Abstract
Introduction: We previously identified Notch2 in smooth muscle cells (SMC) in human atherosclerosis and found that signaling via Notch2 suppressed human SMC proliferation. Thus, we tested whether loss of Notch2 in SMC would alter atherosclerotic plaque progression using a mouse model. Methods: Atherogenesis was examined at the brachiocephalic artery and aortic root in a vascular SMC null (inducible smooth muscle myosin heavy chain Cre) Notch2 strain on the ApoE−/− background. We measured plaque morphology and size, as well as lipid, inflammation, and smooth muscle actin content after Western diet. Results: We generated an inducible SMC Notch2 null on the ApoE−/− background. We observed ∼90% recombination efficiency with no detectable Notch2 in the SMC. Loss of SMC Notch2 did not significantly change plaque size, lipid content, necrotic core, or medial area. However, loss of SMC Notch2 reduced the contractile SMC in brachiocephalic artery lesions and increased inflammatory content in aortic root lesions after 6 weeks of Western diet. These changes were not present with loss of SMC Notch2 after 14 weeks of Western diet. Conclusions: Our data show that loss of SMC Notch2 does not significantly reduce atherosclerotic lesion formation, although in early stages of plaque formation there are changes in SMC and inflammation.
Journal Section:
Editor's choice
References
1.
Briot
A
, Civelek
M
, Seki
A
, Hoi
K
, Mack
JJ
, Lee
SD
, . Endothelial NOTCH1 is suppressed by circulating lipids and antagonizes inflammation during atherosclerosis
. J Exp Med
. 2015
;212
(12
):2147
–63
.2.
Mack
JJ
, Mosqueiro
TS
, Archer
BJ
, Jones
WM
, Sunshine
H
, Faas
GC
, . NOTCH1 is a mechanosensor in adult arteries
. Nat Commun
. 2017
;8
(1
):1620
.3.
Fung
E
, Tang
SMT
, Canner
JP
, Morishige
K
, Arboleda-Velasquez
JF
, Cardoso
AA
, . Delta-like 4 induces Notch signaling in macrophages
. Circulation
. 2007 Jun
;115
(23
):2948
–56
.4.
Monsalve
E
, Ruiz-García
A
, Baladrón
V
, Ruiz-Hidalgo
MJ
, Sánchez-Solana
B
, Rivero
S
, . Notch1 upregulates LPS-induced macrophage activation by increasing NF-κB activity
. Eur J Immunol
. 2009 Sep
;39
(9
):2556
–70
.5.
Fukuda
D
, Aikawa
E
, Swirski
FK
, Novobrantseva
TI
, Kotelianski
V
, Gorgun
CZ
, . Notch ligand delta-like 4 blockade attenuates atherosclerosis and metabolic disorders
. Proc Natl Acad Sci U S A
. 2012
;109
(27
):E1868
–77
.6.
Boucher
J
, Gridley
T
, Liaw
L
. Molecular pathways of notch signaling in vascular smooth muscle cells
. Front Physiol
. 2012
;3
:1
–13
.7.
Baeten
JT
, Lilly
B
. Notch signaling in vascular smooth muscle cells
. Adv Pharmacol
. 2017
;78
:351
–82
.8.
Shankman
LS
, Gomez
D
, Cherepanova
OA
, Salmon
M
, Alencar
GF
, Haskins
RM
, . KLF4 dependent phenotypic modulation of SMCs plays a key role in atherosclerotic plaque pathogenesis laura
. Nat Med
. 2015
;21
(6
):628
–37
.9.
Albarrán-Juárez
J
, Kaur
H
, Grimm
M
, Offermanns
S
, Wettschureck
N
. Lineage tracing of cells involved in atherosclerosis
. Atherosclerosis
. 2016
;251
:445
–53
.10.
Jacobsen
K
, Lund
MB
, Shim
J
, Gunnersen
S
, Füchtbauer
EM
, Kjolby
M
, . Diverse cellular architecture of atherosclerotic plaque derives from clonal expansion of a few medial SMCs
. JCI Insight
. 2017 Oct
;2
(19
):1
–13
.11.
Alencar
GF
, Owsiany
KM
, Karnewar
S
, Sukhavasi
K
, Mocci
G
, Nguyen
AT
, . Stem cell pluripotency genes Klf4 and Oct4 regulate complex SMC phenotypic changes critical in late-stage atherosclerotic lesion pathogenesis
. Circulation
. 2020 Nov
;142
(21
):2045
–59
.12.
Boucher
JM
, Harrington
A
, Rostama
B
, Lindner
V
, Liaw
L
. A receptor-specific function for Notch2 in mediating vascular smooth muscle cell growth arrest through cyclin-dependent kinase inhibitor 1B
. Circ Res
. 2013
;113
(8
):975
–85
.13.
Davis-knowlton
J
, Turner
JE
, Turner
A
, Damian-Loring
S
, Hagler
N
, Henderson
T
, . Characterization of smooth muscle cells from human atherosclerotic lesions and their responses to Notch signaling
. Lab Investig
. 2018 Mar
;99
(3
):290
–304
.14.
Martos-Rodríguez
CJ
, Albarrán-Juárez
J
, Morales-Cano
D
, Caballero
A
, Macgrogan
D
, De La Pompa
JL
, . Fibrous caps in atherosclerosis form by Notch-dependent mechanisms common to arterial media development
. Arterioscler Thromb Vasc Biol
. 2021
;41
(9
):E427
–39
.15.
McCright
B
, Lozier
J
, Gridley
T
. Generation of new Notch2 mutant alleles
. Genesis
. 2006
;44
(1
):29
–33
.16.
Peterson
SM
, Turner
JE
, Harrington
A
, Davis-Knowlton
J
, Lindner
V
, Gridley
T
, . Notch2 and proteomic signatures in mouse neointimal lesion formation
. Arterioscler Thromb Vasc Biol
. 2018 Jul
;38
(7
):1576
–93
.17.
Wirth
A
, Benyó
Z
, Lukasova
M
, Leutgeb
B
, Wettschureck
N
, Gorbey
S
, . G12-G13-LARG-mediated signaling in vascular smooth muscle is required for salt-induced hypertension
. Nat Med
. 2008
;14
(1
):64
–8
.18.
Piedrahita
JA
, Zhang
SH
, Hagaman
JR
, Oliver
PM
, Maeda
N
. Generation of mice carrying a mutant apolipoprotein E gene inactivated by gene targeting in embryonic stem cells
. Proc Natl Acad Sci U S A
. 1992
;89
(10
):4471
–5
.19.
Jaffe
IZ
, Newfell
BG
, Aronovitz
M
, Mohammad
NN
, McGraw
AP
, Perreault
RE
, . Placental growth factor mediates aldosterone-dependent vascular injury in mice
. J Clin Invest
. 2010 Nov
;120
(11
):3891
.20.
Schmittgen
TD
, Livak
KJ
. Analyzing real-time PCR data by the comparative C(T) method
. Nat Protoc
. 2008
;3
(6
):1101
–8
. [cited 2019 Mar 29].21.
Buchan
L
, St Aubin
CR
, Fisher
AL
, Hellings
A
, Castro
M
, Al-Nakkash
L
, . High-fat, high-sugar diet induces splenomegaly that is ameliorated with exercise and genistein treatment
. BMC Res Notes
. 2018 Oct
;11
(1
):752
.22.
Kumar
A
, Lindner
V
. Remodeling with neointima formation in the mouse carotid artery after cessation of blood flow
. Arterioscler Thromb Vasc Biol
. 1997 Oct
;17
(10
):2238
–44
.23.
Seimon
TA
, Wang
Y
, Han
S
, Senokuchi
T
, Schrijvers
DM
, Kuriakose
G
, . Macrophage deficiency of p38α MAPK promotes apoptosis and plaque necrosis in advanced atherosclerotic lesions in mice
. J Clin Invest
. 2009 Apr
;119
(4
):886
.24.
Sato
S
, Hughes
RC
. Regulation of secretion and surface expression of Mac-2, a galactoside- binding protein of macrophages
. J Biol Chem
. 1994 Feb
;269
(6
):4424
–30
.25.
Liu
FT
, Hsu
DK
, Zuberi
RI
, Kuwabara
I
, Chi
EY
, Henderson
WR
. Expression and function of galectin-3, a β-galactoside-binding lectin, in human monocytes and macrophages
. Am J Pathol
. 1995
[cited 2021 Feb 27];147
(4
):1016
–28
.26.
Di Gregoli
K
, Somerville
M
, Bianco
R
, Thomas
AC
, Frankow
A
, Newby
AC
, . Galectin-3 identifies a subset of macrophages with a potential beneficial role in atherosclerosis
. Arterioscler Thromb Vasc Biol
. 2020
;40
:1491
–509
.27.
Feil
S
, Fehrenbacher
B
, Lukowski
R
, Essmann
F
, Schulze-Osthoff
K
, Schaller
M
, . Transdifferentiation of vascular smooth muscle cells to macrophage-like cells during atherogenesis
. Circ Res
. 2014 Sep
;115
(7
):662
–7
.28.
Moss
ME
, DuPont
JJ
, Iyer
SL
, McGraw
AP
, Jaffe
IZ
. No significant role for smooth muscle cell mineralocorticoid receptors in atherosclerosis in the apolipoprotein-E knockout mouse model
. Front Cardiovasc Med
. 2018
;5
:81
.29.
Hansson
GK
, Libby
P
, Tabas
I
. Inflammation and plaque vulnerability
. J Intern Med
. 2015
;278
(5
):483
–93
.30.
Allahverdian
S
, Chehroudi
AC
, McManus
BM
, Abraham
T
, Francis
GA
. Contribution of intimal smooth muscle cells to cholesterol accumulation and macrophage-like cells in human atherosclerosis
. Circulation
. 2014
;129
(15
):1551
–9
.31.
Li
Y
, Zhu
H
, Zhang
Q
, Han
X
, Zhang
Z
, Shen
L
, . Smooth muscle-derived macrophage-like cells contribute to multiple cell lineages in the atherosclerotic plaque
. Cell Discov
. 2021 Nov
;7
(1
):1
–4
.32.
Wang
Y
, Dubland
JA
, Allahverdian
S
, Asonye
E
, Sahin
B
, Jaw
JE
, . Smooth muscle cells contribute the majority of foam cells in ApoE (Apolipoprotein E)-deficient mouse atherosclerosis
. Arterioscler Thromb Vasc Biol
. 2019 May
;39
(5
):876
–87
.33.
Newman
AAC
, Serbulea
V
, Baylis
RA
, Shankman
LS
, Bradley
X
, Alencar
GF
, . Multiple cell types contribute to the atherosclerotic lesion fibrous cap by PDGFRβ and bioenergetic mechanisms
. Nat Metab
. 2021
;3
(2
):166
–81
.34.
Sinha
S
, Iyer
D
, Granata
A
. Embryonic origins of human vascular smooth muscle cells: implications for in vitro modeling and clinical application
. Cell Mol Life Sci
. 2014 Jun
;71
(12
):2271
–88
.35.
Zhang
J
, Chen
J
, Xu
C
, Yang
J
, Guo
Q
, Hu
Q
, . Resveratrol inhibits phenotypic switching of neointimal vascular smooth muscle cells after balloon injury through blockade of Notch pathway
. J Cardiovasc Pharmacol
. 2014
;63
(3
):233
–9
.36.
Jiao
J
, Xiong
W
, Wang
L
, Yang
J
, Qiu
P
, Hirai
H
, . Differentiation defect in neural crest-derived smooth muscle cells in patients with aortopathy associated with bicuspid aortic valves
. EBioMedicine
. 2016
;10
:282
.37.
Nakashima
Y
, Plump
AS
, Raines
EW
, Breslow
JL
, Ross
R
. ApoE-deficient mice develop lesions of all phases of atherosclerosis throughout the arterial tree
. Arterioscler Thromb A J Vasc Biol
. 1994
;14
(1
):133
–40
.© 2022 S. Karger AG, Basel
Copyright / Drug Dosage / Disclaimer
Copyright: All rights reserved. No part of this publication may be translated into other languages, reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying, recording, microcopying, or by any information storage and retrieval system, without permission in writing from the publisher.
Drug Dosage: The authors and the publisher have exerted every effort to ensure that drug selection and dosage set forth in this text are in accord with current recommendations and practice at the time of publication. However, in view of ongoing research, changes in government regulations, and the constant flow of information relating to drug therapy and drug reactions, the reader is urged to check the package insert for each drug for any changes in indications and dosage and for added warnings and precautions. This is particularly important when the recommended agent is a new and/or infrequently employed drug.
Disclaimer: The statements, opinions and data contained in this publication are solely those of the individual authors and contributors and not of the publishers and the editor(s). The appearance of advertisements or/and product references in the publication is not a warranty, endorsement, or approval of the products or services advertised or of their effectiveness, quality or safety. The publisher and the editor(s) disclaim responsibility for any injury to persons or property resulting from any ideas, methods, instructions or products referred to in the content or advertisements.
2022
You do not currently have access to this content.
