Elsahy-Waters syndrome (EWS), also termed branchio-skeleto-genital (BSG) syndrome, is an ultra-rare autosomal recessive multiple congenital anomaly / intellectual disability syndrome caused by biallelic loss-of-function variants in CDH11, which encodes the type II classical cadherin cadherin-11 (OB-cadherin). It is characterized by a distinctive craniofacial gestalt (hypertelorism, brachycephaly, facial asymmetry, midface hypoplasia, mandibular prognathism), severe dental disease (radicular dentin dysplasia with premature tooth loss), vertebral fusions, hypospadias in males, and intellectual disability. First described by Elsahy and Waters in 1971 in three affected brothers; CDH11 was identified as the causal gene in 2018. Heterozygous CDH11 missense variants cause the distinct allelic Teebi hypertelorism syndrome.
Ask a research question about Elsahy-Waters Syndrome. OpenScientist will conduct autonomous deep research using the Disorder Mechanisms Knowledge Base and PubMed literature (typically 10-30 minutes).
Do not include personal health information in your question. Questions and results are cached in your browser's local storage.
name: Elsahy-Waters Syndrome
creation_date: "2026-06-30T00:00:00Z"
category: Mendelian
disease_term:
preferred_term: Elsahy-Waters syndrome
term:
id: MONDO:0008885
label: Elsahy-Waters syndrome
parents:
- Multiple Congenital Anomalies Syndrome
description: >-
Elsahy-Waters syndrome (EWS), also termed branchio-skeleto-genital (BSG)
syndrome, is an ultra-rare autosomal recessive multiple congenital
anomaly / intellectual disability syndrome caused by biallelic
loss-of-function variants in CDH11, which encodes the type II classical
cadherin cadherin-11 (OB-cadherin). It is characterized by a distinctive
craniofacial gestalt (hypertelorism, brachycephaly, facial asymmetry,
midface hypoplasia, mandibular prognathism), severe dental disease
(radicular dentin dysplasia with premature tooth loss), vertebral fusions,
hypospadias in males, and intellectual disability. First described by Elsahy
and Waters in 1971 in three affected brothers; CDH11 was identified as the
causal gene in 2018. Heterozygous CDH11 missense variants cause the distinct
allelic Teebi hypertelorism syndrome.
inheritance:
- name: Autosomal recessive inheritance
inheritance_term:
preferred_term: Autosomal recessive inheritance
term:
id: HP:0000007
label: Autosomal recessive inheritance
description: >-
EWS is inherited in an autosomal recessive manner. Parental consanguinity
has been documented in reported families, and an affected woman and her
affected brother born to consanguineous parents established recessive
inheritance, refuting earlier X-linked hypotheses based on the original
report of three affected brothers.
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "The present report of an affected woman and her brother, born to consanguineous parents, supports autosomal recessive inheritance of this condition."
explanation: >-
Castori et al. 2010 established autosomal recessive inheritance based on
an affected woman and her brother born to consanguineous parents.
genetic:
- name: CDH11
gene_term:
preferred_term: CDH11
term:
id: hgnc:1750
label: CDH11
association: Causative
notes: >-
CDH11 (cadherin-11 / OB-cadherin, OMIM 600023, chromosome 16q21) is the
sole gene known to cause Elsahy-Waters syndrome. Biallelic truncating
(loss-of-function) variants, such as the homozygous nonsense variant
c.127A>T (p.Lys43*) in the first exon, abolish functional protein.
Heterozygous missense variants in the same gene cause the allelic but
phenotypically distinct Teebi hypertelorism syndrome (OMIM 145420).
evidence:
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "Exome sequencing led to the identification of a novel homozygous nonsense variant in the first exon of the cadherin-11 gene (CDH11), which results in a prematurely truncated form of the protein."
explanation: >-
Castori et al. 2018 identified a homozygous truncating CDH11 variant as
the cause of BSG (Elsahy-Waters) syndrome by exome sequencing.
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "This study identifies a novel loss-of-function variant in CDH11 as a cause of BSGS and supports the role of cadherin-11 as a key player in axial and craniofacial malformations."
explanation: >-
Establishes the loss-of-function mechanism and cadherin-11's role in
axial and craniofacial development.
- reference: PMID:33811546
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "Homozygous variants in CDH11 truncating the transmembrane and intracellular domains have been implicated in Elsahy-Waters syndrome (EWS; OMIM 211380) with hypertelorism."
explanation: >-
Li et al. 2021 confirm that biallelic CDH11 truncating variants cause
EWS, contrasting with the heterozygous missense mechanism of Teebi
hypertelorism syndrome.
pathophysiology:
- name: Cadherin-11 Loss of Function
description: >-
Biallelic loss-of-function (truncating) variants in CDH11 eliminate or
severely truncate cadherin-11, a type II classical cadherin that mediates
calcium-dependent homophilic cell-cell adhesion. Truncation of the
transmembrane and intracellular domains prevents membrane anchoring and
abolishes adhesive and signaling function. This is the initiating molecular
lesion of Elsahy-Waters syndrome.
biological_processes:
- preferred_term: Calcium-dependent cell-cell adhesion
term:
id: GO:0016339
label: calcium-dependent cell-cell adhesion
modifier: DECREASED
cell_types:
- preferred_term: Mesenchymal stem cell
term:
id: CL:0000134
label: mesenchymal stem cell
- preferred_term: Fibroblast
term:
id: CL:0000057
label: fibroblast
evidence:
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "Cadherins are cell-adhesion molecules that control morphogenesis, cell migration, and cell shape changes during multiple developmental processes."
explanation: >-
Establishes cadherin-11 as a developmental cell-adhesion molecule whose
loss disrupts morphogenesis.
- reference: PMID:33811546
supports: SUPPORT
evidence_source: COMPUTATIONAL
snippet: "Six of the variants that cluster around the EC2-EC3 and EC3-EC4 linker regions are predicted to affect Ca2+ binding that is required for cadherin stability."
explanation: >-
Functional analysis of CDH11 variants shows disruption of Ca2+-dependent
cadherin stability, the molecular basis of the adhesion defect.
downstream:
- target: Impaired Cranial Neural Crest and Mesenchymal Cell Behavior
description: >-
Loss of cadherin-11 adhesion disrupts cranial neural crest cell
migration and mesenchymal cell adhesion, morphology, and migratory
behavior during craniofacial morphogenesis.
causal_link_type: DIRECT
- target: Delayed Osteogenic and Odontogenic Differentiation
description: >-
Cadherin-11 is prevalently expressed in osteoblastic lineages and is
required for normal osteogenic and odontoblastic differentiation; its
loss delays bone and dentin formation.
causal_link_type: INDIRECT_KNOWN_INTERMEDIATES
- target: Intellectual disability
description: >-
Cadherin-11 mediates neuronal cell-cell adhesion in the developing brain;
loss of this adhesion is proposed to underlie the neurodevelopmental
impairment of EWS. The precise human intermediates are not established.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- name: Impaired Cranial Neural Crest and Mesenchymal Cell Behavior
description: >-
Cadherin-11 is strongly expressed in human facial mesenchyme and regulates
cranial neural crest cell migration and mesenchymal cell adhesion. Loss of
function reduces cell-substrate adhesion and alters cell morphology, focal
adhesion, and migration, perturbing the morphogenetic movements that shape
the craniofacial skeleton and axial structures.
biological_processes:
- preferred_term: Neural crest cell migration
term:
id: GO:0001755
label: neural crest cell migration
modifier: DECREASED
- preferred_term: Cell migration
term:
id: GO:0016477
label: cell migration
modifier: DECREASED
cell_types:
- preferred_term: Neural crest cell
term:
id: CL:0011012
label: neural crest cell
- preferred_term: Fibroblast
term:
id: CL:0000057
label: fibroblast
evidence:
- reference: PMID:33811546
supports: SUPPORT
evidence_source: IN_VITRO
snippet: "Immunohistochemical study demonstrates that CDH11 is strongly expressed in human facial mesenchyme."
explanation: >-
CDH11 expression in human facial mesenchyme supports its role in
craniofacial mesenchymal development.
- reference: PMID:33811546
supports: SUPPORT
evidence_source: IN_VITRO
snippet: "we show that five variants from the EC1, EC2-EC3 linker, and EC3 regions significantly reduced the cell-substrate trans adhesion activity and one variant from EC3-EC4 linker results in changes in cell morphology, focal adhesion, and migration"
explanation: >-
Functional assays demonstrate that CDH11 variants reduce cell-substrate
adhesion and alter migration, the cellular defect underlying abnormal
craniofacial and axial morphogenesis.
downstream:
- target: Abnormal Craniofacial and Axial Morphogenesis
description: >-
Disrupted neural crest and mesenchymal cell migration and adhesion lead
to abnormal patterning of the craniofacial skeleton and vertebral column.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Hypospadias
description: >-
Impaired mesenchymal cell adhesion and migration during genital tubercle
development produce the ventral urethral defect (hypospadias).
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- name: Delayed Osteogenic and Odontogenic Differentiation
description: >-
Cadherin-11 (OB-cadherin) is prevalently expressed in osteoblastic cell
lines and up-regulated during differentiation, indicating a specific role
in bone formation. It is also required for odontoblastic differentiation of
dental mesenchymal stem cells. Loss of cadherin-11 delays osteogenic and
odontoblastic differentiation, impairing bone and dentin formation.
biological_processes:
- preferred_term: Osteoblast differentiation
term:
id: GO:0001649
label: osteoblast differentiation
modifier: DECREASED
- preferred_term: Odontogenesis of dentin-containing tooth
term:
id: GO:0042475
label: odontogenesis of dentin-containing tooth
modifier: DECREASED
cell_types:
- preferred_term: Osteoblast
term:
id: CL:0000062
label: osteoblast
- preferred_term: Odontoblast
term:
id: CL:0000060
label: odontoblast
evidence:
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "its prevalent expression in osteoblastic cell lines and up-regulation during differentiation suggest a specific function in bone formation and development."
explanation: >-
Cadherin-11's osteoblast-restricted expression and up-regulation during
differentiation support its role in bone formation, whose impairment
underlies the skeletal phenotype.
- reference: PMID:37818127
supports: SUPPORT
evidence_source: IN_VITRO
snippet: "Mutations or dysregulation of related genes may contribute to genetic diseases with dentin defects caused by impaired odontoblastic differentiation, including tricho-dento-osseous (TDO) syndrome, X-linked hypophosphatemic rickets (XLH), Raine syndrome (RS), hypophosphatasia (HPP), Schimke immuno-osseous dysplasia (SIOD), and Elsahy-Waters syndrome (EWS)."
explanation: >-
Pan et al. 2023 link Elsahy-Waters syndrome to impaired odontoblastic
differentiation of dental mesenchymal stem cells, the basis of the
radicular dentin dysplasia.
downstream:
- target: Dentin Dysplasia
description: >-
Impaired odontoblastic differentiation produces defective dentin,
manifesting as radicular dentin dysplasia with shortened roots.
causal_link_type: INDIRECT_KNOWN_INTERMEDIATES
- target: Premature loss of teeth
description: >-
Defective dentin and supporting alveolar bone lead to progressive
premature tooth loss.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- name: Abnormal Craniofacial and Axial Morphogenesis
description: >-
The combined adhesion, migration, and differentiation defects converge on
abnormal morphogenesis of the craniofacial skeleton and vertebral column,
producing the characteristic facial gestalt and vertebral fusions of EWS.
The facial phenotype evolves with age and becomes more recognizable in
adulthood.
biological_processes:
- preferred_term: Bone morphogenesis
term:
id: GO:0060349
label: bone morphogenesis
modifier: ABNORMAL
cell_types:
- preferred_term: Osteoblast
term:
id: CL:0000062
label: osteoblast
evidence:
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "This study identifies a novel loss-of-function variant in CDH11 as a cause of BSGS and supports the role of cadherin-11 as a key player in axial and craniofacial malformations."
explanation: >-
Directly links CDH11 loss of function to axial and craniofacial
malformations.
downstream:
- target: Hypertelorism
description: Abnormal craniofacial morphogenesis produces hypertelorism.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Brachycephaly
description: Abnormal cranial morphogenesis produces brachycephaly.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Facial asymmetry
description: Abnormal craniofacial morphogenesis produces facial asymmetry.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Exotropia
description: Abnormal craniofacial/orbital morphogenesis produces divergent strabismus (exotropia).
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Wide nose
description: Abnormal facial morphogenesis produces a broad nose with concave ridge.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Midface retrusion
description: Maxillary / midface hypoplasia results from abnormal facial morphogenesis.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Mandibular prognathia
description: Abnormal lower-face morphogenesis produces mandibular prognathism.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
- target: Fused cervical vertebrae
description: Abnormal axial morphogenesis produces congenital vertebral fusion.
causal_link_type: INDIRECT_UNKNOWN_INTERMEDIATES
phenotypes:
- category: Craniofacial
name: Hypertelorism
description: >-
Markedly increased interorbital distance is a core recognizable feature,
present in essentially all reported patients.
phenotype_term:
preferred_term: Hypertelorism
term:
id: HP:0000316
label: Hypertelorism
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Hypertelorism is part of the characteristic craniofacial morphology of EWS.
- category: Craniofacial
name: Brachycephaly
description: Shortened anteroposterior skull shape.
phenotype_term:
preferred_term: Brachycephaly
term:
id: HP:0000248
label: Brachycephaly
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Brachycephaly is part of the characteristic craniofacial morphology of EWS.
- category: Craniofacial
name: Facial asymmetry
description: Persistent asymmetry of the facial contour.
phenotype_term:
preferred_term: Facial asymmetry
term:
id: HP:0000324
label: Facial asymmetry
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Facial asymmetry is part of the characteristic craniofacial morphology of EWS.
- category: Craniofacial
name: Midface retrusion
description: Underdeveloped midface / maxillary region contributing to the characteristic profile.
phenotype_term:
preferred_term: Midface retrusion
term:
id: HP:0011800
label: Midface retrusion
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Underdeveloped midface (midface retrusion) is part of the characteristic craniofacial morphology of EWS.
- category: Craniofacial
name: Wide nose
description: Broad nasal bridge, sometimes with a concave nasal ridge.
phenotype_term:
preferred_term: Wide nose
term:
id: HP:0000445
label: Wide nose
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Broad nose is part of the characteristic craniofacial morphology of EWS.
- category: Craniofacial
name: Mandibular prognathia
description: Forward projection of the mandible with characteristic lower-face prominence.
phenotype_term:
preferred_term: Mandibular prognathia
term:
id: HP:0000303
label: Mandibular prognathia
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Prognathism is part of the characteristic craniofacial morphology of EWS.
- category: Dental
name: Dentin Dysplasia
description: >-
Radicular dentin dysplasia with severe root malformation (shortened roots,
obliterated pulp chambers) is the hallmark dental feature.
phenotype_term:
preferred_term: Radicular dentin dysplasia
term:
id: HP:0033784
label: Dentin dysplasia
clinical_course: PROGRESSIVE
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Radicular dentin dysplasia is a hallmark feature of EWS.
- category: Dental
name: Premature loss of teeth
description: Progressive early loss of teeth, often severe enough to impair chewing.
phenotype_term:
preferred_term: Premature loss of teeth
term:
id: HP:0006480
label: Premature loss of teeth
clinical_course: PROGRESSIVE
evidence:
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "Branchio-skeleto-genital (or Elsahy-Waters) syndrome (BSGS) is an ultra-rare condition featuring a characteristic face, premature loss of teeth, vertebral and genital anomalies, and intellectual disability."
explanation: Premature loss of teeth is a defining feature of EWS.
- category: Skeletal
name: Fused cervical vertebrae
description: >-
Congenital vertebral synostosis, especially of the cervical spine
(e.g., C2-C3); part of the vertebral anomalies of EWS.
phenotype_term:
preferred_term: Cervical vertebral fusion
term:
id: HP:0002949
label: Fused cervical vertebrae
evidence:
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "Branchio-skeleto-genital (or Elsahy-Waters) syndrome (BSGS) is an ultra-rare condition featuring a characteristic face, premature loss of teeth, vertebral and genital anomalies, and intellectual disability."
explanation: Vertebral anomalies (including cervical vertebral fusion) are a defining feature of EWS.
- category: Genitourinary
name: Hypospadias
description: >-
Urethral opening on the ventral penis; a recurrent male genital anomaly
present in affected males reported to date.
phenotype_term:
preferred_term: Hypospadias
term:
id: HP:0000047
label: Hypospadias
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "Elsahy-Waters or branchioskeletogenital syndrome is a rare MCA/MR syndrome characterized by moderate mental retardation, hypospadias and characteristic craniofacial morphology"
explanation: Hypospadias is a defining feature of EWS.
- category: Craniofacial
name: Exotropia
description: Divergent strabismus, part of the characteristic craniofacial morphology of EWS.
phenotype_term:
preferred_term: Exotropia
term:
id: HP:0000577
label: Exotropia
evidence:
- reference: PMID:20949527
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "characteristic craniofacial morphology, which includes brachycephaly, facial asymmetry, exotropia, hypertelorism/telechantus, broad nose, concave nasal ridge, underdeveloped midface, prognathism, and radicular dentin dysplasia."
explanation: Exotropia is part of the characteristic craniofacial morphology of EWS.
- category: Neurodevelopmental
name: Intellectual disability
description: >-
Typically mild-to-moderate cognitive impairment with delayed psychomotor
development; a key feature distinguishing EWS from dominant CDH11-related
Teebi hypertelorism syndrome.
phenotype_term:
preferred_term: Intellectual disability
term:
id: HP:0001249
label: Intellectual disability
evidence:
- reference: PMID:30194892
supports: SUPPORT
evidence_source: HUMAN_CLINICAL
snippet: "Branchio-skeleto-genital (or Elsahy-Waters) syndrome (BSGS) is an ultra-rare condition featuring a characteristic face, premature loss of teeth, vertebral and genital anomalies, and intellectual disability."
explanation: Intellectual disability is a defining feature of EWS.
datasets: []
Elsahy-Waters syndrome (EWS), also known as branchioskeletogenital syndrome (BSGS), is an ultra-rare autosomal recessive multiple congenital anomaly/intellectual disability (MCA/MR) syndrome characterized by distinctive craniofacial features, premature loss of teeth with radicular dentin dysplasia, vertebral and genital anomalies, and intellectual disability (castori2018anovelmutation pages 1-2, castori2010elsahy–waterssyndromeevidence pages 1-2). The condition was first described in 1971 by Elsahy and Waters in three affected brothers (castori2010elsahy–waterssyndromeevidence pages 4-6). CDH11 was identified as the causal gene in 2017–2018 through exome sequencing studies (castori2018anovelmutation pages 1-2, castori2018anovelmutation pages 2-4).
The following table summarizes the disease identifiers, nomenclature, and core genetic information:
| Category | Identifier/Detail | Source |
|---|---|---|
| Disease name | Elsahy-Waters syndrome | (castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 1-2) |
| OMIM disease ID | OMIM: 211380 | (li2021pathogenicvariantsin pages 9-11) |
| MONDO ID | MONDO:0008885 | (OpenTargets Search: Elsahy-Waters syndrome) |
| Synonyms | Branchioskeletogenital syndrome; branchio-skeleto-genital syndrome; BSG syndrome; BSGS | (castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 1-2) |
| Causal gene | CDH11 | (castori2018anovelmutation pages 1-2, OpenTargets Search: Elsahy-Waters syndrome) |
| Gene OMIM ID | OMIM: 600023 | (castori2018anovelmutation pages 1-2) |
| Chromosomal location | 16q21 | (li2021pathogenicvariantsin pages 14-16) |
| Protein | Cadherin-11; OB-cadherin; osteoblast-cadherin | (castori2018anovelmutation pages 1-2, castori2018anovelmutation pages 4-5) |
| Inheritance | Autosomal recessive | (castori2010elsahy–waterssyndromeevidence pages 1-2, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4) |
| Molecular mechanism | Biallelic loss-of-function variants in CDH11 causing prematurely truncated protein and impaired adhesion | (castori2018anovelmutation pages 1-2, castori2018anovelmutation pages 2-4, li2021pathogenicvariantsin pages 1-3) |
| Reported variant classes | Homozygous nonsense and other truncating variants | (castori2018anovelmutation pages 1-2, li2021pathogenicvariantsin pages 9-11, li2021pathogenicvariantsin pages 1-3) |
| Example pathogenic variant | CDH11 c.127A>T (p.Lys43*) homozygous nonsense variant | (castori2018anovelmutation pages 2-4) |
| Functional consequence | Impaired Ca2+-dependent cell adhesion / reduced cell-substrate adhesion; delayed osteogenic differentiation proposed | (li2021pathogenicvariantsin pages 1-3, pan2023theodontoblasticdifferentiation pages 15-16) |
| Relationship to Teebi hypertelorism syndrome | Distinct allelic disorder: heterozygous CDH11 variants cause Teebi hypertelorism syndrome, while biallelic truncating variants cause Elsahy-Waters syndrome | (li2021pathogenicvariantsin pages 9-11, li2021pathogenicvariantsin pages 1-3) |
| Distinguishing clinical-genetic note | Global developmental delay/intellectual disability is emphasized in Elsahy-Waters syndrome and helps distinguish it from many Teebi hypertelorism syndrome cases | (li2021pathogenicvariantsin pages 9-11) |
| Open Targets association | CDH11 is the sole associated target listed for Elsahy-Waters syndrome; association score 0.713 | (OpenTargets Search: Elsahy-Waters syndrome) |
| Reported patients/families through 2018 | Approximately 6 patients from 4 families reported as of 2018 | (castori2018anovelmutation pages 2-4) |
| Additional case after 2018 | First East Asian patient reported in 2021, expanding geographic representation | (OpenTargets Search: Elsahy-Waters syndrome) |
Table: This table summarizes the core disease identifiers, nomenclature, inheritance, and CDH11-related molecular genetics for Elsahy-Waters syndrome. It is useful as a compact reference for knowledge-base curation and for distinguishing this recessive CDH11 disorder from dominant CDH11-related Teebi hypertelorism syndrome.
Information for this entry is derived from aggregated disease-level resources including OMIM (211380), OpenTargets (MONDO:0008885), and published case reports in the primary literature rather than individual patient EHR data (OpenTargets Search: Elsahy-Waters syndrome, castori2010elsahy–waterssyndromeevidence pages 1-2).
Elsahy-Waters syndrome is a monogenic Mendelian disorder caused by biallelic loss-of-function mutations in the CDH11 gene (OMIM 600023) located on chromosome 16q21 (castori2018anovelmutation pages 1-2, castori2018anovelmutation pages 2-4). Cadherins are Ca²⁺-dependent cell-adhesion molecules that control morphogenesis, cell migration, and cell shape changes during multiple developmental processes (castori2018anovelmutation pages 1-2). The identified pathogenic variants include homozygous nonsense mutations resulting in prematurely truncated forms of the cadherin-11 protein, such as c.127A>T (p.Lys43*) (castori2018anovelmutation pages 2-4). There are no known environmental, infectious, or lifestyle risk factors for this genetic condition.
No genetic or environmental protective factors have been identified for this condition. The partial redundancy of cadherin-11 with N-cadherin (CDH2) in bone tissue may mitigate the severity of the skeletal phenotype, as evidenced by the relatively mild skeletal phenotype in Cdh11 null mice compared to compound Cdh2 heterozygous/Cdh11 null mice (castori2018anovelmutation pages 4-5).
The clinical phenotype of EWS is distinctive, multisystemic, and shows both intra-familial and inter-familial variability (castori2010elsahy–waterssyndromeevidence pages 4-6). The facial phenotype evolves with age, initially resembling craniosynostosis syndromes but becoming more characteristic in adulthood (castori2010elsahy–waterssyndromeevidence pages 4-6). The following table provides a comprehensive listing of all reported phenotypic features with suggested HPO terms:
| Organ system | Phenotype/Feature | Description | Frequency (if known) | HPO term | Reference/PMID |
|---|---|---|---|---|---|
| Craniofacial | Brachycephaly / turribrachycephaly | Shortened anteroposterior skull shape; in some reports described as turri-brachycephaly with small skull circumference | Reported in multiple families; exact percentage not available | HP:0000248 Brachycephaly | Castori 2010, Am J Med Genet A 152A:2810-2815 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2010elsahy–waterssyndromeevidence pages 1-2) |
| Craniofacial | Facial asymmetry | Persistent asymmetry of facial contour, sometimes with head tilting | Reported in multiple patients | HP:0000324 Facial asymmetry | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 2-4) |
| Craniofacial | Hypertelorism / telecanthus | Markedly increased interorbital distance; a core recognizable feature | Present in essentially all reported patients described in available case series | HP:0000316 Hypertelorism | Castori 2010; Li 2021 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2010elsahy–waterssyndromeevidence pages 1-2, li2021pathogenicvariantsin pages 9-11) |
| Craniofacial | Proptosis | Prominent globes/orbital protrusion | Reported in several patients | HP:0000520 Proptosis | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2018anovelmutation pages 2-4) |
| Craniofacial | Blepharochalasis | Redundant or lax eyelid tissue | Reported in several patients | HP:0000613 Blepharochalasis | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4) |
| Craniofacial | Midface hypoplasia | Underdeveloped midface/maxillary region contributing to characteristic profile | Common in reported cases | HP:0000340 Midface retrusion | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 2-4) |
| Craniofacial | Broad nose with concave ridge / bulbous or bifid tip | Broad nasal bridge and tip, sometimes with concave nasal ridge or bifid tip | Common in reported cases | HP:0000445 Broad nose; HP:0011120 Concave nasal ridge; HP:0000455 Broad nasal tip | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 2-4) |
| Craniofacial | Prognathism / prominent mandible | Forward projection of mandible with characteristic lower-face prominence | Reported in multiple patients | HP:0000303 Prognathism | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 2-4) |
| Craniofacial | High forehead / bitemporal narrowing | Tall forehead and narrowing of temporal regions | Reported in some patients | HP:0000348 High forehead | Castori 2018 (castori2018anovelmutation pages 2-4) |
| Craniofacial | Strabismus / exotropia | Divergent strabismus/exotropia reported in some individuals | Variable | HP:0000486 Strabismus; HP:0000567 Exotropia | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 4-6, castori2010elsahy–waterssyndromeevidence pages 1-2) |
| Craniofacial / Oropharyngeal | Bifid uvula | Midline split of uvula | Reported in at least one patient/family | HP:0000193 Bifid uvula | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 4-6) |
| Craniofacial / Perioral | Short philtrum and thin upper vermilion | Mild perioral dysmorphism contributing to facial gestalt | Variable | HP:0000322 Short philtrum; HP:0000219 Thin upper lip vermilion | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 4-6) |
| Dental | Radicular dentin dysplasia | Severe root malformation with shortened roots and obliterated pulp chambers; hallmark dental feature | Core feature in reported patients | HP:0006312 Dentin dysplasia | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 2-4) |
| Dental | Dentigerous / apical cysts | Recurrent cysts associated with teeth or apices | Variable; present in some but not all reported patients | HP:0011072 Dentigerous cyst | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4) |
| Dental | Premature tooth loss / early exfoliation | Progressive early loss of teeth, often severe enough to impair chewing | Common and clinically significant | HP:0006480 Premature loss of teeth | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4) |
| Dental | Unerupted or malformed teeth / dysodontiasis | Abnormal tooth eruption and morphology | Variable | HP:0000670 Delayed eruption of teeth; HP:0000684 Abnormality of tooth morphology | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2018anovelmutation pages 2-4) |
| Dental / Jaw | Alveolar bone resorption | Marked alveolar bone loss accompanying dental pathology | Reported in multiple patients | HP:0100259 Abnormal alveolar ridge morphology | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 2-4) |
| Functional impact | Difficulty chewing solid foods | Severe dental disease can prevent normal mastication and compromise oral intake | Reported in affected siblings followed long term | HP:0012537 Dysphagia for solids (closest related term) | Castori 2018 (castori2018anovelmutation pages 2-4) |
| Skeletal | Cervical vertebral fusion (e.g., C2-C3) | Congenital vertebral synostosis, especially in cervical spine | Recurrent feature | HP:0002949 Vertebral fusion | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2010elsahy–waterssyndromeevidence pages 1-2, castori2018anovelmutation pages 2-4) |
| Skeletal | Lumbar vertebral fusion / posterior arch fusion | Fusion involving lumbar vertebrae or posterior arches | Variable | HP:0002949 Vertebral fusion | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4) |
| Skeletal | Scoliosis | Thoracolumbar spinal curvature abnormality | Variable | HP:0002650 Scoliosis | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6) |
| Skeletal | Thick calvaria / cranial bone abnormality | Increased calvarial thickness reported radiographically | Reported in some cases | HP:0000244 Calvarial thickening | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 1-2) |
| Skeletal / Mandible | Thinning of mandible | Radiographic mandibular thinning | Reported in at least one family | HP:0000278 Retrognathia/mandibular anomaly (closest broad term) | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 2-4) |
| Genital | Hypospadias | Urethral opening on ventral penis; recurrent male genital anomaly | Present in affected males reported to date | HP:0000047 Hypospadias | Castori 2010; Castori 2018; Li 2021 (castori2010elsahy–waterssyndromeevidence pages 1-2, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4, li2021pathogenicvariantsin pages 9-11) |
| Genital | Small penis / hypogenitalism | Underdevelopment of external genitalia | Variable among male cases | HP:0000054 Micropenis | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 1-2) |
| Genitourinary | Ureteral stenosis | Structural urinary tract anomaly reported in one case | Rare/isolated report | HP:0012839 Ureter stenosis | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 4-6) |
| Neurological / Developmental | Intellectual disability / developmental delay | Typically mild-to-moderate cognitive impairment with delayed psychomotor development; considered a key distinguishing feature from dominant CDH11-related Teebi syndrome | Reported in all EWS patients summarized by Li 2021 | HP:0001249 Intellectual disability; HP:0001263 Global developmental delay | Castori 2010; Castori 2018; Li 2021 (castori2010elsahy–waterssyndromeevidence pages 1-2, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4, li2021pathogenicvariantsin pages 9-11) |
| Neurological | Microcephaly | Small head circumference reported in some affected individuals | Variable | HP:0000252 Microcephaly | Castori 2018 (castori2018anovelmutation pages 2-4) |
| Neurological | Seizures | Seizure disorder reported in at least one patient | Rare/variable | HP:0001250 Seizure | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 4-6) |
| Auditory | Mixed hearing loss / progressive bilateral hearing loss | Sensorineural-conductive mixed loss, in some cases progressive and bilateral | Variable | HP:0000408 Hearing impairment; HP:0004789 Mixed hearing impairment | Castori 2010; Castori 2018 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6, castori2018anovelmutation pages 2-4) |
| Dermatological | Pachydermia / thick furrowed skin | Thickened furrowed facial skin, especially glabellar region | Reported in some patients | HP:0000974 Hyperkeratosis / HP:0007430 Thickened skin (closest broad term) | Castori 2018; Castori 2010 (castori2018anovelmutation pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6) |
| Dermatological | Glabellar skin wrinkling/furrows | Wrinkling or furrows over glabella contributing to facial appearance | Variable but recurrent | HP:0000997 Abnormality of skin texture | Castori 2010 (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6) |
| Dermatological | Progressive alopecia | Progressive scalp hair loss reported in long-term follow-up of siblings | Reported in some patients | HP:0008070 Alopecia | Castori 2018 (castori2018anovelmutation pages 2-4) |
| Functional / Social | Dependence in adult life | Reported lack of occupational activity and reliance on parental support in adulthood | Observed in 2 adult siblings with long-term follow-up | HP:0033676 Impaired activities of daily living (closest related term) | Castori 2018 (castori2018anovelmutation pages 2-4) |
Table: This table summarizes the reported clinical phenotype spectrum of Elsahy-Waters syndrome across major organ systems, with suggested HPO mappings and supporting citations from the gathered evidence. It is useful for disease knowledge base curation, phenotype annotation, and differential diagnosis.
Age of Onset: Congenital/childhood. The craniofacial gestalt and dental anomalies become more recognizable with age, and cognitive impairment becomes clearer during childhood (castori2010elsahy–waterssyndromeevidence pages 4-6).
Severity: Moderate. Intellectual disability is typically mild to moderate. The dental phenotype, however, is severe and significantly impacts daily functioning, preventing solid food consumption in some patients (castori2018anovelmutation pages 2-4).
Progression: Progressive features include worsening dental pathology (progressive tooth loss, dentigerous cysts), progressive alopecia, and progressive hearing loss in some patients (castori2010elsahy–waterssyndromeevidence pages 2-4, castori2018anovelmutation pages 2-4). The characteristic facial phenotype becomes more pronounced with age (castori2010elsahy–waterssyndromeevidence pages 4-6).
Quality of Life Impact: Severely impacted. Both affected siblings in the study by Castori et al. (2018) were dependent on their parents without occupational activity. The dental complications represent a major clinical burden, impairing mastication and nutritional intake (castori2018anovelmutation pages 2-4).
CDH11 (Cadherin-11; HGNC:1750; OMIM: 600023; Ensembl: ENSG00000140937) on chromosome 16q21 is the sole gene known to cause EWS when mutated in a biallelic fashion (OpenTargets Search: Elsahy-Waters syndrome, castori2018anovelmutation pages 1-2).
Notably, heterozygous missense variants in CDH11 cause a distinct allelic disorder — Teebi hypertelorism syndrome (THS; OMIM 145420) — which presents with hypertelorism but generally normal or only mildly delayed development and minimal skeletal findings, contrasting with the biallelic loss-of-function mechanism in EWS (li2021pathogenicvariantsin pages 9-11, li2021pathogenicvariantsin pages 1-3). This genotype-phenotype correlation distinguishes dominant (haploinsufficiency or dominant-negative) from recessive (complete loss-of-function) CDH11-related conditions.
No specific modifier genes have been identified. However, partial redundancy between CDH11 and CDH2 (N-cadherin) in bone tissue has been demonstrated in mouse models, where compound Cdh2 heterozygous/Cdh11 null mice display more pronounced bone phenotypes than single Cdh11 null mice, suggesting CDH2 may modify disease expression (castori2018anovelmutation pages 4-5).
CDH11 is known to undergo promoter methylation inactivation in certain cancer contexts (Chen et al. 2021, J Cancer 12:1190-1199), but no specific epigenetic findings have been reported in EWS.
No environmental factors, lifestyle factors, or infectious agents have been implicated in the etiology or modification of Elsahy-Waters syndrome. This is consistent with its classification as a Mendelian genetic disorder.
CDH11 encodes cadherin-11 (also termed OB-cadherin or osteoblast-cadherin), a type II classical cadherin that mediates Ca²⁺-dependent homophilic cell-cell adhesion (castori2018anovelmutation pages 1-2, li2021pathogenicvariantsin pages 1-3). Key pathways and molecular mechanisms include:
Cell adhesion and migration: CDH11 localizes to focal adhesions and promotes cell-substrate adhesion. Pathogenic variants reduce cell-to-substrate transadhesion activity and alter fibroblast morphology, with delayed lamellipodia formation and abnormal membrane dynamics observed in patient-derived fibroblasts (li2021pathogenicvariantsin pages 14-16, li2021pathogenicvariantsin pages 17-24, li2021pathogenicvariantsin pages 8-9). CDH11 regulates protrusive activity in cranial neural crest cells through interactions with Trio and small GTPases (GO:0007155 cell adhesion; GO:0016477 cell migration) (li2021pathogenicvariantsin pages 14-16).
TGFβ1/Smad signaling: Cadherin-11 regulates extracellular matrix (ECM) production via the TGFβ1 pathway. Cells lacking cadherin-11 show increased TGFβ1 expression and subsequent translocation of phosphorylated SMAD2/3 into the nucleus, with changes in ECM composition including decreased type VI collagen and increased fibronectin (Passanha et al. 2022, Stem Cells 40:669-677).
RhoA/ROCK signaling: CDH11 modulates RhoA/ROCK pathway activity, which is involved in cytoskeletal organization and fibrosis (Franzè et al. 2020, J Crohn's Colitis 14:406-417).
Smad2/3, ERK1/2, and JNK pathways: RNA-seq of CDH11-null atrial fibroblasts showed significant decreases in transcripts associated with Smad2/3, ERK1/2, and JNK pathways (Cao et al. 2021, J Inflamm Res 14:2897-2911).
The pathophysiological sequence from molecular defect to clinical manifestation proceeds as follows: 1. Initial trigger: Biallelic loss-of-function CDH11 mutations → absence/severe truncation of functional cadherin-11 protein 2. Upstream mechanism: Loss of Ca²⁺-dependent cell-cell adhesion and impaired cell-substrate interactions in mesenchymal tissues 3. Intermediate processes: Disrupted cranial neural crest cell migration, impaired osteoblast differentiation, altered ECM production, and dysregulated TGFβ1/Smad signaling 4. Downstream effects: Abnormal craniofacial morphogenesis, defective bone formation (vertebral fusions, calvarial abnormalities), defective dentin formation (radicular dentin dysplasia), and impaired neurodevelopment 5. Clinical manifestation: The distinctive craniofacial gestalt, dental anomalies, skeletal malformations, genital anomalies, and intellectual disability characteristic of EWS
Cadherin-11 normally contains five extracellular cadherin (EC) repeat domains, a transmembrane domain, and an intracellular domain. The truncating variants identified in EWS eliminate the transmembrane and intracellular domains entirely, preventing membrane anchoring and intracellular signaling (li2021pathogenicvariantsin pages 9-11, li2021pathogenicvariantsin pages 1-3). The Ca²⁺-binding regions between EC domains are critical for cadherin stability, and disruption of these regions impairs the protein's adhesive function (li2021pathogenicvariantsin pages 1-3).
Early dental intervention could potentially improve quality of life, though dental implants have not been feasible in reported cases due to alveolar bone resorption (castori2018anovelmutation pages 2-4).
Diagnosis of EWS is based on recognition of the characteristic clinical phenotype: distinctive craniofacial features (hypertelorism, brachycephaly, midface hypoplasia, facial asymmetry), radicular dentin dysplasia with premature tooth loss, vertebral fusions, hypospadias in males, and intellectual disability (castori2018anovelmutation pages 1-2, castori2010elsahy–waterssyndromeevidence pages 1-2).
No specific mortality data are available for EWS. The condition is not known to be life-limiting, but longitudinal data are extremely limited given the ultra-rarity of the disorder.
No disease-specific pharmacotherapy exists for EWS. Management is entirely symptomatic and supportive (MAXO:0000009 — supportive care).
No clinical trials are registered for EWS on ClinicalTrials.gov. No gene therapy, cell therapy, or targeted therapeutic approaches have been reported or are in development for this condition.
Not applicable as a Mendelian genetic disorder.
No naturally occurring animal model of Elsahy-Waters syndrome has been reported. The disease has not been documented in companion animals or livestock.
CDH11 expression has been documented during zebrafish skull development, and zebrafish models may be useful for studying craniofacial aspects of the syndrome, though no specific EWS zebrafish model has been reported.
OpenTargets (MONDO:0008885) identifies CDH11 (ENSG00000140937) as the sole molecular target associated with Elsahy-Waters syndrome, with an association score of 0.71 based on 5 evidence items from multiple curation sources including ClinGen and the Developmental Disorders Gene Curation Expert Panel (OpenTargets Search: Elsahy-Waters syndrome). Key supporting PMIDs include 28988429, 33811546, 29271567, 27431290, 30194892, and 34278706 (OpenTargets Search: Elsahy-Waters syndrome).
Disease Ontology: - MONDO:0008885 (Elsahy-Waters syndrome) - OMIM:211380
Gene Ontology (Biological Process): - GO:0007155 (cell adhesion) - GO:0016477 (cell migration) - GO:0001649 (osteoblast differentiation) - GO:0060349 (bone morphogenesis) - GO:0007275 (multicellular organism development)
Gene Ontology (Cellular Component): - GO:0005913 (cell-cell adherens junction) - GO:0005925 (focal adhesion) - GO:0016020 (membrane)
Gene Ontology (Molecular Function): - GO:0005509 (calcium ion binding) - GO:0045296 (cadherin binding)
Cell Ontology: - CL:0000062 (osteoblast) - CL:0000060 (odontoblast) - CL:0000134 (mesenchymal stem cell) - CL:0000008 (cranial neural crest cell)
UBERON: - UBERON:0003128 (craniofacial skeleton) - UBERON:0001751 (dentin) - UBERON:0001130 (vertebral column) - UBERON:0000955 (brain)
CHEBI: - CHEBI:29108 (calcium(2+)) — required for CDH11 function
Elsahy-Waters syndrome is an ultra-rare autosomal recessive Mendelian disorder caused by biallelic loss-of-function mutations in CDH11, the gene encoding cadherin-11 (OB-cadherin). As of 2018, approximately 6 patients from 4 families had been reported worldwide, with all families demonstrating consanguinity (castori2018anovelmutation pages 2-4, castori2010elsahy–waterssyndromeevidence pages 4-6). The clinical phenotype encompasses distinctive craniofacial dysmorphism (hypertelorism, brachycephaly, midface hypoplasia), severe dental anomalies (radicular dentin dysplasia, dentigerous cysts, premature tooth loss), skeletal malformations (vertebral fusions), genital anomalies (hypospadias in males), and mild-to-moderate intellectual disability (castori2018anovelmutation pages 1-2, castori2010elsahy–waterssyndromeevidence pages 2-4, castori2018anovelmutation pages 2-4). The molecular pathophysiology involves impaired Ca²⁺-dependent cell adhesion, disrupted cranial neural crest cell migration, and delayed osteogenic differentiation (li2021pathogenicvariantsin pages 14-16, castori2018anovelmutation pages 1-2, pan2023theodontoblasticdifferentiation pages 15-16). No disease-specific therapies exist; management is supportive with particular challenges in dental rehabilitation (castori2018anovelmutation pages 2-4). CDH11 heterozygous variants cause the allelic but phenotypically distinct Teebi hypertelorism syndrome (li2021pathogenicvariantsin pages 9-11). Cdh11 knockout mice provide a partial animal model but exhibit a milder phenotype due to functional redundancy with N-cadherin (castori2018anovelmutation pages 4-5).
References
(castori2018anovelmutation pages 1-2): Marco Castori, Claus‐Eric Ott, Luigi Bisceglia, Maria Pia Leone, Tommaso Mazza, Stefano Castellana, Jurgen Tomassi, Silvia Lanciotti, Stefan Mundlos, Raoul C. Hennekam, Uwe Kornak, and Francesco Brancati. A novel mutation in cdh11, encoding cadherin‐11, cause branchioskeletogenital (elsahy‐waters) syndrome. American Journal of Medical Genetics Part A, 176:2028-2033, Sep 2018. URL: https://doi.org/10.1002/ajmg.a.40379, doi:10.1002/ajmg.a.40379. This article has 8 citations.
(castori2010elsahy–waterssyndromeevidence pages 1-2): Marco Castori, Piero Cascone, Michele Valiante, Luigi Laino, Giorgio Iannetti, Raoul C.M. Hennekam, and Paola Grammatico. Elsahy–waters syndrome: evidence for autosomal recessive inheritance. American Journal of Medical Genetics Part A, 152A:2810-2815, Nov 2010. URL: https://doi.org/10.1002/ajmg.a.33634, doi:10.1002/ajmg.a.33634. This article has 16 citations.
(castori2010elsahy–waterssyndromeevidence pages 4-6): Marco Castori, Piero Cascone, Michele Valiante, Luigi Laino, Giorgio Iannetti, Raoul C.M. Hennekam, and Paola Grammatico. Elsahy–waters syndrome: evidence for autosomal recessive inheritance. American Journal of Medical Genetics Part A, 152A:2810-2815, Nov 2010. URL: https://doi.org/10.1002/ajmg.a.33634, doi:10.1002/ajmg.a.33634. This article has 16 citations.
(castori2018anovelmutation pages 2-4): Marco Castori, Claus‐Eric Ott, Luigi Bisceglia, Maria Pia Leone, Tommaso Mazza, Stefano Castellana, Jurgen Tomassi, Silvia Lanciotti, Stefan Mundlos, Raoul C. Hennekam, Uwe Kornak, and Francesco Brancati. A novel mutation in cdh11, encoding cadherin‐11, cause branchioskeletogenital (elsahy‐waters) syndrome. American Journal of Medical Genetics Part A, 176:2028-2033, Sep 2018. URL: https://doi.org/10.1002/ajmg.a.40379, doi:10.1002/ajmg.a.40379. This article has 8 citations.
(li2021pathogenicvariantsin pages 9-11): Dong Li, Michael E. March, Paola Fortugno, Liza L. Cox, Leticia S. Matsuoka, Rosanna Monetta, Christoph Seiler, Louise C. Pyle, Emma C. Bedoukian, María José Sánchez-Soler, Oana Caluseriu, Katheryn Grand, Allison Tam, Alicia R. P. Aycinena, Letizia Camerota, Yiran Guo, Patrick Sleiman, Bert Callewaert, Candy Kumps, Annelies Dheedene, Michael Buckley, Edwin P. Kirk, Anne Turner, Benjamin Kamien, Chirag Patel, Meredith Wilson, Tony Roscioli, John Christodoulou, Timothy C. Cox, Elaine H. Zackai, Francesco Brancati, Hakon Hakonarson, and Elizabeth J. Bhoj. Pathogenic variants in cdh11 impair cell adhesion and cause teebi hypertelorism syndrome. Human Genetics, 140:1061-1076, Apr 2021. URL: https://doi.org/10.1007/s00439-021-02274-3, doi:10.1007/s00439-021-02274-3. This article has 12 citations and is from a peer-reviewed journal.
(OpenTargets Search: Elsahy-Waters syndrome): Open Targets Query (Elsahy-Waters syndrome, 1 results). Buniello, A. et al. (2025). Open Targets Platform: facilitating therapeutic hypotheses building in drug discovery. Nucleic Acids Research.
(li2021pathogenicvariantsin pages 14-16): Dong Li, Michael E. March, Paola Fortugno, Liza L. Cox, Leticia S. Matsuoka, Rosanna Monetta, Christoph Seiler, Louise C. Pyle, Emma C. Bedoukian, María José Sánchez-Soler, Oana Caluseriu, Katheryn Grand, Allison Tam, Alicia R. P. Aycinena, Letizia Camerota, Yiran Guo, Patrick Sleiman, Bert Callewaert, Candy Kumps, Annelies Dheedene, Michael Buckley, Edwin P. Kirk, Anne Turner, Benjamin Kamien, Chirag Patel, Meredith Wilson, Tony Roscioli, John Christodoulou, Timothy C. Cox, Elaine H. Zackai, Francesco Brancati, Hakon Hakonarson, and Elizabeth J. Bhoj. Pathogenic variants in cdh11 impair cell adhesion and cause teebi hypertelorism syndrome. Human Genetics, 140:1061-1076, Apr 2021. URL: https://doi.org/10.1007/s00439-021-02274-3, doi:10.1007/s00439-021-02274-3. This article has 12 citations and is from a peer-reviewed journal.
(castori2018anovelmutation pages 4-5): Marco Castori, Claus‐Eric Ott, Luigi Bisceglia, Maria Pia Leone, Tommaso Mazza, Stefano Castellana, Jurgen Tomassi, Silvia Lanciotti, Stefan Mundlos, Raoul C. Hennekam, Uwe Kornak, and Francesco Brancati. A novel mutation in cdh11, encoding cadherin‐11, cause branchioskeletogenital (elsahy‐waters) syndrome. American Journal of Medical Genetics Part A, 176:2028-2033, Sep 2018. URL: https://doi.org/10.1002/ajmg.a.40379, doi:10.1002/ajmg.a.40379. This article has 8 citations.
(li2021pathogenicvariantsin pages 1-3): Dong Li, Michael E. March, Paola Fortugno, Liza L. Cox, Leticia S. Matsuoka, Rosanna Monetta, Christoph Seiler, Louise C. Pyle, Emma C. Bedoukian, María José Sánchez-Soler, Oana Caluseriu, Katheryn Grand, Allison Tam, Alicia R. P. Aycinena, Letizia Camerota, Yiran Guo, Patrick Sleiman, Bert Callewaert, Candy Kumps, Annelies Dheedene, Michael Buckley, Edwin P. Kirk, Anne Turner, Benjamin Kamien, Chirag Patel, Meredith Wilson, Tony Roscioli, John Christodoulou, Timothy C. Cox, Elaine H. Zackai, Francesco Brancati, Hakon Hakonarson, and Elizabeth J. Bhoj. Pathogenic variants in cdh11 impair cell adhesion and cause teebi hypertelorism syndrome. Human Genetics, 140:1061-1076, Apr 2021. URL: https://doi.org/10.1007/s00439-021-02274-3, doi:10.1007/s00439-021-02274-3. This article has 12 citations and is from a peer-reviewed journal.
(pan2023theodontoblasticdifferentiation pages 15-16): Houwen Pan, Yiling Yang, Hongyuan Xu, Anting Jin, Xiangru Huang, Xin Gao, Siyuan Sun, Yuanqi Liu, Jingyi Liu, Tingwei Lu, Xinyu Wang, Yanfei Zhu, and Lingyong Jiang. The odontoblastic differentiation of dental mesenchymal stem cells: molecular regulation mechanism and related genetic syndromes. Frontiers in Cell and Developmental Biology, Sep 2023. URL: https://doi.org/10.3389/fcell.2023.1174579, doi:10.3389/fcell.2023.1174579. This article has 35 citations.
(castori2010elsahy–waterssyndromeevidence pages 2-4): Marco Castori, Piero Cascone, Michele Valiante, Luigi Laino, Giorgio Iannetti, Raoul C.M. Hennekam, and Paola Grammatico. Elsahy–waters syndrome: evidence for autosomal recessive inheritance. American Journal of Medical Genetics Part A, 152A:2810-2815, Nov 2010. URL: https://doi.org/10.1002/ajmg.a.33634, doi:10.1002/ajmg.a.33634. This article has 16 citations.
(li2021pathogenicvariantsin pages 17-24): Dong Li, Michael E. March, Paola Fortugno, Liza L. Cox, Leticia S. Matsuoka, Rosanna Monetta, Christoph Seiler, Louise C. Pyle, Emma C. Bedoukian, María José Sánchez-Soler, Oana Caluseriu, Katheryn Grand, Allison Tam, Alicia R. P. Aycinena, Letizia Camerota, Yiran Guo, Patrick Sleiman, Bert Callewaert, Candy Kumps, Annelies Dheedene, Michael Buckley, Edwin P. Kirk, Anne Turner, Benjamin Kamien, Chirag Patel, Meredith Wilson, Tony Roscioli, John Christodoulou, Timothy C. Cox, Elaine H. Zackai, Francesco Brancati, Hakon Hakonarson, and Elizabeth J. Bhoj. Pathogenic variants in cdh11 impair cell adhesion and cause teebi hypertelorism syndrome. Human Genetics, 140:1061-1076, Apr 2021. URL: https://doi.org/10.1007/s00439-021-02274-3, doi:10.1007/s00439-021-02274-3. This article has 12 citations and is from a peer-reviewed journal.
(li2021pathogenicvariantsin pages 8-9): Dong Li, Michael E. March, Paola Fortugno, Liza L. Cox, Leticia S. Matsuoka, Rosanna Monetta, Christoph Seiler, Louise C. Pyle, Emma C. Bedoukian, María José Sánchez-Soler, Oana Caluseriu, Katheryn Grand, Allison Tam, Alicia R. P. Aycinena, Letizia Camerota, Yiran Guo, Patrick Sleiman, Bert Callewaert, Candy Kumps, Annelies Dheedene, Michael Buckley, Edwin P. Kirk, Anne Turner, Benjamin Kamien, Chirag Patel, Meredith Wilson, Tony Roscioli, John Christodoulou, Timothy C. Cox, Elaine H. Zackai, Francesco Brancati, Hakon Hakonarson, and Elizabeth J. Bhoj. Pathogenic variants in cdh11 impair cell adhesion and cause teebi hypertelorism syndrome. Human Genetics, 140:1061-1076, Apr 2021. URL: https://doi.org/10.1007/s00439-021-02274-3, doi:10.1007/s00439-021-02274-3. This article has 12 citations and is from a peer-reviewed journal.