Introduction: NOTCH3, one of the four mammalian Notch receptors, acts as a transcriptional activator in a variety of tissues. Variants in NOTCH3 lead to distinct phenotypes, depending on variant type and location. Truncating variants in the last exon generate a protein lacking the PEST domain, responsible for degradation, leading to a gain-of-function effect and causing Lateral Meningoceles syndrome (LMS), characterized by dysmorphisms and variable cardiac, skeletal, and connective tissue abnormalities; motor delay may occur, but the cognitive function is usually normal. Case Presentation: We report the first case of prenatal molecular diagnosis of LMS, which was made using prenatal exome sequencing after an ultrasound with findings of fetal cystic hygroma, mild bilateral ventriculomegaly, and facial dysmorphisms. After birth, magnetic resonance imaging confirmed the presence of lateral meningoceles. A complete clinical evaluation was performed and unexpected biliary anomalies were found. Conclusion: The occurrence of biliary anomalies has not been previously reported in LMS but may have biological plausibility. Expression of NOTCH3 has been demonstrated in biliary development and is thought to play a role in the differentiation of hepatoblasts into biliary epithelial cells, and also in liver regeneration and repair. We hypothesize that the findings reported here might expand the phenotype of LMS.

1.
Gripp
KW
,
Robbins
KM
,
Sobreira
NL
,
Witmer
PD
,
Bird
LM
,
Avela
K
, et al
.
Truncating mutations in the last exon of NOTCH3 cause lateral meningocele syndrome
.
Am J Med Genet
.
2015
;
167A
(
2
):
271
81
.
2.
Meng
H
,
Zhang
X
,
Yu
G
,
Lee
SJ
,
Chen
YE
,
Prudovsky
I
, et al
.
Biochemical characterization and cellular effects of CADASIL mutants of NOTCH3
.
PLoS One
.
2012
;
7
(
9
):
e44964
.
3.
Wu
D
,
Wang
S
,
Oliveira
DV
,
Del Gaudio
F
,
Vanlandewijck
M
,
Lebouvier
T
, et al
.
The infantile myofibromatosis NOTCH3 L1519P mutation leads to hyperactivated ligand-independent Notch signaling and increased PDGFRB expression
.
Dis Model Mech
.
2021
;
14
(
2
):
dmm046300
.
4.
Stellingwerff
MD
,
Nulton
C
,
Helman
G
,
Roosendaal
SD
,
Benko
WS
,
Pizzino
A
, et al
.
Early-onset vascular leukoencephalopathy caused by bi-allelic NOTCH3 variants
.
Neuropediatrics
.
2022
;
53
(
2
):
115
21
.
5.
Richards
S
,
Aziz
N
,
Bale
S
,
Bick
D
,
Das
S
,
Gastier-Foster
J
, et al
.
Standards and guidelines for the interpretation of sequence variants: a joint consensus recommendation of the American College of medical genetics and genomics and the association for molecular pathology
.
Genet Med
.
2015
;
17
(
5
):
405
24
.
6.
Han
Y
,
Chen
M
,
Wang
H
.
Management of lateral meningocele syndrome in a child without neurological symptoms and literature review
.
Childs Nerv Syst
.
2022
;
38
(
5
):
903
7
.
7.
Yamada
M
,
Arimitsu
T
,
Suzuki
H
,
Miwa
T
,
Kosaki
K
.
Early diagnosis of lateral meningocele syndrome in an infant without neurological symptoms based on genomic analysis
.
Childs Nerv Syst
.
2022
;
38
(
3
):
659
63
.
8.
Flynn
DM
,
Nijjar
S
,
Hubscher
SG
,
de Goyet
JDV
,
Kelly
DA
,
Strain
AJ
, et al
.
The role of Notch receptor expression in bile duct development and disease
.
J Pathol
.
2004
;
204
(
1
):
55
64
.
9.
Lu
J
,
Zhou
Y
,
Hu
T
,
Zhang
H
,
Shen
M
,
Cheng
P
, et al
.
Notch signaling coordinates progenitor cell-mediated biliary regeneration following partial hepatectomy
.
Sci Rep
.
2016
;
6
:
22754
.
10.
Falix
FA
,
Weeda
VB
,
Labruyere
WT
,
Poncy
A
,
de Waart
DR
,
Hakvoort
TB
, et al
.
Hepatic Notch2 deficiency leads to bile duct agenesis perinatally and secondary bile duct formation after weaning
.
Dev Biol
.
2014
;
396
(
2
):
201
13
.
11.
Isidor
B
,
Lindenbaum
P
,
Pichon
O
,
Bézieau
S
,
Dina
C
,
Jacquemont
S
, et al
.
Truncating mutations in the last exon of NOTCH2 cause a rare skeletal disorder with osteoporosis
.
Nat Genet
.
2011
;
43
(
4
):
306
8
.
12.
Takahashi
K
,
Sato
Y
,
Yamamura
M
,
Nakada
S
,
Tamano
Y
,
Sasaki
M
, et al
.
Notch-Hes1 signaling activation in Caroli disease and polycystic liver disease
.
Pathol Int
.
2021
;
71
(
8
):
521
9
.
13.
Benedito
R
,
Hellström
M
.
Notch as a hub for signaling in angiogenesis
.
Exp Cell Res
.
2013
;
319
(
9
):
1281
8
.
14.
Mašek
J
,
Andersson
ER
.
The developmental biology of genetic Notch disorders
.
Development
.
2017
;
144
(
10
):
1743
63
.
15.
Ejaz
R
,
Qin
W
,
Huang
L
,
Blaser
S
,
Tetreault
M
,
Hartley
T
, et al,
Care4Rare Canada Consortium
.
Lateral meningocele (Lehman) syndrome: a child with a novel NOTCH3 mutation
.
Am J Med Genet
.
2016
;
170A
(
4
):
1070
5
.
16.
Cappuccio
G
,
Apuzzo
D
,
Alagia
M
,
Torella
A
,
Pinelli
M
,
Franco
B
, et al
.
Expansion of the phenotype of lateral meningocele syndrome
.
Am J Med Genet
.
2020
;
182
(
5
):
1259
62
.
17.
Rubadeux
D
,
Owens
JW
,
Shillington
A
.
A case of lateral meningocele syndrome without lateral meningocele
.
Mol Syndromol
.
2024
;
15
(
4
):
328
32
.
18.
Brown
EC
,
Gupta
K
,
Sayama
C
.
Neurosurgical management in lateral meningocele syndrome
.
J Neurosurg Pediatr
.
2017
;
19
(
2
):
232
38
.
19.
Alves
D
,
Sampaio
M
,
Figueired
R
,
Leão
M
.
Lateral meningocele syndrome: Additional report and further evidence supporting a connective tissue basis
.
Am J Med Genet A
.
2013
;
161A
(
7
):
1768
72
.
20.
Chen
KM
,
Bird
L
,
Barnes
P
,
Barth
R
,
Hudgins
L
.
Lateral meningocele syndrome: Vertical transmission and expansion of the phenotype
.
Am J Med Genet A
.
2005
;
133A
(
2
):
115
21
.
21.
Gripp
KW
,
Scott
CI
,
HugheS
HE
,
Wallerstein
R
,
Nicholson
L
,
States
L
, et al
.
Lateral meningocele syndrome: Three new patients and review of the literature
.
Am J Med Genet
.
1997
;
70
(
3
):
229
39
.
22.
Avela
K
,
Valanne
L
,
Heleniu
I
,
Mäkitie
O
.
Hajdu-Cheney syndrome with severe dural ectasia
.
Am J Med Genet A
.
2011
;
155A
(
3
):
595
98
.
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