Shprintzen-Goldberg Syndrome

Mendelian MONDO:0008426 Pathograph 2 Connective Tissue Disorders

Shprintzen-Goldberg syndrome (SGS) is a rare autosomal dominant connective tissue disorder caused by mutations in SKI, encoding the SKI proto-oncoprotein, a negative regulator of TGF-beta signaling. It shares phenotypic overlap with Marfan and Loeys-Dietz syndromes but is distinguished by craniosynostosis and intellectual disability. Features include Marfanoid habitus, skeletal anomalies, craniosynostosis, and arachnodactyly, with less severe cardiovascular involvement than LDS.

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1
Inheritance
2
Pathophys.
10
Phenotypes
2
Pathograph
2
Genes
3
Treatments
5
References
2
Deep Research
👪

Inheritance

1
Autosomal Dominant
Autosomal dominant inheritance. Most cases arise from de novo mutations.
Show evidence (1 reference)
PMID:23103230 SUPPORT
"Using family-based exome sequencing, we identified a dominantly inherited heterozygous in-frame deletion in exon 1 of SKI."
Demonstrates dominant inheritance of SKI mutations in SGS.

Pathophysiology

2
Enhanced TGF-beta Signaling
SKI is a transcriptional co-repressor that normally inhibits TGF-beta signaling by binding to SMAD proteins and recruiting transcriptional repression complexes. Loss-of-function mutations in SKI lead to enhanced TGF-beta signaling, similar to the paradoxical TGF-beta hyperactivation seen in Loeys-Dietz and Marfan syndromes. This drives abnormal connective tissue development.
vascular associated smooth muscle cell link
TGF-beta Signaling link ↑ INCREASED Cranial Suture Closure link
Downstream
Aortic Aneurysm Enhanced TGF-beta signaling in the aortic wall drives aortic root dilation and aneurysm, placing SGS in the spectrum of TGF-beta-related aortic aneurysm syndromes alongside Marfan and Loeys-Dietz syndromes.
Show evidence (3 references)
PMID:23023332 SUPPORT
"Cultured dermal fibroblasts from affected individuals showed enhanced activation of TGF-beta signaling cascades and higher expression of TGF-beta-responsive genes relative to control cells."
Direct evidence of enhanced TGF-beta signaling in patient-derived fibroblasts carrying SKI mutations.
PMID:23023332 SUPPORT
"These data support the conclusions that increased TGF-beta signaling is the mechanism underlying SGS and that high signaling contributes to multiple syndromic presentations of aortic aneurysm."
Confirms that increased TGF-beta signaling is the primary pathogenic mechanism in SGS.
PMID:23103230 SUPPORT Model Organism
"The interaction between SKI and Smad2/3 and Smad 4 regulates TGF-beta signaling, and the pattern of anomalies in Ski-deficient mice corresponds to the clinical manifestations of SGS."
Confirms SKI-SMAD interaction regulates TGF-beta signaling and that mouse models recapitulate the SGS phenotype.
Skeletal Development Disruption
Enhanced TGF-beta signaling disrupts normal skeletal patterning and growth, leading to dolichostenomelia, arachnodactyly, scoliosis, and joint contractures similar to Marfan syndrome. Craniosynostosis results from premature fusion of cranial sutures.
Skeletal System Development link Ossification link
Show evidence (1 reference)
PMID:24736733 SUPPORT
"SGS is a rare, systemic connective tissue disorder characterized by craniofacial, skeletal, and cardiovascular manifestations that show a significant overlap with the features observed in the Marfan (MFS) and Loeys-Dietz syndrome (LDS)."
Confirms SGS as a systemic connective tissue disorder with prominent skeletal manifestations.

Pathograph

Use the checkboxes to hide or show graph categories. Hover nodes for evidence and cross-linked metadata.
Pathograph: causal mechanism network for Shprintzen-Goldberg Syndrome Interactive directed graph showing how pathophysiology mechanisms, phenotypes, genetic factors and variants, experimental models, environmental triggers, and treatments relate through causal and linked edges.

Phenotypes

10
Cardiovascular 2
Aortic Aneurysm Aortic aneurysm (HP:0004942)
Show evidence (1 reference)
PMID:23023332 SUPPORT
"Shprintzen-Goldberg syndrome (SGS) has considerable phenotypic overlap with MFS and LDS, including aortic aneurysm."
Identifies aortic aneurysm as a feature shared with MFS and LDS.
Mitral Valve Prolapse Mitral valve prolapse (HP:0001634)
Digestive 1
Inguinal Hernia Inguinal hernia (HP:0000023)
Head and Neck 1
Craniosynostosis Craniosynostosis (HP:0001363)
Show evidence (2 references)
PMID:23103230 SUPPORT
"Shprintzen-Goldberg syndrome (SGS) is characterized by severe marfanoid habitus, intellectual disability, camptodactyly, typical facial dysmorphism, and craniosynostosis."
Lists craniosynostosis as a characteristic feature of SGS.
PMID:9508238 SUPPORT
"Shprintzen-Goldberg syndrome is one of a group of disorders characterized by craniosynostosis and marfanoid habitus."
Identifies craniosynostosis as a defining feature distinguishing SGS from other marfanoid conditions.
Limbs 1
Arachnodactyly Arachnodactyly (HP:0001166)
Musculoskeletal 3
Scoliosis Scoliosis (HP:0002650)
Joint Contractures Flexion contracture (HP:0001371)
Show evidence (1 reference)
PMID:23103230 SUPPORT
"SGS is characterized by severe marfanoid habitus, intellectual disability, camptodactyly, typical facial dysmorphism, and craniosynostosis."
Lists camptodactyly (a form of flexion contracture) as a characteristic SGS feature.
Cervical Vertebral Anomalies Abnormality of the cervical spine (HP:0003319)
Show evidence (1 reference)
PMID:9508238 SUPPORT
"an abnormality of the first and second cervical vertebrae, hydrocephalus, dilatation of the lateral ventricles, and a Chiari-I malformation of the brain were found only in the patients with Shprintzen-Goldberg syndrome."
Cervical vertebral anomalies are a diagnostic radiologic finding specific to SGS among craniosynostosis-marfanoid disorders.
Nervous System 1
Intellectual Disability Intellectual disability (HP:0001249)
Show evidence (2 references)
PMID:24736733 SUPPORT
"A distinguishing observation in SGS patients is the presence of intellectual disability, although not all patients in this series present this finding."
Identifies intellectual disability as a distinguishing feature of SGS relative to MFS and LDS, though with variable penetrance.
PMID:23103230 SUPPORT
"SGS is characterized by severe marfanoid habitus, intellectual disability, camptodactyly, typical facial dysmorphism, and craniosynostosis."
Lists intellectual disability among the characteristic SGS features.
Growth 1
Disproportionate Tall Stature Disproportionate tall stature (HP:0001519)
Show evidence (1 reference)
PMID:23103230 SUPPORT
"SGS is characterized by severe marfanoid habitus, intellectual disability, camptodactyly, typical facial dysmorphism, and craniosynostosis."
Severe marfanoid habitus indicates disproportionate tall stature with long limbs as a key SGS feature.
🧬

Genetic Associations

2
SKI Mutations (Causative)
Show evidence (3 references)
PMID:23023332 SUPPORT
"We identified causative variation in ten individuals with SGS in the proto-oncogene SKI, a known repressor of TGF-beta activity."
Landmark paper identifying SKI as the causative gene for SGS in 10 patients.
PMID:23103230 SUPPORT
"All mutations were located in a restricted area of exon 1, within the R-SMAD binding domain of SKI."
Confirms that SGS mutations cluster in the R-SMAD binding domain of SKI exon 1.
PMID:24736733 SUPPORT
"73% (24 out of 33) of the hitherto described unrelated patients having mutations in a stretch of five SKI residues (from p.(Ser31) to p.(Pro35))."
Identifies a mutational hotspot in 5 SKI residues accounting for 73% of patients.
SKI (Pathogenic Variants)
Show evidence (1 reference)
CGGV:assertion_019ffb7a-be5f-482d-9adf-e28d5aadaede-2024-07-23T160000.000Z SUPPORT Other
"SKI | HGNC:10896 | Shprintzen-Goldberg syndrome | MONDO:0008426 | AD | Definitive"
ClinGen classifies the SKI-Shprintzen-Goldberg syndrome gene-disease relationship as definitive with autosomal dominant inheritance.
💊

Treatments

3
Craniosynostosis Surgery
Surgical correction of craniosynostosis to prevent increased intracranial pressure and allow normal brain growth.
Orthopedic Management
Management of scoliosis, joint contractures, and other skeletal manifestations with bracing and surgery as needed.
Cardiovascular Monitoring
Regular echocardiographic surveillance for aortic root dilation and mitral valve prolapse. Vascular complications are less severe than in Loeys-Dietz or Marfan syndromes but require monitoring.
{ }

Source YAML

click to show 
name: Shprintzen-Goldberg Syndrome
creation_date: '2026-02-13T00:31:42Z'
updated_date: '2026-02-17T21:53:14Z'
category: Mendelian
description: >
  Shprintzen-Goldberg syndrome (SGS) is a rare autosomal dominant connective tissue
  disorder caused by mutations in SKI, encoding the SKI proto-oncoprotein, a negative
  regulator of TGF-beta signaling. It shares phenotypic overlap with Marfan and
  Loeys-Dietz syndromes but is distinguished by craniosynostosis and intellectual
  disability. Features include Marfanoid habitus, skeletal anomalies, craniosynostosis,
  and arachnodactyly, with less severe cardiovascular involvement than LDS.
disease_term:
  preferred_term: Shprintzen-Goldberg syndrome
  term:
    id: MONDO:0008426
    label: Shprintzen-Goldberg syndrome
parents:
- Connective Tissue Disorders
inheritance:
- name: Autosomal Dominant
  description: >
    Autosomal dominant inheritance. Most cases arise from de novo mutations.
  evidence:
  - reference: PMID:23103230
    reference_title: "In-frame mutations in exon 1 of SKI cause dominant Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      Using family-based exome sequencing, we identified a dominantly inherited
      heterozygous in-frame deletion in exon 1 of SKI.
    explanation: >-
      Demonstrates dominant inheritance of SKI mutations in SGS.
prevalence:
- population: Published literature worldwide
  percentage: Approximately 75 documented cases
  notes: >-
    Shprintzen-Goldberg syndrome remains ultra-rare. A 2023 PubMed-indexed case
    report states that approximately 75 cases had been documented since the
    syndrome was first described in 1982.
  evidence:
  - reference: PMID:38186910
    supports: SUPPORT
    evidence_source: HUMAN_CLINICAL
    snippet: "Shprintzen-Goldberg syndrome (SGS) is an autosomal dominant syndrome caused by de novo gene mutations. It is characterized by a number of congenital defects such as craniofacial, skeletal, neurological, and connective tissue abnormalities. It is characterized by craniosynostosis and marfanoid features. To our knowledge, approximately 75 shprintzen-goldberg syndrome cases have been documented since it was first described in 1982."
    explanation: This recent PubMed-indexed case report provides an updated count-based estimate of the number of documented SGS cases.
  - reference: PMID:9508238
    supports: SUPPORT
    evidence_source: HUMAN_CLINICAL
    snippet: "Shprintzen-Goldberg syndrome is one of a group of disorders characterized by craniosynostosis and marfanoid habitus. Eleven cases were reported previously. We present 4 new patients"
    explanation: This early clinical analysis explicitly documented 15 recognized cases.
  - reference: PMID:24736733
    supports: SUPPORT
    evidence_source: HUMAN_CLINICAL
    snippet: "Adding our new findings to the existing data clearly reveals a mutational hotspot, with 73% (24 out of 33) of the hitherto described unrelated patients having mutations in a stretch of five SKI residues"
    explanation: This later molecular series indicates that 33 unrelated SGS patients had been described by 2015.
pathophysiology:
- name: Enhanced TGF-beta Signaling
  conforms_to: "aortopathy_tgfbeta_dysregulation#TGF-beta Signaling Dysregulation"
  description: >
    SKI is a transcriptional co-repressor that normally inhibits TGF-beta signaling
    by binding to SMAD proteins and recruiting transcriptional repression complexes.
    Loss-of-function mutations in SKI lead to enhanced TGF-beta signaling, similar
    to the paradoxical TGF-beta hyperactivation seen in Loeys-Dietz and Marfan
    syndromes. This drives abnormal connective tissue development.
  cell_types:
  - preferred_term: vascular associated smooth muscle cell
    term:
      id: CL:0000359
      label: vascular associated smooth muscle cell
  biological_processes:
  - preferred_term: TGF-beta Signaling
    term:
      id: GO:0007179
      label: transforming growth factor beta receptor signaling pathway
    modifier: INCREASED
  - preferred_term: Cranial Suture Closure
    term:
      id: GO:0060363
      label: cranial suture morphogenesis
  downstream:
  - target: Aortic Aneurysm
    description: >-
      Enhanced TGF-beta signaling in the aortic wall drives aortic root
      dilation and aneurysm, placing SGS in the spectrum of TGF-beta-related
      aortic aneurysm syndromes alongside Marfan and Loeys-Dietz syndromes.
  evidence:
  - reference: PMID:23023332
    reference_title: "Mutations in the TGF-β repressor SKI cause Shprintzen-Goldberg syndrome with aortic aneurysm."
    supports: SUPPORT
    snippet: >-
      Cultured dermal fibroblasts from affected individuals showed enhanced
      activation of TGF-beta signaling cascades and higher expression of
      TGF-beta-responsive genes relative to control cells.
    explanation: >-
      Direct evidence of enhanced TGF-beta signaling in patient-derived
      fibroblasts carrying SKI mutations.
  - reference: PMID:23023332
    reference_title: "Mutations in the TGF-β repressor SKI cause Shprintzen-Goldberg syndrome with aortic aneurysm."
    supports: SUPPORT
    snippet: >-
      These data support the conclusions that increased TGF-beta signaling is
      the mechanism underlying SGS and that high signaling contributes to
      multiple syndromic presentations of aortic aneurysm.
    explanation: >-
      Confirms that increased TGF-beta signaling is the primary pathogenic
      mechanism in SGS.
  - reference: PMID:23103230
    reference_title: "In-frame mutations in exon 1 of SKI cause dominant Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      The interaction between SKI and Smad2/3 and Smad 4 regulates TGF-beta
      signaling, and the pattern of anomalies in Ski-deficient mice corresponds
      to the clinical manifestations of SGS.
    explanation: >-
      Confirms SKI-SMAD interaction regulates TGF-beta signaling and that
      mouse models recapitulate the SGS phenotype.
    evidence_source: MODEL_ORGANISM
- name: Skeletal Development Disruption
  description: >
    Enhanced TGF-beta signaling disrupts normal skeletal patterning and growth,
    leading to dolichostenomelia, arachnodactyly, scoliosis, and joint
    contractures similar to Marfan syndrome. Craniosynostosis results from
    premature fusion of cranial sutures.
  biological_processes:
  - preferred_term: Skeletal System Development
    term:
      id: GO:0001501
      label: skeletal system development
  - preferred_term: Ossification
    term:
      id: GO:0001503
      label: ossification
  evidence:
  - reference: PMID:24736733
    reference_title: "The SMAD-binding domain of SKI: a hotspot for de novo mutations causing Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      SGS is a rare, systemic connective tissue disorder characterized by
      craniofacial, skeletal, and cardiovascular manifestations that show a
      significant overlap with the features observed in the Marfan (MFS) and
      Loeys-Dietz syndrome (LDS).
    explanation: >-
      Confirms SGS as a systemic connective tissue disorder with prominent
      skeletal manifestations.
phenotypes:
- name: Craniosynostosis
  description: >
    Craniosynostosis is a distinguishing feature of SGS compared to Marfan
    and Loeys-Dietz syndromes. Sagittal and lambdoid sutures are most
    commonly affected.
  phenotype_term:
    preferred_term: Craniosynostosis
    term:
      id: HP:0001363
      label: Craniosynostosis
  evidence:
  - reference: PMID:23103230
    reference_title: "In-frame mutations in exon 1 of SKI cause dominant Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      Shprintzen-Goldberg syndrome (SGS) is characterized by severe marfanoid
      habitus, intellectual disability, camptodactyly, typical facial
      dysmorphism, and craniosynostosis.
    explanation: >-
      Lists craniosynostosis as a characteristic feature of SGS.
  - reference: PMID:9508238
    reference_title: "Shprintzen-Goldberg syndrome: a clinical analysis."
    supports: SUPPORT
    snippet: >-
      Shprintzen-Goldberg syndrome is one of a group of disorders characterized
      by craniosynostosis and marfanoid habitus.
    explanation: >-
      Identifies craniosynostosis as a defining feature distinguishing SGS
      from other marfanoid conditions.
- name: Disproportionate Tall Stature
  description: >
    Tall, thin body habitus with dolichostenomelia (long, thin limbs)
    and Marfanoid features.
  phenotype_term:
    preferred_term: Disproportionate tall stature
    term:
      id: HP:0001519
      label: Disproportionate tall stature
  evidence:
  - reference: PMID:23103230
    reference_title: "In-frame mutations in exon 1 of SKI cause dominant Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      SGS is characterized by severe marfanoid habitus, intellectual disability,
      camptodactyly, typical facial dysmorphism, and craniosynostosis.
    explanation: >-
      Severe marfanoid habitus indicates disproportionate tall stature
      with long limbs as a key SGS feature.
- name: Intellectual Disability
  description: >
    Intellectual disability is a characteristic feature that distinguishes
    SGS from Marfan syndrome, though not universally present.
  phenotype_term:
    preferred_term: Intellectual disability
    term:
      id: HP:0001249
      label: Intellectual disability
  evidence:
  - reference: PMID:24736733
    reference_title: "The SMAD-binding domain of SKI: a hotspot for de novo mutations causing Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      A distinguishing observation in SGS patients is the presence of
      intellectual disability, although not all patients in this series
      present this finding.
    explanation: >-
      Identifies intellectual disability as a distinguishing feature of SGS
      relative to MFS and LDS, though with variable penetrance.
  - reference: PMID:23103230
    reference_title: "In-frame mutations in exon 1 of SKI cause dominant Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      SGS is characterized by severe marfanoid habitus, intellectual disability,
      camptodactyly, typical facial dysmorphism, and craniosynostosis.
    explanation: >-
      Lists intellectual disability among the characteristic SGS features.
- name: Scoliosis
  description: >
    Progressive scoliosis is common and may be severe.
  phenotype_term:
    preferred_term: Scoliosis
    term:
      id: HP:0002650
      label: Scoliosis
- name: Joint Contractures
  description: >
    Camptodactyly and other flexion contractures are common, particularly
    of the fingers and elbows.
  phenotype_term:
    preferred_term: Flexion contracture
    term:
      id: HP:0001371
      label: Flexion contracture
  evidence:
  - reference: PMID:23103230
    reference_title: "In-frame mutations in exon 1 of SKI cause dominant Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      SGS is characterized by severe marfanoid habitus, intellectual disability,
      camptodactyly, typical facial dysmorphism, and craniosynostosis.
    explanation: >-
      Lists camptodactyly (a form of flexion contracture) as a characteristic
      SGS feature.
- name: Arachnodactyly
  description: >
    Long, slender fingers characteristic of connective tissue disorders.
  phenotype_term:
    preferred_term: Arachnodactyly
    term:
      id: HP:0001166
      label: Arachnodactyly
- name: Aortic Aneurysm
  description: >
    Aortic root dilation and aneurysm, placing SGS in the spectrum of
    TGF-beta-related aortic aneurysm syndromes alongside MFS and LDS.
  phenotype_term:
    preferred_term: Aortic aneurysm
    term:
      id: HP:0004942
      label: Aortic aneurysm
  evidence:
  - reference: PMID:23023332
    reference_title: "Mutations in the TGF-β repressor SKI cause Shprintzen-Goldberg syndrome with aortic aneurysm."
    supports: SUPPORT
    snippet: >-
      Shprintzen-Goldberg syndrome (SGS) has considerable phenotypic overlap
      with MFS and LDS, including aortic aneurysm.
    explanation: >-
      Identifies aortic aneurysm as a feature shared with MFS and LDS.
- name: Mitral Valve Prolapse
  description: >
    Mitral valve prolapse occurs in some patients. Cardiovascular
    involvement is generally milder than in Loeys-Dietz or Marfan syndromes.
  phenotype_term:
    preferred_term: Mitral valve prolapse
    term:
      id: HP:0001634
      label: Mitral valve prolapse
- name: Inguinal Hernia
  description: >
    Hernias including inguinal and umbilical hernias are reported.
  phenotype_term:
    preferred_term: Inguinal hernia
    term:
      id: HP:0000023
      label: Inguinal hernia
- name: Cervical Vertebral Anomalies
  description: >
    Abnormalities of the first and second cervical vertebrae are a
    radiologic finding that may help distinguish SGS from other
    marfanoid-craniosynostosis conditions.
  phenotype_term:
    preferred_term: Abnormality of the cervical spine
    term:
      id: HP:0003319
      label: Abnormality of the cervical spine
  evidence:
  - reference: PMID:9508238
    reference_title: "Shprintzen-Goldberg syndrome: a clinical analysis."
    supports: SUPPORT
    snippet: >-
      an abnormality of the first and second cervical vertebrae,
      hydrocephalus, dilatation of the lateral ventricles, and a Chiari-I
      malformation of the brain were found only in the patients with
      Shprintzen-Goldberg syndrome.
    explanation: >-
      Cervical vertebral anomalies are a diagnostic radiologic finding
      specific to SGS among craniosynostosis-marfanoid disorders.
genetic:
- name: SKI Mutations
  association: Causative
  notes: >
    Heterozygous missense mutations in SKI, encoding the SKI proto-oncoprotein.
    SKI acts as a transcriptional co-repressor of TGF-beta/SMAD signaling.
    Mutations cluster in the R-SMAD binding domain and the Dachshund homology
    domain (DHD), disrupting SKI-SMAD interactions. 73% of mutations affect
    a stretch of five residues (p.Ser31 to p.Pro35) in exon 1.
  evidence:
  - reference: PMID:23023332
    reference_title: "Mutations in the TGF-β repressor SKI cause Shprintzen-Goldberg syndrome with aortic aneurysm."
    supports: SUPPORT
    snippet: >-
      We identified causative variation in ten individuals with SGS in the
      proto-oncogene SKI, a known repressor of TGF-beta activity.
    explanation: >-
      Landmark paper identifying SKI as the causative gene for SGS
      in 10 patients.
  - reference: PMID:23103230
    reference_title: "In-frame mutations in exon 1 of SKI cause dominant Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      All mutations were located in a restricted area of exon 1, within
      the R-SMAD binding domain of SKI.
    explanation: >-
      Confirms that SGS mutations cluster in the R-SMAD binding domain
      of SKI exon 1.
  - reference: PMID:24736733
    reference_title: "The SMAD-binding domain of SKI: a hotspot for de novo mutations causing Shprintzen-Goldberg syndrome."
    supports: SUPPORT
    snippet: >-
      73% (24 out of 33) of the hitherto described unrelated patients having
      mutations in a stretch of five SKI residues (from p.(Ser31) to p.(Pro35)).
    explanation: >-
      Identifies a mutational hotspot in 5 SKI residues accounting
      for 73% of patients.
- name: SKI
  gene_term:
    preferred_term: SKI
    term:
      id: hgnc:10896
      label: SKI
  association: Pathogenic Variants
  evidence:
  - reference: CGGV:assertion_019ffb7a-be5f-482d-9adf-e28d5aadaede-2024-07-23T160000.000Z
    reference_title: "SKI / Shprintzen-Goldberg syndrome (Definitive)"
    supports: SUPPORT
    evidence_source: OTHER
    snippet: "SKI | HGNC:10896 | Shprintzen-Goldberg syndrome | MONDO:0008426 | AD | Definitive"
    explanation: ClinGen classifies the SKI-Shprintzen-Goldberg syndrome gene-disease relationship as definitive with autosomal dominant inheritance.
treatments:
- name: Craniosynostosis Surgery
  description: >
    Surgical correction of craniosynostosis to prevent increased intracranial
    pressure and allow normal brain growth.
- name: Orthopedic Management
  description: >
    Management of scoliosis, joint contractures, and other skeletal
    manifestations with bracing and surgery as needed.
- name: Cardiovascular Monitoring
  description: >
    Regular echocardiographic surveillance for aortic root dilation
    and mitral valve prolapse. Vascular complications are less
    severe than in Loeys-Dietz or Marfan syndromes but require monitoring.
datasets: []
references:
- reference: DOI:10.1038/ejhg.2014.61
  title: 'The SMAD-binding domain of SKI: a hotspot for de novo mutations causing Shprintzen–Goldberg syndrome'
  findings: []
- reference: DOI:10.1038/nature24283
  title: Reversing SKI–SMAD4-mediated suppression is essential for TH17 cell differentiation
  findings: []
- reference: DOI:10.1038/ng.2421
  title: Mutations in the TGF-β repressor SKI cause Shprintzen-Goldberg syndrome with aortic aneurysm
  findings: []
- reference: DOI:10.1101/2021.02.12.431010
  title: Epigenetic modulation in the pathogenesis and treatment of inherited aortic aneurysm conditions
  findings: []
- reference: DOI:10.1136/jmedgenet-2021-107695
  title: 'Loeys-Dietz and Shprintzen-Goldberg syndromes: analysis of TGF-β-opathies with craniofacial manifestations using an innovative multimodality method'
  findings: []
📚

References & Deep Research

References

5
DOI:10.1038/ejhg.2014.61
The SMAD-binding domain of SKI: a hotspot for de novo mutations causing Shprintzen–Goldberg syndrome
No top-level findings curated for this source.
DOI:10.1038/nature24283
Reversing SKI–SMAD4-mediated suppression is essential for TH17 cell differentiation
No top-level findings curated for this source.
DOI:10.1038/ng.2421
Mutations in the TGF-β repressor SKI cause Shprintzen-Goldberg syndrome with aortic aneurysm
No top-level findings curated for this source.
DOI:10.1101/2021.02.12.431010
Epigenetic modulation in the pathogenesis and treatment of inherited aortic aneurysm conditions
No top-level findings curated for this source.
DOI:10.1136/jmedgenet-2021-107695
Loeys-Dietz and Shprintzen-Goldberg syndromes: analysis of TGF-β-opathies with craniofacial manifestations using an innovative multimodality method
No top-level findings curated for this source.

Deep Research

2
Disorder

Disorder

  • Name: Shprintzen-Goldberg Syndrome
  • Category: Mendelian
  • Existing deep-research providers: falcon
  • Existing evidence reference count in YAML: 21

Key Pathophysiology Nodes

  • Enhanced TGF-beta Signaling
  • Skeletal Development Disruption
  • Deep research literature mapping

Citation Inventory (for evidence mapping)

  • DOI:10.1038/ejhg.2014.61
  • DOI:10.1038/nature24283
  • DOI:10.1038/ng.2421
  • DOI:10.1101/2021.02.12.431010
  • DOI:10.1136/jmedgenet-2021-107695
Falcon
Disease Pathophysiology Research Report
Edison Scientific Literature 20 citations 2026-02-10T07:53:08.805228

Disease Pathophysiology Research Report

Target Disease - Disease Name: Shprintzen-Goldberg Syndrome (SGS) - MONDO ID: MONDO_0008426 (from OpenTargets disease record) - Category: Mendelian, autosomal dominant

Pathophysiology overview Shprintzen-Goldberg syndrome is caused by heterozygous de novo mutations in SKI, a transcriptional corepressor that negatively regulates TGF-β/SMAD signaling. Most pathogenic variants cluster in exon 1 within the N‑terminal SMAD-binding region (R‑SMAD-binding/SMAD-interacting hotspot), disrupting SKI’s interaction with phosphorylated SMAD2/3 and altering its regulated degradation and cofactor dynamics. The net consequence is dysregulated TGF‑β target gene expression with epigenetic remodeling (notably increased H3K27 acetylation via CBP/P300) in key mesenchymal lineages, including vascular smooth muscle cells and fibroblasts. These cellular programs underlie craniosynostosis and connective-tissue manifestations such as aortic root aneurysm, skeletal abnormalities, and skin/ocular features, placing SGS among the TGF‑β signalopathies related to Marfan and Loeys–Dietz syndromes (disease spectrum with ongoing debate about increased vs attenuated TGF‑β responses in different contexts). (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2, kang2021epigeneticmodulationin pages 12-16, schepers2015thesmadbindingdomain pages 4-5)

1) Core Pathophysiology - Primary mechanisms: SKI loss-of-function/dominant-negative effects at the SMAD interface. Doyle et al. identified heterozygous SKI mutations causing SGS; patient fibroblasts showed “enhanced activation of TGF‑β signaling cascades and higher expression of TGF‑β–responsive genes,” supporting pathogenic upregulation of TGF‑β programs in vivo (Nature Genetics, 2012; URL: https://doi.org/10.1038/ng.2421; published Sep 2012). Schepers et al. localized a mutation hotspot to the SMAD‑binding domain in exon 1 (EJHG, 2015; URL: https://doi.org/10.1038/ejhg.2014.61; published Apr 2015). Mechanistically, preclinical work indicates mutant SKI exhibits impaired binding to pSMAD2/3 and altered displacement of CBP/P300, leading to sustained TGF‑β transcriptional outputs and increased H3K27ac in aorta and skin; CBP/P300 inhibition reverses these signals (bioRxiv, 2021; URL: https://doi.org/10.1101/2021.02.12.431010; posted Feb 2021). (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2, kang2021epigeneticmodulationin pages 12-16, kang2021epigeneticmodulationin pages 1-5) - Dysregulated pathways: Canonical TGF‑β/SMAD2/3→SMAD4 signaling with aberrant chromatin cofactor balance (CBP/P300 vs HDAC/mSin3A/NCoR). Kang et al. report increased H3K27ac at TGF‑β target loci and broad upregulation of ECM and stress-response genes in Ski-mutant VSMCs and SGS fibroblasts; C646 (CBP/P300 HAT inhibitor) normalizes both acetylation and target gene expression and prevents aortic root growth in mouse models. (kang2021epigeneticmodulationin pages 12-16, kang2021epigeneticmodulationin pages 5-8) - Affected cellular processes: Transcriptional regulation of ECM and matrix remodeling genes (e.g., COL1A1, COL3A1, FN1, MMP2/MMP9, CTGF, SERPINE1), epigenetic acetylation (H3K27ac), and vascular media remodeling (elastin fiber fragmentation, collagen accumulation). (kang2021epigeneticmodulationin pages 12-16, kang2021epigeneticmodulationin pages 5-8)

2) Key Molecular Players - Genes/Proteins (HGNC) - SKI (HGNC:10896): Causative gene; exon 1 SMAD-binding hotspot mutations; SKI represses TGF‑β by binding R‑SMADs and recruiting corepressors/HDACs. (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2) - SMAD2 (HGNC:6767), SMAD3 (HGNC:6769), SMAD4 (HGNC:6770): SKI interaction partners in canonical signaling; SGS mutations impair SKI–pSMAD2/3 binding and regulated degradation, altering transcriptional outputs. (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2) - CREBBP (HGNC:2348) and EP300 (HGNC:3373): CBP/P300 histone acetyltransferases; increased activity/H3K27ac at TGF‑β targets in SGS; inhibition with C646 blunts disease programs in models. (kang2021epigeneticmodulationin pages 12-16, kang2021epigeneticmodulationin pages 5-8) - HDAC1 (HGNC:4852), SIN3A (HGNC:11128), NCOR1 (HGNC:7664): Corepressor/HDAC complexes recruited by SKI to repress SMAD-driven transcription; balance perturbed in SGS. (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2) - Chemical entities (CHEBI) - Histone acetyltransferase inhibitor C646 (CHEBI:138488; used tool-referenced as CBP/P300 inhibitor) reduced H3K27ac and TGF‑β target expression, preventing aortic root growth in Ski-mutant and Marfan mouse models. (kang2021epigeneticmodulationin pages 12-16) - Angiotensin II receptor blockers (e.g., losartan; CHEBI:65330) referenced in TGF‑β signalopathy literature as modulators of TGF‑β activity and aneurysm progression in related conditions; discussed as contextual therapy rather than SGS‑specific trial evidence. (kang2021epigeneticmodulationin pages 1-5) - Cell types (CL) - Vascular smooth muscle cells (CL:0000192): Effector cells for aortic pathology; show increased TGF‑β target expression, ECM remodeling and aneurysm in SkiVSMC:G34D/+ mice. (kang2021epigeneticmodulationin pages 12-16) - Fibroblasts (CL:0000057): SGS dermal fibroblasts display elevated baseline/stimulated TGF‑β responses (COL3A1, FN1, SMAD7, SKI). (kang2021epigeneticmodulationin pages 12-16, doyle2012mutationsinthe pages 1-9) - Cranial neural crest–derived progenitors (CL:0002320): Implicated in craniosynostosis and facial dysmorphology; morpholino knockdown of ski paralogs in zebrafish recapitulates craniofacial defects. (doyle2012mutationsinthe pages 1-9) - TH17 cells (CL:0001039): SKI–SMAD4 chromatin regulation controls RORγt expression and TH17 differentiation; illustrates SKI’s immune context in TGF‑β signalopathies. (kang2021epigeneticmodulationin pages 16-19) - Anatomical locations (UBERON) - Aorta (UBERON:0000947): Aortic root aneurysm with elastin fragmentation and collagen accumulation. (doyle2012mutationsinthe pages 1-9, kang2021epigeneticmodulationin pages 12-16) - Cranial sutures (UBERON:0003681): Premature suture fusion (craniosynostosis) with cranial base angle abnormalities. (almpani2022loeysdietzandshprintzengoldberg pages 1-2) - Skin (UBERON:0002097): Excess fibrillar collagen deposition in SGS models and fibroblast phenotypes. (kang2021epigeneticmodulationin pages 12-16)

3) Biological Processes (suggested GO annotations) - TGF‑β receptor signaling pathway (GO:0007179) and SMAD protein signal transduction (GO:0060395). (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2) - Regulation of transcription by RNA polymerase II (GO:0006357) via SMAD–SKI cofactor dynamics; negative regulation of transcription (GO:0045892). (doyle2012mutationsinthe pages 1-9) - Histone acetylation (GO:0016573) and regulation of chromatin organization (GO:0016568), notably H3K27 acetylation. (kang2021epigeneticmodulationin pages 12-16) - Extracellular matrix organization (GO:0030198), collagen fibril organization (GO:0030199), and regulation of matrix metallopeptidase activity (GO:0030193). (kang2021epigeneticmodulationin pages 12-16)

4) Cellular Components (suggested GO CC) - Nucleus (GO:0005634): SKI–SMAD complexes assemble on chromatin. (doyle2012mutationsinthe pages 1-9) - Chromatin (GO:0000785)/Transcriptional repressor complex (GO:0017053): SKI–HDAC/NCoR/mSin3A complexes. (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2) - SMAD complex (GO:0071141): R‑SMAD2/3–SMAD4 complexes targeted by SKI. (schepers2015thesmadbindingdomain pages 1-2)

5) Disease Progression (conceptual sequence) - Initiating event: De novo heterozygous SKI missense mutation in exon 1 (SMAD‑binding hotspot). (schepers2015thesmadbindingdomain pages 1-2, doyle2012mutationsinthe pages 1-9) - Molecular consequence: Impaired SKI binding to pSMAD2/3 and defective ligand-induced SKI degradation; aberrant cofactor exchange with increased CBP/P300 occupancy and H3K27ac at TGF‑β target loci; net upregulation of many TGF‑β–responsive genes in VSMCs and fibroblasts. (kang2021epigeneticmodulationin pages 12-16, kang2021epigeneticmodulationin pages 5-8) - Cellular/tissue effects: ECM remodeling with collagen accumulation and elastin fragmentation in aortic media; dysregulated cranial suture biology from altered neural crest progenitor signaling; fibroblast hyper-responsiveness. (kang2021epigeneticmodulationin pages 12-16, doyle2012mutationsinthe pages 1-9, almpani2022loeysdietzandshprintzengoldberg pages 1-2) - Clinical manifestations: Progressive aortic root dilation/aneurysm, craniosynostosis and craniofacial dysmorphology, marfanoid skeletal features, skin and ocular findings. (doyle2012mutationsinthe pages 1-9, almpani2022loeysdietzandshprintzengoldberg pages 1-2)

6) Phenotypic Manifestations (HPO terms with links to mechanisms) - Craniosynostosis (HP:0001363): Premature suture fusion; cranial base angle and craniofacial growth abnormalities quantified in SGS cohort. (almpani2022loeysdietzandshprintzengoldberg pages 1-2) - Aortic root dilatation/aneurysm (HP:0002616/HP:0004942): Media remodeling with ECM dysregulation driven by altered TGF‑β signaling. (doyle2012mutationsinthe pages 1-9, kang2021epigeneticmodulationin pages 12-16) - Marfanoid habitus (HP:0001519), scoliosis (HP:0002650), pectus deformity (HP:0000767/HP:0000768): Connective-tissue manifestations consistent with TGF‑β pathway dysregulation. (doyle2012mutationsinthe pages 1-9) - Ocular features: Hypertelorism (HP:0000316), downslanting palpebral fissures (HP:0000494), myopia (HP:0000545), ectopia lentis variably reported—quantified ophthalmic summary in systematic review. (almpani2022loeysdietzandshprintzengoldberg pages 1-2) - Skin/soft tissue: Skin laxity/abnormal scarring may reflect ECM remodeling and collagen deposition observed in models and patient cells. (kang2021epigeneticmodulationin pages 12-16)

7) Relation to Marfan/Loeys–Dietz and signaling controversy - Doyle et al. reported enhanced TGF‑β signaling in SGS fibroblasts, aligning SGS with MFS/LDS signalopathies that show increased canonical and non‑SMAD signaling and phenotypic rescue by TGF‑β antagonism/ARB in models. (doyle2012mutationsinthe pages 1-9) - Subsequent mechanistic work (e.g., SKI stabilization due to lost pSMAD2/3 binding) indicates attenuation of acute TGF‑β transcriptional responses in engineered cells, yet in vivo SGS mouse models and patient fibroblasts exhibit net increased TGF‑β target expression with heightened H3K27ac, suggesting cell context, time scale, and chromatin cofactor dynamics reconcile the apparent paradox. Therapeutically, CBP/P300 inhibition corrected the in vivo epigenetic/transcriptional phenotype and aortic growth. (kang2021epigeneticmodulationin pages 12-16, kang2021epigeneticmodulationin pages 5-8)

8) Therapeutic implications and real-world considerations - Epigenetic therapy: Pharmacologic CBP/P300 inhibition (C646) reduced H3K27ac, normalized TGF‑β target expression, and prevented aortic root enlargement in Ski-mutant and Fbn1C1039G/+ mice, highlighting a mechanistically anchored strategy under preclinical evaluation. (kang2021epigeneticmodulationin pages 12-16) - TGF‑β pathway modulation: ARBs (e.g., losartan) have been effective in related TGF‑β signalopathies in preclinical and selected clinical contexts; while SGS-specific trials are lacking here, these data motivate individualized consideration under expert care. (kang2021epigeneticmodulationin pages 1-5) - Multidisciplinary management: Given severe craniofacial involvement, airway compromise, and aortic disease, coordinated craniofacial, cardiology, genetics, and ophthalmology care is indicated; Almpani et al. demonstrate objective craniofacial clustering and airway metrics in SGS/LDS cohorts. (almpani2022loeysdietzandshprintzengoldberg pages 1-2)

Embedded artifact summary table | Entity | Identifier (ontology) | Role in SGS Pathophysiology | Pathway / Process (GO terms) | Primary Cell Types (CL) | Primary Tissues / Organs (UBERON) | Key Evidence (DOI / URL with citation) | |---|---|---|---|---|---|---| | SKI | HGNC:10896 (SKI) | Transcriptional corepressor of TGF-β/SMADs; SGS-causing missense variants cluster in the N-terminal R‑SMAD / SMAD‑binding hotspot (exon 1) → impaired pSMAD2/3 binding, SKI stabilization and altered cofactor displacement, leading to dysregulated TGF‑β target transcription and chromatin changes. | TGF‑β signaling regulation (GO:0007179); transcriptional repression / chromatin modulation (histone acetylation changes, H3K27ac) | Vascular smooth muscle cell (CL:0000192); fibroblast (CL:0000057); neural progenitors | Aorta (UBERON:0000947); cranial structures / sutures (UBERON:0003681); skin (UBERON:0002097) | Doyle et al., Nat Genet 2012 doi:10.1038/ng.2421 https://doi.org/10.1038/ng.2421 (doyle2012mutationsinthe pages 1-9); Schepers et al., Eur J Hum Genet 2015 doi:10.1038/ejhg.2014.61 https://doi.org/10.1038/ejhg.2014.61 (schepers2015thesmadbindingdomain pages 1-2); Kang et al., bioRxiv 2021 doi:10.1101/2021.02.12.431010 https://doi.org/10.1101/2021.02.12.431010 (kang2021epigeneticmodulationin pages 5-8) | | TGF‑β / SMAD signaling | GO:0007179 (TGF‑β receptor signaling pathway) | Central signaling axis dysregulated in SGS; net effects context-dependent but associated with altered canonical SMAD2/3 responses and downstream target gene programs (matrix, ECM, MMPs, CTGF, SERPINE1). | GO:0007179 (TGF‑β pathway); GO:0006351 (transcription) | VSMC (CL:0000192), fibroblast (CL:0000057), immune cells (e.g., TH17 CL:0001039) | Aorta (UBERON:0000947); craniofacial tissues (UBERON:0003681) | Doyle et al., Nat Genet 2012 (NG doi:10.1038/ng.2421) (doyle2012mutationsinthe pages 1-9); Schepers 2015 (schepers2015thesmadbindingdomain pages 1-2); Kang bioRxiv 2021 (kang2021epigeneticmodulationin pages 12-16) | | SMAD2 / SMAD3 / SMAD4 complexes | HGNC:SMAD2, HGNC:SMAD3, HGNC:SMAD4 | R‑SMADs (SMAD2/3) are SKI interaction partners; loss of regulated SKI–pSMAD binding perturbs SMAD complex turnover, cofactor exchange and transcriptional output. | Canonical SMAD-mediated transcription (GO:0006355 / GO:0007179) | VSMC, fibroblast, neural crest derivatives | Aorta, cranial tissues | Functional interaction and disruption described in Doyle 2012 and Schepers 2015; SKI–SMAD mechanistics and consequences summarized in Kang et al., bioRxiv 2021 (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2, kang2021epigeneticmodulationin pages 5-8) | | CBP / P300 (CREBBP / EP300) | HGNC:CREBBP, HGNC:EP300 | Histone acetyltransferases that deposit H3K27ac at TGF‑β target regulatory elements; SGS SKI variants fail to displace CBP/P300 from SMAD complexes → increased H3K27ac and sustained target transcription; CBP/P300 inhibition (C646) normalizes acetylation and blunts aneurysm progression in mouse models. | Chromatin acetylation / transcription coactivation (H3K27ac) | VSMC, fibroblast | Aortic media, skin | Kang et al., bioRxiv 2021 doi:10.1101/2021.02.12.431010 (kang2021epigeneticmodulationin pages 12-16, kang2021epigeneticmodulationin pages 5-8) | | HDAC / corepressor complexes (HDAC1, NCoR1, SIN3A) | HGNC:HDAC1, HGNC:NCoR1, HGNC:SIN3A | Components recruited by SKI to repress SMAD-driven transcription; SGS mutations perturb the balance between corepressor (HDAC) recruitment and coactivator (CBP/P300) activity, altering chromatin state. | Histone deacetylation / transcriptional repression | VSMC, fibroblast, neural crest cells | Aorta, craniofacial tissues | Doyle et al., Nat Genet 2012; Schepers et al., Eur J Hum Genet 2015 (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2) | | Vascular smooth muscle cell | CL:0000192 | Key effector cell in aortic pathology; mutant Ski in VSMCs drives increased TGF‑β target expression, ECM remodeling (collagens, MMPs), elastin fragmentation and aortic root dilation in mouse models. | TGF‑β signaling / ECM organization | VSMC (CL:0000192) | Aorta (UBERON:0000947) | Kang et al., bioRxiv 2021 (SkiVSMC:G34D/+ model) doi:10.1101/2021.02.12.431010 (kang2021epigeneticmodulationin pages 12-16) | | Fibroblast | CL:0000057 | Patient dermal fibroblasts show altered baseline and TGF‑β–stimulated expression of COL3A1, FN1, SMAD7 and SKI; used as cellular readout of SKI mutation effects. | TGF‑β response / ECM gene expression | Fibroblast (CL:0000057) | Skin (UBERON:0002097) | Kang et al., bioRxiv 2021; Doyle et al., 2012 (kang2021epigeneticmodulationin pages 12-16, doyle2012mutationsinthe pages 1-9) | | Cranial neural crest cell | CL:0002320 | Neural-crest–derived craniofacial progenitors implicated in craniosynostosis and facial dysmorphology; SKI function required during craniofacial development (animal models, morpholino knockdown phenocopy). | Developmental signaling (TGF/BMP cross-talk) | Neural crest derivatives | Cranial sutures (UBERON:0003681) | Doyle et al., Nat Genet 2012; Almpani et al., J Med Genet 2022 (doyle2012mutationsinthe pages 1-9, almpani2022loeysdietzandshprintzengoldberg pages 1-2) | | T helper 17 cell (TH17) | CL:0001039 | SKI–SMAD4 axis regulates TH17 differentiation by controlling chromatin at RORγt locus; SKI degradation is required to reverse SKI–SMAD4 suppression during TH17 development → links SKI to immune modulation in TGF‑β signalopathies. | TGF‑β–dependent T cell differentiation (immune regulation) | TH17 (CL:0001039) | Secondary lymphoid tissues | Zhang et al., Nature 2017 doi:10.1038/nature24283 (cited in evidence syntheses) (kang2021epigeneticmodulationin pages 16-19, doyle2012mutationsinthe pages 1-9) | | Aorta | UBERON:0000947 | Principal clinical site of life‑threatening pathology (aortic root aneurysm/dilation); histology shows elastin fragmentation, collagen accumulation and medial remodeling driven by altered TGF‑β/epigenetic programs. | Vascular development / ECM organization | VSMC, fibroblast | Aorta (UBERON:0000947) | Doyle et al., Nat Genet 2012; Kang et al., bioRxiv 2021 (doyle2012mutationsinthe pages 1-9, kang2021epigeneticmodulationin pages 12-16) | | Cranial suture | UBERON:0003681 | Site of premature fusion (craniosynostosis) in SGS; developmental perturbation linked to aberrant SKI/TGF‑β signaling in cranial neural crest–derived tissues. | Cranial development / ossification | Neural crest progenitors | Cranial sutures (UBERON:0003681) | Almpani et al., J Med Genet 2022; Doyle 2012 (almpani2022loeysdietzandshprintzengoldberg pages 1-2, doyle2012mutationsinthe pages 1-9) | | Skin | UBERON:0002097 | Dermatologic manifestations and fibroblast phenotypes reflect altered ECM deposition (increased fibrillar collagen) and epigenetic changes (H3K27ac) seen in patient cells and mouse models. | ECM organization / chromatin modification | Fibroblast (CL:0000057) | Skin (UBERON:0002097) | Kang et al., bioRxiv 2021 doi:10.1101/2021.02.12.431010 (kang2021epigeneticmodulationin pages 12-16) |

Table: Concise, ontology-aligned summary of key molecular players, cell/tissue involvement, and primary evidence for Shprintzen-Goldberg syndrome, useful for knowledgebase curation and mechanistic overviews.

Evidence quotations (selected mechanistic quotes) - “We identified causative variation in ten individuals with SGS in the proto-oncogene SKI, a known repressor of TGF‑β activity. Cultured dermal fibroblasts from affected individuals showed enhanced activation of TGF‑β signaling cascades and higher expression of TGF‑β–responsive genes relative to control cells.” (Nature Genetics, 2012; doi:10.1038/ng.2421; URL: https://doi.org/10.1038/ng.2421) (doyle2012mutationsinthe pages 1-9) - “The SMAD-binding domain of SKI: a hotspot for de novo mutations causing Shprintzen–Goldberg syndrome.” (EJHG, 2015; doi:10.1038/ejhg.2014.61; URL: https://doi.org/10.1038/ejhg.2014.61) (schepers2015thesmadbindingdomain pages 1-2) - “Aortic root aneurysm in SGS mice is associated with both increased acetylation of histone H3 at lysine-27 (H3K27) and TGFβ target gene expression, all of which can be ameliorated by pharmacological CBP/P300 inhibition in vivo; similar findings were seen in cultured dermal fibroblast from SGS patients.” (bioRxiv preprint, 2021; doi:10.1101/2021.02.12.431010; URL: https://doi.org/10.1101/2021.02.12.431010) (kang2021epigeneticmodulationin pages 12-16) - Craniofacial phenotyping: “increased cranial base angle with shortened anterior cranial base and underdevelopment of the maxilla and mandible… reduced pharyngeal airway in 55%… distinct clustering of patients with SGS… particularly severe phenotype associated with … SKI mutations.” (J Med Genet, 2022; doi:10.1136/jmedgenet-2021-107695; URL: https://doi.org/10.1136/jmedgenet-2021-107695) (almpani2022loeysdietzandshprintzengoldberg pages 1-2)

Expert perspectives and analysis - Foundational discovery and animal/cell data support a unifying model: SKI mutations in SGS disable regulated SKI–R‑SMAD interactions and cofactor exchange, producing sustained TGF‑β target gene activation through increased CBP/P300-driven H3K27ac despite reports of attenuated acute responses in engineered systems. This reconciles the long-standing debate by invoking context-specific kinetics and chromatin state, consistent with in vivo disease phenotypes and therapeutic rescue by CBP/P300 inhibition. (kang2021epigeneticmodulationin pages 12-16, doyle2012mutationsinthe pages 1-9)

Key statistics and data - Genetic architecture: SKI exon 1 hotspot (SMAD-binding domain) accounts for the majority of pathogenic SGS variants identified to date; recurrent substitutions include p.Gly116 and p.Gly117 (Doyle 2012; Schepers 2015). (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2) - Craniofacial cohort (n=44 across LDS/SGS): 84% mandibular retrognathism; 84% flat midface projection; 73% abnormal eye shape; 73% low-set ears; reduced pharyngeal airway in 55% (Almpani 2022; published Dec 2022). (almpani2022loeysdietzandshprintzengoldberg pages 1-2)

References (URLs and publication dates) - Doyle AJ et al. Mutations in the TGF‑β repressor SKI cause Shprintzen‑Goldberg syndrome with aortic aneurysm. Nature Genetics. Published Sep 2012. DOI/URL: https://doi.org/10.1038/ng.2421 (doyle2012mutationsinthe pages 1-9) - Schepers D et al. The SMAD‑binding domain of SKI: a hotspot for de novo mutations causing Shprintzen–Goldberg syndrome. European Journal of Human Genetics. Published Apr 2015. DOI/URL: https://doi.org/10.1038/ejhg.2014.61 (schepers2015thesmadbindingdomain pages 1-2, schepers2015thesmadbindingdomain pages 4-5) - Kang BE et al. Epigenetic modulation in the pathogenesis and treatment of inherited aortic aneurysm conditions. bioRxiv preprint. Posted Feb 2021. DOI/URL: https://doi.org/10.1101/2021.02.12.431010 (kang2021epigeneticmodulationin pages 1-5, kang2021epigeneticmodulationin pages 5-8, kang2021epigeneticmodulationin pages 12-16) - Almpani K et al. Loeys‑Dietz and Shprintzen‑Goldberg syndromes: analysis of TGF‑β‑opathies with craniofacial manifestations using an innovative multimodality method. Journal of Medical Genetics. Published Dec 2022. DOI/URL: https://doi.org/10.1136/jmedgenet-2021-107695 (almpani2022loeysdietzandshprintzengoldberg pages 1-2) - Additional mechanistic background: Zhang S et al. Reversing SKI–SMAD4-mediated suppression is essential for TH17 cell differentiation. Nature. Published Oct 2017. DOI/URL: https://doi.org/10.1038/nature24283 (context for SKI’s role in immune TGF‑β signaling) (kang2021epigeneticmodulationin pages 16-19)

Ontology-ready annotations (examples) - HGNC: SKI (HGNC:10896); SMAD2 (HGNC:6767); SMAD3 (HGNC:6769); SMAD4 (HGNC:6770); CREBBP (HGNC:2348); EP300 (HGNC:3373); HDAC1 (HGNC:4852); SIN3A (HGNC:11128); NCOR1 (HGNC:7664). (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2, kang2021epigeneticmodulationin pages 12-16) - GO BP: TGF‑β receptor signaling pathway (GO:0007179); SMAD protein signal transduction (GO:0060395); regulation of transcription by RNA Pol II (GO:0006357); histone acetylation (GO:0016573); extracellular matrix organization (GO:0030198). (doyle2012mutationsinthe pages 1-9, schepers2015thesmadbindingdomain pages 1-2, kang2021epigeneticmodulationin pages 12-16) - GO CC: SMAD complex (GO:0071141); transcriptional repressor complex (GO:0017053); chromatin (GO:0000785); nucleus (GO:0005634). (schepers2015thesmadbindingdomain pages 1-2, doyle2012mutationsinthe pages 1-9) - HPO: Craniosynostosis (HP:0001363); Aortic root dilatation (HP:0002616); Aortic aneurysm (HP:0004942); Marfanoid habitus (HP:0001519); Scoliosis (HP:0002650); Pectus excavatum/carinatum (HP:0000767/HP:0000768); Hypertelorism (HP:0000316); Downslanting palpebral fissures (HP:0000494); Myopia (HP:0000545). (doyle2012mutationsinthe pages 1-9, almpani2022loeysdietzandshprintzengoldberg pages 1-2) - CL: Vascular smooth muscle cell (CL:0000192); Fibroblast (CL:0000057); Cranial neural crest cell (CL:0002320); TH17 cell (CL:0001039). (kang2021epigeneticmodulationin pages 12-16, doyle2012mutationsinthe pages 1-9, kang2021epigeneticmodulationin pages 16-19) - UBERON: Aorta (UBERON:0000947); Cranial suture (UBERON:0003681); Skin (UBERON:0002097). (doyle2012mutationsinthe pages 1-9, almpani2022loeysdietzandshprintzengoldberg pages 1-2, kang2021epigeneticmodulationin pages 12-16) - CHEBI: Losartan (CHEBI:65330); C646 (CBP/P300 inhibitor; CHEBI:138488). (kang2021epigeneticmodulationin pages 1-5, kang2021epigeneticmodulationin pages 12-16)

Limitations and open questions - Reconciling disparate reports of attenuated versus enhanced TGF‑β responses requires further human tissue studies across developmental windows and cell types. SGS-specific clinical trials of epigenetic or TGF‑β–modulatory therapies have not yet been reported here. (kang2021epigeneticmodulationin pages 12-16, doyle2012mutationsinthe pages 1-9)

References

  1. (doyle2012mutationsinthe pages 1-9): Alexander J Doyle, Jefferson J Doyle, Seneca L Bessling, Samantha Maragh, Mark E Lindsay, Dorien Schepers, Elisabeth Gillis, Geert Mortier, Tessa Homfray, Kimberly Sauls, Russell A Norris, Nicholas D Huso, Dan Leahy, David W Mohr, Mark J Caulfield, Alan F Scott, Anne Destrée, Raoul C Hennekam, Pamela H Arn, Cynthia J Curry, Lut Van Laer, Andrew S McCallion, Bart L Loeys, and Harry C Dietz. Mutations in the tgf-β repressor ski cause shprintzen-goldberg syndrome with aortic aneurysm. Nature genetics, 44:1249-1254, Sep 2012. URL: https://doi.org/10.1038/ng.2421, doi:10.1038/ng.2421. This article has 327 citations and is from a highest quality peer-reviewed journal.

  2. (schepers2015thesmadbindingdomain pages 1-2): Dorien Schepers, Alexander J Doyle, Gretchen Oswald, Elizabeth Sparks, Loretha Myers, Patrick J Willems, Sahar Mansour, Michael A Simpson, Helena Frysira, Anneke Maat-Kievit, Rick Van Minkelen, Jeanette M Hoogeboom, Geert R Mortier, Hannah Titheradge, Louise Brueton, Lois Starr, Zornitza Stark, Charlotte Ockeloen, Charles Marques Lourenco, Ed Blair, Emma Hobson, Jane Hurst, Isabelle Maystadt, Anne Destrée, Katta M Girisha, Michelle Miller, Harry C Dietz, Bart Loeys, and Lut Van Laer. The smad-binding domain of ski: a hotspot for de novo mutations causing shprintzen–goldberg syndrome. European Journal of Human Genetics, 23:224-228, Apr 2015. URL: https://doi.org/10.1038/ejhg.2014.61, doi:10.1038/ejhg.2014.61. This article has 75 citations and is from a domain leading peer-reviewed journal.

  3. (kang2021epigeneticmodulationin pages 12-16): Benjamin E. Kang, Rustam Bagirzadeh, Djahida Bedja, Jefferson J. Doyle, Elena G. MacFarlane, and Harry C. Dietz. Epigenetic modulation in the pathogenesis and treatment of inherited aortic aneurysm conditions. bioRxiv, Feb 2021. URL: https://doi.org/10.1101/2021.02.12.431010, doi:10.1101/2021.02.12.431010. This article has 1 citations and is from a poor quality or predatory journal.

  4. (schepers2015thesmadbindingdomain pages 4-5): Dorien Schepers, Alexander J Doyle, Gretchen Oswald, Elizabeth Sparks, Loretha Myers, Patrick J Willems, Sahar Mansour, Michael A Simpson, Helena Frysira, Anneke Maat-Kievit, Rick Van Minkelen, Jeanette M Hoogeboom, Geert R Mortier, Hannah Titheradge, Louise Brueton, Lois Starr, Zornitza Stark, Charlotte Ockeloen, Charles Marques Lourenco, Ed Blair, Emma Hobson, Jane Hurst, Isabelle Maystadt, Anne Destrée, Katta M Girisha, Michelle Miller, Harry C Dietz, Bart Loeys, and Lut Van Laer. The smad-binding domain of ski: a hotspot for de novo mutations causing shprintzen–goldberg syndrome. European Journal of Human Genetics, 23:224-228, Apr 2015. URL: https://doi.org/10.1038/ejhg.2014.61, doi:10.1038/ejhg.2014.61. This article has 75 citations and is from a domain leading peer-reviewed journal.

  5. (kang2021epigeneticmodulationin pages 1-5): Benjamin E. Kang, Rustam Bagirzadeh, Djahida Bedja, Jefferson J. Doyle, Elena G. MacFarlane, and Harry C. Dietz. Epigenetic modulation in the pathogenesis and treatment of inherited aortic aneurysm conditions. bioRxiv, Feb 2021. URL: https://doi.org/10.1101/2021.02.12.431010, doi:10.1101/2021.02.12.431010. This article has 1 citations and is from a poor quality or predatory journal.

  6. (kang2021epigeneticmodulationin pages 5-8): Benjamin E. Kang, Rustam Bagirzadeh, Djahida Bedja, Jefferson J. Doyle, Elena G. MacFarlane, and Harry C. Dietz. Epigenetic modulation in the pathogenesis and treatment of inherited aortic aneurysm conditions. bioRxiv, Feb 2021. URL: https://doi.org/10.1101/2021.02.12.431010, doi:10.1101/2021.02.12.431010. This article has 1 citations and is from a poor quality or predatory journal.

  7. (kang2021epigeneticmodulationin pages 16-19): Benjamin E. Kang, Rustam Bagirzadeh, Djahida Bedja, Jefferson J. Doyle, Elena G. MacFarlane, and Harry C. Dietz. Epigenetic modulation in the pathogenesis and treatment of inherited aortic aneurysm conditions. bioRxiv, Feb 2021. URL: https://doi.org/10.1101/2021.02.12.431010, doi:10.1101/2021.02.12.431010. This article has 1 citations and is from a poor quality or predatory journal.

  8. (almpani2022loeysdietzandshprintzengoldberg pages 1-2): Konstantinia Almpani, Denise K. Liberton, Priyam Jani, Cyrus Keyvanfar, Rashmi Mishra, Natasha Curry, Pamela Orzechowski, Pamela A. Frischmeyer-Guerrerio, and Janice S. Lee. Loeys-dietz and shprintzen-goldberg syndromes: analysis of tgf-β-opathies with craniofacial manifestations using an innovative multimodality method. Journal of Medical Genetics, 59:938-946, Dec 2022. URL: https://doi.org/10.1136/jmedgenet-2021-107695, doi:10.1136/jmedgenet-2021-107695. This article has 20 citations and is from a domain leading peer-reviewed journal.