Abstract
Dopamine receptor type 2 (DRD2) agonists are the first-choice treatment for prolactin-secreting pituitary tumors but are poorly effective in nonfunctioning pituitary neuroendocrine tumors (NF-PitNETs). DRD2 reduces AKT phosphorylation in lactotrophs, but no data are available in NF-PitNETs. DRD2 effects on AKT are mediated by a β-arrestin 2-dependent mechanism in mouse striatum. The aim of this study was to investigate DRD2 effects on AKT phosphorylation and cell proliferation in human primary cultured NF-PitNET cells and in rat tumoral lactotroph cells MMQ, and to test β-arrestin 2 involvement. We found that the DRD2 agonist BIM53097 induced a reduction of the p-AKT/total-AKT ratio in MMQ (–32.8 ± 17.6%, p < 0.001 vs. basal) and in a subset (n = 15/41, 36.6%) of NF-PitNETs (subgroup 1). In the remaining NF-PitNETs (subgroup 2), BIM53097 induced an increase in p-AKT. The ability of BIM53097 to reduce p-AKT correlated with its antimitotic effect, since the majority of subgroup 1 NF-PitNETs was responsive to BIM53097, and nearly all subgroup 2 NF-PitNETs were resistant. β-Arrestin 2 was expressed in MMQ and in 80% of subgroup 1 NF-PitNETs, whereas it was undetectable in 77% of subgroup 2 NF-PitNETs. In MMQ, β-arrestin 2 silencing prevented DRD2 inhibitory effects on p-AKT and cell proliferation. Accordingly, β-arrestin 2 transfection in subgroup 2 NF-PitNETs conferred to BIM53097 the ability to inhibit both p-AKT and cell growth. In conclusion, we demonstrated that β-arrestin 2 is required for DRD2 inhibitory effects on AKT phosphorylation and cell proliferation in MMQ and NF-PitNETs, paving the way for a potential role of β-arrestin 2 as a biomarker predicting NF-PitNETs’ responsiveness to treatment with dopamine agonists.
References
1.
Asa
SL
, Casar-Borota
O
, Chanson
P
, Delgrange
E
, Earls
P
, Ezzat
S
, et al.; attendees of 14th Meeting of the International Pituitary Pathology Club, Annecy, France, November 2016
. From pituitary adenoma to pituitary neuroendocrine tumor (PitNET): an International Pituitary Pathology Club proposal
. Endocr Relat Cancer
. 2017
Apr
;24
(4
):C5
–8
.
[PubMed]
1351-00882.
Delgado-López
PD
, Pi-Barrio
J
, Dueñas-Polo
MT
, Pascual-Llorente
M
, Gordón-Bolaños
MC
. Recurrent non-functioning pituitary adenomas: a review on the new pathological classification, management guidelines and treatment options
. Clin Transl Oncol
. 2018
Oct
;20
(10
):1233
–45
.
[PubMed]
1699-048X3.
Melmed
S
, Casanueva
FF
, Hoffman
AR
, Kleinberg
DL
, Montori
VM
, Schlechte
JA
, et al.; Endocrine Society
. Diagnosis and treatment of hyperprolactinemia: an Endocrine Society clinical practice guideline
. J Clin Endocrinol Metab
. 2011
Feb
;96
(2
):273
–88
.
[PubMed]
0021-972X4.
Greenman
Y
, Tordjman
K
, Osher
E
, Veshchev
I
, Shenkerman
G
, Reider-Groswasser
II
, et al. Postoperative treatment of clinically nonfunctioning pituitary adenomas with dopamine agonists decreases tumour remnant growth
. Clin Endocrinol (Oxf)
. 2005
Jul
;63
(1
):39
–44
.
[PubMed]
0300-06645.
Greenman
Y
, Cooper
O
, Yaish
I
, Robenshtok
E
, Sagiv
N
, Jonas-Kimchi
T
, et al. Treatment of clinically nonfunctioning pituitary adenomas with dopamine agonists
. Eur J Endocrinol
. 2016
Jul
;175
(1
):63
–72
.
[PubMed]
0804-46436.
Colao
A
, Di Somma
C
, Pivonello
R
, Faggiano
A
, Lombardi
G
, Savastano
S
. Medical therapy for clinically non-functioning pituitary adenomas
. Endocr Relat Cancer
. 2008
Dec
;15
(4
):905
–15
.
[PubMed]
1351-00887.
Cooper
O
, Greenman
Y.
Dopamine Agonists for Pituitary Adenomas.
Front Endocrinol (Lau-sanne). 2018
Aug;21;9:469. 8.
Even-Zohar
N
, Greenman
Y
. Management of NFAs: medical treatment
. Pituitary
. 2018
Apr
;21
(2
):168
–75
.
[PubMed]
1386-341X9.
Florio
T
, Barbieri
F
, Spaziante
R
, Zona
G
, Hofland
LJ
, van Koetsveld
PM
, et al. Efficacy of a dopamine-somatostatin chimeric molecule, BIM-23A760, in the control of cell growth from primary cultures of human non-functioning pituitary adenomas: a multi-center study
. Endocr Relat Cancer
. 2008
Jun
;15
(2
):583
–96
.
[PubMed]
1351-008810.
Peverelli
E
, Olgiati
L
, Locatelli
M
, Magni
P
, Fustini
MF
, Frank
G
, et al. The dopamine-somatostatin chimeric compound BIM-23A760 exerts antiproliferative and cytotoxic effects in human non-functioning pituitary tumors by activating ERK1/2 and p38 pathways
. Cancer Lett
. 2010
Feb
;288
(2
):170
–6
.
[PubMed]
0304-383511.
Peverelli
E
, Giardino
E
, Treppiedi
D
, Meregalli
M
, Belicchi
M
, Vaira
V
, et al. Dopamine receptor type 2 (DRD2) and somatostatin receptor type 2 (SSTR2) agonists are effective in inhibiting proliferation of progenitor/stem-like cells isolated from nonfunctioning pituitary tumors
. Int J Cancer
. 2017
Apr
;140
(8
):1870
–80
.
[PubMed]
0020-713612.
Vitali
E
, Peverelli
E
, Giardino
E
, Locatelli
M
, Lasio
GB
, Beck-Peccoz
P
, et al. Cyclic adenosine 3′-5′-monophosphate (cAMP) exerts proliferative and anti-proliferative effects in pituitary cells of different types by activating both cAMP-dependent protein kinase A (PKA) and exchange proteins directly activated by cAMP (Epac)
. Mol Cell Endocrinol
. 2014
Mar
;383
(1-2
):193
–202
.
[PubMed]
0303-720713.
Iaccarino
C
, Samad
TA
, Mathis
C
, Kercret
H
, Picetti
R
, Borrelli
E
. Control of lactotrop proliferation by dopamine: essential role of signaling through D2 receptors and ERKs
. Proc Natl Acad Sci USA
. 2002
Oct
;99
(22
):14530
–5
.
[PubMed]
0027-842414.
Radl
D
, De Mei
C
, Chen
E
, Lee
H
, Borrelli
E
. Each individual isoform of the dopamine D2 receptor protects from lactotroph hyperplasia
. Mol Endocrinol
. 2013
Jun
;27
(6
):953
–65
.
[PubMed]
0888-880915.
Lin
SJ
, Leng
ZG
, Guo
YH
, Cai
L
, Cai
Y
, Li
N
, et al. Suppression of mTOR pathway and induction of autophagy-dependent cell death by cabergoline
. Oncotarget
. 2015
Nov
;6
(36
):39329
–41
.
[PubMed]
1949-255316.
Beaulieu
JM
, Sotnikova
TD
, Marion
S
, Lefkowitz
RJ
, Gainetdinov
RR
, Caron
MG
. An Akt/beta-arrestin 2/PP2A signaling complex mediates dopaminergic neurotransmission and behavior
. Cell
. 2005
Jul
;122
(2
):261
–73
.
[PubMed]
0092-867417.
Beaulieu
JM
, Gainetdinov
RR
, Caron
MG
. The Akt-GSK-3 signaling cascade in the actions of dopamine
. Trends Pharmacol Sci
. 2007
Apr
;28
(4
):166
–72
.
[PubMed]
0165-614718.
Musat
M
, Korbonits
M
, Kola
B
, Borboli
N
, Hanson
MR
, Nanzer
AM
, et al. Enhanced protein kinase B/Akt signalling in pituitary tumours
. Endocr Relat Cancer
. 2005
Jun
;12
(2
):423
–33
.
[PubMed]
1351-008819.
Xu
M
, Shorts-Cary
L
, Knox
AJ
, Kleinsmidt-DeMasters
B
, Lillehei
K
, Wierman
ME
. Epidermal growth factor receptor pathway substrate 8 is overexpressed in human pituitary tumors: role in proliferation and survival
. Endocrinology
. 2009
May
;150
(5
):2064
–71
.
[PubMed]
0013-722720.
Peverelli
E
, Giardino
E
, Mangili
F
, Treppiedi
D
, Catalano
R
, Ferrante
E
, et al. cAMP/PKA-induced filamin A (FLNA) phosphorylation inhibits SST2 signal transduction in GH-secreting pituitary tumor cells
. Cancer Lett
. 2018
Oct
;435
:101
–9
.
[PubMed]
0304-383521.
Cambiaghi
V
, Vitali
E
, Morone
D
, Peverelli
E
, Spada
A
, Mantovani
G
, et al. Identification of human somatostatin receptor 2 domains involved in internalization and signaling in QGP-1 pancreatic neuroendocrine tumor cell line
. Endocrine
. 2017
Apr
;56
(1
):146
–57
.
[PubMed]
1355-008X22.
Dumble
M
, Crouthamel
MC
, Zhang
SY
, Schaber
M
, Levy
D
, Robell
K
, et al. Discovery of novel AKT inhibitors with enhanced anti-tumor effects in combination with the MEK inhibitor
. PLoS One
. 2014
Jun
;9
(6
):e100880
.
[PubMed]
1932-620323.
Rhodes
N
, Heerding
DA
, Duckett
DR
, Eberwein
DJ
, Knick
VB
, Lansing
TJ
, et al. Characterization of an Akt kinase inhibitor with potent pharmacodynamic and antitumor activity
. Cancer Res
. 2008
Apr
;68
(7
):2366
–74
.
[PubMed]
0008-547224.
Han
EK
, Leverson
JD
, McGonigal
T
, Shah
OJ
, Woods
KW
, Hunter
T
, et al. Akt inhibitor A-443654 induces rapid Akt Ser-473 phosphorylation independent of mTORC1 inhibition
. Oncogene
. 2007
Aug
;26
(38
):5655
–61
.
[PubMed]
0950-923225.
Kinoshita
S
, Ri
M
, Kanamori
T
, Aoki
S
, Yoshida
T
, Narita
T
, et al. Potent antitumor effect of combination therapy with sub-optimal doses of Akt inhibitors and pomalidomide plus dexamethasone in multiple myeloma
. Oncol Lett
. 2018
Jun
;15
(6
):9450
–6
.
[PubMed]
1792-107426.
Chen
R
, Duan
J
, Li
L
, Ma
Q
, Sun
Q
, Ma
J
, et al. mTOR promotes pituitary tumor development through activation of PTTG1
. Oncogene
. 2017
Feb
;36
(7
):979
–88
.
[PubMed]
0950-923227.
Lopes
MB
. The 2017 World Health Organization classification of tumors of the pituitary gland: a summary
. Acta Neuropathol
. 2017
Oct
;134
(4
):521
–35
.
[PubMed]
0001-632228.
Yamaji
M
, Ota
A
, Wahiduzzaman
M
, Karnan
S
, Hyodo
T
, Konishi
H
, et al. Novel ATP-competitive Akt inhibitor afuresertib suppresses the proliferation of malignant pleural mesothelioma cells
. Cancer Med
. 2017
Nov
;6
(11
):2646
–59
.
[PubMed]
2045-763429.
Ventra
C
, Meucci
O
, Grimaldi
M
, Scorziello
A
, Porcellini
A
, Schettini
G
. Absence of D2S dopamine receptor in the prolactin-secreting MMQ pituitary clone: characterization of a wild D2L receptor coupled to native transduction mechanisms
. J Mol Endocrinol
. 1995
Jun
;14
(3
):375
–89
.
[PubMed]
0952-504130.
Brami-Cherrier
K
, Valjent
E
, Garcia
M
, Pagès
C
, Hipskind
RA
, Caboche
J
. Dopamine induces a PI3-kinase-independent activation of Akt in striatal neurons: a new route to cAMP response element-binding protein phosphorylation
. J Neurosci
. 2002
Oct
;22
(20
):8911
–21
.
[PubMed]
0270-647431.
Mannoury la Cour
C
, Salles
MJ
, Pasteau
V
, Millan
MJ
. Signaling pathways leading to phosphorylation of Akt and GSK-3β by activation of cloned human and rat cerebral D₂and D₃ receptors
. Mol Pharmacol
. 2011
Jan
;79
(1
):91
–105
.
[PubMed]
0026-895X© 2020 S. Karger AG, Basel
2020
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