, is a hallmark feature. People with Marfan syndrome are at increased risk for retinal detachment, glaucoma, and early cataract formation. The skeletal system involvement is characterized by bone overgrowth and joint laxity. The extremities are disproportionately long for the size of the trunk (dolichostenomelia). Overgrowth of the ribs can push the sternum in (pectus excavatum) or out (pectus carinatum). Scoliosis is common and can be mild or severe and progressive. The major sources of morbidity and early mortality in the Marfan syndrome relate to the cardiovascular system. Cardiovascular manifestations include dilatation of the aorta at the level of the sinuses of Valsalva, a predisposition for aortic tear and rupture, mitral valve prolapse with or without regurgitation, tricuspid valve prolapse, and enlargement of the proximal pulmonary artery. With proper management, the life expectancy of someone with Marfan syndrome approximates that of the general population. FBN1 is the gene associated with Marfan syndrome. Inheritance is autosomal dominant.Mutations in FBN1 have been reported in three individuals with a clinical diagnosis of Shprintzen-Goldberg syndrome (SGS) [Sood et al 1996, Kosaki et al 2005]:The case of Sood et al [1996] with the p.Cys1223Tyr allele was atypical for both Marfan syndrome and SGS. While the individual reported had ectopia lentis (typical for Marfan syndrome and not SGS), she also had craniosynostosis, strabismus, abnormal ears, hypotonia, and foot deformities (typical of SGS and not Marfan syndrome). The individual described by Kosaki et al [2006] with the p.Cys1223Tyr allele had craniosynostosis, dolichocephaly, mild exophthalmos, downslanted palpebral fissures, pectus carinatum, scoliosis, arachnodactyly with contractures of the interphalangeal joints, developmental delay, minimal enlargement of the aortic root, and mitral valve prolapse, but no evidence of ectopia lentis — that is, findings more typical of SGS. The p.Pro1148Ala mutation in the other case reported by Sood et al [1996] has been found in aortic aneurysm syndromes, but shows relative enrichment in normal Asian and Hispanic populations and is likely to be a polymorphism [Schrijver et al 1997, Watanabe et al 1997, Whiteman et al 1998].Adès et al [2005] found no FBN1 mutations in their cohort of individuals with a clinical diagnosis of SGS. Congenital contractural arachnodactyly (CCA) is characterized by a Marfan-like appearance (tall, slender habitus in which arm span exceeds height) and long, slender fingers and toes (arachnodactyly). Most affected individuals have “crumpled” ears that present as a folded upper helix of the external ear and most have contractures of major joints (knees and ankles) at birth. The proximal interphalangeal joints also have flexion contractures (i.e., camptodactyly), as do the toes. Hip contractures, adducted thumbs, and club foot may occur. The majority of affected individuals have muscular hypoplasia. Contractures usually improve with time. Kyphosis/scoliosis is present in about half of all affected individuals. It begins as early as infancy, is progressive, and causes the greatest morbidity in CCA. Dilatation of the aorta is occasionally present. Infants have been observed with a severe/lethal form characterized by multiple cardiovascular and gastrointestinal anomalies in addition to the typical skeletal findings. FBN2, encoding the extracellular matrix microfibril fibrillin 2, is the only gene known to be associated with CCA. Inheritance is autosomal dominant.Frontometaphyseal dysplasia (FMD) and Melnick-Needles syndrome (MNS), two disorders in the otopalatodigital spectrum disorders, share skeletal findings with SGS including tall, square-shaped vertebrae, bowed tibiae, and occasionally, fusion of upper cervical vertebrae. The presence of intellectual disability and craniosynostosis usually distinguishes SGS from FMD or MNS. No mutations in FLNA have been found in SGS [S Robertson and L Adès, personal communication].Note to clinicians: For a patient-specific ‘simultaneous consult’ related to this disorder, go to , an interactive diagnostic decision support software tool that provides differential diagnoses based on patient findings (registration or institutional access required).

ManagementEvaluations Following Initial DiagnosisTo establish the extent of disease and needs in an individual diagnosed with Shprintzen-Goldberg syndrome (SGS), the following evaluations are recommended:Radiographs to detect skeletal manifestations that may require attention by an orthopedist (e.g. severe scoliosis, C1/C2 abnormality)Brain MRIEchocardiogram MRA or CT scan with 3D reconstruction from head to pelvis to identify arterial aneurysms and arterial tortuosity throughout the arterial tree should be considered [Carmignac et al 2012] Surgical evaluation for hernia repair, if indicatedDevelopmental assessmentOphthalmology examination by an ophthalmologist with expertise in connective tissue disordersMedical genetics consultationTreatment of ManifestationsManagement of SGS is best conducted through the coordinated input of a multidisciplinary team of specialists including a medical geneticist, cardiologist, ophthalmologist, orthopedist, cardiothoracic surgeon, and craniofacial team. The following are appropriate:Cardiovascular If aortic dilatation is present, treatment with beta-adrenergic blockers or other medications should be considered in order to reduce hemodynamic stress.Surgical intervention for aneurysms may be indicated.HerniaSurgical repair of abdominal hernias may be indicated.CraniofacialCleft palate and craniosynostosis require management by a craniofacial team; treatment is the same as in all disorders with these manifestations.SkeletalSurgical fixation of cervical spine instability may be necessary. Clubfoot deformity may require surgical correction.Pectus excavatum may be severe; rarely, surgical correction is indicated for medical reasons.PhysiotherapyPhysiotherapy may help increase mobility in individuals with joint contractures.Special educationA developmental assessment will help with placement in a special education center or in a special education program in a regular school.Prevention of Secondary ComplicationsSubacute bacterial endocarditis (SBE) prophylaxis is recommended for dental work or other procedures expected to contaminate the bloodstream with bacteria for individuals with cardiac complications.SurveillanceAll individuals with SGS should be managed by a cardiologist who is familiar with this condition.Agents/Circumstances to AvoidThe following should be avoided:Contact sports, which may lead to catastrophic complications in those with cardiovascular issues or cervical spine anomalies/instability Agents that stimulate the cardiovascular system, including routine use of decongestantsActivities that cause joint pain or injuryEvaluation of Relatives at RiskSee Genetic Counseling for issues related to testing of at-risk relatives for genetic counseling purposes.Therapies Under InvestigationSearch ClinicalTrials.gov for access to information on clinical studies for a wide range of diseases and conditions. Note: There may not be clinical trials for this disorder.

Molecular GeneticsInformation in the Molecular Genetics and OMIM tables may differ from that elsewhere in the GeneReview: tables may contain more recent information. —ED.Table A. Shprintzen-Goldberg Syndrome: Genes and DatabasesView in own windowGene SymbolChromosomal LocusProtein NameHGMDSKI1p36​.33Ski oncogeneSKIData are compiled from the following standard references: gene symbol from HGNC; chromosomal locus, locus name, critical region, complementation group from OMIM; protein name from UniProt. For a description of databases (Locus Specific, HGMD) to which links are provided, click here.Table B. OMIM Entries for Shprintzen-Goldberg Syndrome (View All in OMIM) View in own window 164780V-SKI AVIAN SARCOMA VIRAL ONCOGENE HOMOLOG; SKI 182212SHPRINTZEN-GOLDBERG CRANIOSYNOSTOSIS SYNDROME; SGSNormal allelic variants. The proto-oncoprotein, SKI, has seven exons; the transcript variant is 5,707 bps. Pathologic allelic variants. In their report of patients with SGS, Doyle et al [2012] found mutations in exon 1 of SKI in all ten patients: nine missense mutations and one 9-bp deletion. The alterations in SKI were found in two distinct N-terminal regions of the protein. The first region is located in the SMAD2/3-binding domain of SKI (residues 17-45) and the second region localizes to a portion of the Daschund-homology domain (DHD) of the SKI protein that mediates binding to SNW1 and N-CoR, proteins essential for recruitment of transcriptional corepressors, such as histone deacetylases [Doyle et al 2012]. Mutations in exon 1 of SKI were found in 18 of the 19 patients with SGS reported by Carmignac et al [2012]. A family with five affected individuals had a dominantly inherited heterozygous in-frame deletion in exon 1; a small deletion was also found in a simplex case while the remaining individuals had heterozygous missense mutations in exon 1, within the R-SMAD-binding domain of SKI. Normal gene product. The SKI gene product is in the same family as the SnoN protein. The SKI family of proteins negatively regulate SMAD-dependent TGF-β signaling by impeding SMAD2 and SMAD3 (SMAD2/3) activation, preventing nuclear translocation of the receptor-activated SMAD (R-SMAD)-SMAD4 complex and inhibiting TGF-β target gene output by competing with p300/CBP for SMAD binding and recruiting transcriptional repressor proteins, such as mSin3A and HDAC1 [Doyle et al 2012]. SKI has four transcripts (splice variants): SKI-001, SKI-002, SKI-004 and SKI-005. Only SKI-001 has a protein product.The SKI protein has a 728 amino-acid sequence with multiple domains and is expressed both inside and outside the cell. The different domains have different functions, with the primary domains interacting with Smad proteins. The SKI oncogene is present in all cells, and is commonly active during development. All mutations reported to date in SGS were in exon 1, in two distinct N-terminal regions of the protein. The first region is located in the SMAD2/3-binding domain of SKI (residues 17-45) and the second region localizes to a portion of the Daschund-homology domain (DHD) of the SKI protein.Abnormal gene product. Doyle et al [2012] assessed the functional consequences of SKI mutations and showed excessive SMAD2/3 and extracellular signal-regulated kinase (ERK1) and ERK2 (ERK1/2) phosphorylation in cells of affected individuals compared to controls, both at baseline and after acute (30-min) stimulation with exogenous TGF-β2. They concluded that this implied loss of suppression of the TGF-β-dependent signaling cascades in SGS cells. The SKI family of proteins negatively regulates SMAD-dependent TGF-β signaling. Mutations in SKI result in enhanced activation of TGF-β signaling cascades and higher expression of TGF-β-responsive genes relative to control cells. Dysregulation of TGF-β signaling has been implicated in the pathogenesis of syndromic presentations of aneurysm, with excessive TGF-β signaling observed in the aortic wall and other diseased tissue in mouse models of Marfan syndrome. Doyle et al [2012] showed that the multisystem manifestations of SGS are caused by primary mutations in a prototypical repressor of TGF-β signaling and, from their study, concluded that the gene in which mutation is causative was SKI. Their data supported the conclusion that increased TGF-β signaling is the mechanism underlying SGS.