doi: 10.1074/jbc.M900992200.
Epub 2009 Feb 23.
VCP mutations causing frontotemporal lobar degeneration disrupt localization of TDP-43 and induce cell death
Affiliations
- PMID: 19237541
- PMCID: PMC2673306
- DOI: 10.1074/jbc.M900992200
Item in Clipboard
VCP mutations causing frontotemporal lobar degeneration disrupt localization of TDP-43 and induce cell death
J Biol Chem.
.
Abstract
Frontotemporal lobar degeneration (FTLD) with inclusion body myopathy and Paget disease of bone is a rare, autosomal dominant disorder caused by mutations in the VCP (valosin-containing protein) gene. The disease is characterized neuropathologically by frontal and temporal lobar atrophy, neuron loss and gliosis, and ubiquitin-positive inclusions (FTLD-U), which are distinct from those seen in other sporadic and familial FTLD-U entities. The major component of the ubiquitinated inclusions of FTLD with VCP mutation is TDP-43 (TAR DNA-binding protein of 43 kDa). TDP-43 proteinopathy links sporadic amyotrophic lateral sclerosis, sporadic FTLD-U, and most familial forms of FTLD-U. Understanding the relationship between individual gene defects and pathologic TDP-43 will facilitate the characterization of the mechanisms leading to neurodegeneration. Using cell culture models, we have investigated the role of mutant VCP in intracellular trafficking, proteasomal function, and cell death and demonstrate that mutations in the VCP gene 1) alter localization of TDP-43 between the nucleus and cytosol, 2) decrease proteasome activity, 3) induce endoplasmic reticulum stress, 4) increase markers of apoptosis, and 5) impair cell viability. These results suggest that VCP mutation-induced neurodegeneration is mediated by several mechanisms.
Figures
Model of pathogenic mutations and domains in valosin-containing
protein. CDC48 (magenta), located within the N terminus (residues
22-108), binds the following cofactors: p47, gp78, and Npl4-Ufd1
(23-25,
28). There are two AAA-ATPase
domains (AAA; blue) at residues 240-283 and 516-569, which
are joined by two linker regions (L1 and L2;
red).
Neuropathology of the brain of a 47-year-old man with frontotemporal
lobar degeneration and VCP mutation R155H. A, low power
micrograph of the superficial laminae of the frontal lobe showing two neurons
(arrows) containing intranuclear aggregates of VCP. B, high
power micrograph showing a VCP-immunoreactive intranuclear inclusion.
C, a TDP-43-immunoreactive intranuclear aggregate. D, a
ubiquitin-immunoreactive neuronal intranuclear inclusion. E, a TDP-43
NCI. F, a ubiquitin-immunoreactive NCI. A and B,
VCP immunohistochemistry (IHC); C and E, TDP-43
immunohistochemistry; D and F, ubiquitin
immunohistochemistry. Scale bar, 20 μm (A) and 5 μm
(B-F).
Mutations in VCP decrease cell viability and proteasome
activity and increase the amount of soluble ubiquitin in neuroblastoma,
SHSY-5Y, cells. A, trypan blue exclusion assay measured cell
viability over a 3-day time course after transfection in three separate
experiments. The graph shows viability of WT compared with mutant
VCP transiently transfected SHSY-5Y cells (n = 3;
*, p < 0.05; **, p < 0.001).
B, proteasome chymotrypsin cleavage activity in retinoic acid induced
differentiated SHSY-5Y cells transiently transfected with VCP constructs
assessed 24 h post-transfection (n = 6; *, p <
0.05; **, p < 0.001). C, SHSY-5Y cells
transiently transfected with monomeric dsRED-VCP constructs; arrows
indicate colocalization of TDP-43/VCP (yellow) and visualization by
confocal microscopy (VCP dsRED fusion constructs (red), anti-FK2
(blue), and anti-TDP-43 (green)). D (top),
immunoblotting of low salt and urea-soluble cell fractions reveals a distinct
ubiquitin-positive band of ∼37 kDa. Soluble low salt (L) and
soluble urea (U) fractions are shown. 5Y, control SHSY-5Y
cells not transfected. Top, blot probed with anti-ubiquitin
antibodies. D (bottom), fractions were probed with anti-VCP
and anti-TDP-43 antibodies. A single band of ∼43 kDa of TDP-43 was
identified; no other bands and no cleavage products were detected in the
cellular protein fractions. VCP was detected using anti-VCP antibodies, and
two bands were identified: full-length VCP of ∼97 kDa and VCP-dsRED fusion
protein of ∼150 kDa.
Mutations in VCP increase markers of ER stress. A,
Western blot analysis of VCP constructs in SHSY-5Y cells under different
conditions: untreated SHSY-5Y cells (5Y), retinoic acid
(RA)-induced differentiation, and cells in the presence of
phosphatidylinositol 3-kinase inhibitor, LY294002 (LY). B,
there was an increase, but not statistically significant, in GRP78 levels in
mutants compared with controls. Values represent relative optical density
values of GRP78 in untreated cells in arbitrary units normalized to
β-actin (ACTB) in three separate experiments. C, GRP78
mRNA normalized to GAPDH was significantly increased in mutants, as determined
by quantitative RT-PCR (qRT-PCR). D, quantitative RT-PCR of
calreticulin mRNA levels were significantly reduced in mutants compared with
WT control when normalized to GAPDH 24 h after transfection and 24 h after
retinoic acid-induced differentiation in SHSY-5Y cells. Data are expressed as
mean ± S.D.; Student's t test; *, p <
0.05; **, p < 0.001.
Apoptotic markers are elevated in mutant cell lines compared with
controls. A, caspase-4 and/or -9 activity was significantly
increased in all mutants. B, caspase-3 activity was also elevated in
all mutants compared with WT control cells. Transiently transfected
overexpressed WT VCP was compared with mutant VCP in SHSY-5Y cells
(n = 10; *, p < 0.05; **,
p < 0.001).
VCP colocalizes with the ER-Golgi network. Overexpressed dsRED-VCP
fusion protein (red), GOLGB1 (anti-giantin, trans-Golgi)
(green), and protein-disulfide isomerase (PDI; ER marker,
secondary; blue) were visualized by confocal microscopy.
Mutant VCP alters endogenous TDP-43 localization 24 h
post-transfection. At 24 h post-transfection, dsRED-VCP fusion protein
(red), TDP-43 (green), and TOPRO-3 (nuclear marker;
blue) were visualized by confocal microscopy (arrows
indicate TDP-43 and VCP colocalization and accumulation
(merge/yellow)).
Mutant VCP localizes to the nucleus from cytoplasm 24 h
post-transfection. Wild-type VCP shows no change in cytosolic
distribution. R95G and R155H showed a similar spatial pattern of protein
localization; the graphs show the intensity distribution profile of
dsRED-VCP (red line), TDP-43 (green line), and TOPRO-3,
nuclear marker (blue line) of the merged image. Intensity profile of
R155H (A) and control, nontransfected cell (SHSY-5Y) profile
are represented in the graph (B) and show predominantly nuclear and
subtle TDP-43 cytoplasmic staining.
Mutant VCP translocates to the nucleus from the cytoplasm. VCP
translocates to the nucleus and TDP-43 appears more abundant in the cytoplasm
of R155C-, R191Q-, and A232E-transfected cells. The graphs show the
intensity distribution profile of dsRED-VCP (red line), TDP-43
(green line), and TOPRO-3 (nuclear marker; blue line) in the
analyzed cells.
Mutant VCP alters endogenous TDP-43 localization 48 h
post-transfection. dsRED-VCP fusion protein (red), TDP-43
(green), and TOPRO-3 (nuclear marker; blue) were visualized
by confocal microscopy At 48 h post-transfection. The arrows indicate
TDP-43 and VCP colocalization in the cytosol
(merge/yellow).
Mutant VCP induces TDP-43 distribution to the cytosol 48 h
post-transfection. Wild-type VCP-expressing cells show no change in
nuclear distribution of TDP-43. In contrast, VCP R95G and R155H mutants
display a relative increase in cytosolic TDP-43. The graphs show the
intensity distribution profile of dsRED-VCP (red line), TDP-43
(green line), and TOPRO-3 (nuclear marker; blue line) of the
merged image.
Mutant VCP induces TDP-43 distribution from the nucleus to the
cytosol 48 h post-transfection. R155C, R191Q, and A232E mutants display a
relative increase in cytosolic TDP-43. The graphs show the intensity
distribution profile of dsRED-VCP (red line), TDP-43 (green
line), and TOPRO-3 (nuclear marker; blue line) of the merged
image.
Overexpression of dsRED-VCP E305Q/E578Q (dominant negative) leads to
nuclear fragmentation consistent with neuronal cell death at 24 h
post-transfection. There is little to no TDP-43 present either in the
nucleus or cytoplasm. dsRED-VCP E305Q/E578Q (dominant negative)
(red), TDP-43 (green) and TOPRO-3 (nuclear marker;
blue) and visualized by confocal microscopy.
TDP-43 complexes with VCP in co-immunoprecipitation assays in both
SHSY-5Y cells and human brain. A, TDP-43 immunoprecipitation
(IP) in VCP-transfected SHSY-5Y cells probed with anti-VCP
(top) and 5% loading control (bottom). B, VCP
immunoprecipitation in high salt (HS) fraction of human brain probed
with anti-TDP-43. Samples were immunoprecipitated with VCP: normal adult
control cases (NL-1 and NL-2); Alzheimer disease
(AD); familial FTLD-U with GRN A9D mutation (GRN);
sporadic (FTLD-U); and FTLD-U with the VCP R155H mutation
(VCP) (top) and 2% loading control (bottom).
C, TDP-43 immunoprecipitation in HS of human brain probed with
anti-VCP: age-matched control (NL-1); familial FTLD-U with
GRN A9D mutation (GRN); sporadic (FTLD-U); and
FTLD-U with VCP R155H mutation (VCP).
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