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The Journal of Neuroscience, March 1, 2003, 23(5):1638
Role of Integrin-Linked Kinase in Nerve Growth
Factor-Stimulated Neurite Outgrowth
Julia
Mills1,
Murat
Digicaylioglu5,
Arthur T.
Legg2,
Clint E.
Young4,
Sean S.
Young1,
Alasdair M.
Barr3,
Lauren
Fletcher5,
Timothy P.
O'Connor2, and
Shoukat
Dedhar1
1 Department of Biochemistry and Molecular Biology,
University of British Columbia, Vancouver, Canada V6T 123, and British
Columbia Cancer Agency, British Columbia, Canada V6H 326, 2 Department of Anatomy and Cell Biology, University of
British Columbia, Vancouver, British Columbia, Canada V6T 123, 3 Department of Psychology, University of British Columbia,
Vancouver, British Columbia, Canada V6T 124, 4 Department
of Psychiatry, University of British Columbia, Vancouver, British
Columbia, Canada V6T 2A1, and 5 Center for Neuroscience and
Aging Research, The Burnham Institute, La Jolla, California 92037
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ABSTRACT |
The role of integrin-linked kinase (ILK), a kinase that is involved
in various cellular processes, including adhesion and migration, has
not been studied in primary neurons. Using mRNA dot blot and Western
blot analysis of ILK in rat and human brain tissue, we found that ILK
is expressed in various regions of the CNS. Immunohistochemical
and immunocytochemical techniques revealed granular ILK staining that
is enriched in neurons and colocalizes with the  1 integrin subunit.
The role of ILK in neurite growth promotion by NGF was studied in rat
pheochromocytoma cells and dorsal root ganglion neurons using a
pharmacological inhibitor of ILK (KP-392) or after overexpression of
dominant-negative ILK (ILK-DN). Both molecular and pharmacological
inhibition of ILK activity significantly reduced NGF-induced neurite
outgrowth. Survival assays indicate that KP-392-induced suppression of
neurite outgrowth occurred in the absence of cell death. ILK kinase
activity was stimulated by NGF. NGF-mediated stimulation of
phosphorylation of both AKT and the Tau kinase
glycogen synthase kinase-3 (GSK-3) was inhibited in the presence of
KP-392 and after overexpression of ILK-DN. Consequently, ILK inhibition
resulted in an increase in the hyperphosphorylation of
Tau, a substrate of GSK-3. Together these findings
indicate that ILK is an important effector in NGF-mediated neurite outgrowth.
Key words:
integrin-linked kinase; glycogen synthase kinase-3; NGF; neurite growth; AKT; 1 integrin; extracellular matrix
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Introduction |
Integrin linked-kinase (ILK) is a 59 kDa, phosphatidylinositol-3 kinase (PI-3 kinase)-dependent,
serine-threonine kinase that regulates various cellular processes,
including adhesion, migration, differentiation, and survival (for
review, see Dedhar et al., 1999 ; Wu, 1999; Dedhar, 2000; Wu and Dedhar,
2001). ILK contains four ankyrin repeats at the
NH2 terminus followed by a pleckstrin homology
(PH)-like domain and a protein kinase catalytic domain near the COOH
terminus (Hannigan et al., 1996). ILK interacts with 1 and 3
integrins through its C terminus (Hannigan et al., 1996), the
LIM domain-only adaptor protein particularly interesting new
cysteine-histidine rich protein (PINCH) through its ankyrin repeat
domains (Tu et al., 1999) and may interact with phosphatidylinositol phosphates through the PH domain motif (Delcommenne et al., 1998). The
ILK-PINCH interaction is important for its localization within focal
adhesions (Li et al., 1999) and is thought to link ILK with growth
factor receptor kinase signaling by way of other PINCH binding proteins
such as Nck-2 (Tu et al., 1998). PINCH and Nck-2 form a ternary complex
with ILK and are recruited to activated growth factor receptors (Tu et
al., 1999). ILK also binds paxillin and the calponin homology
containing actin binding proteins affixin (Yamaji et al., 2001) and
calponin homology ILK-binding protein (CH-ILKBP) (Tu et al., 2001)
within focal adhesions (Nikolopoulos and Turner, 2001). These
protein-protein interactions provide a framework for the formation of
ILK signaling complexes that couple integrins and growth factors to the
cytoskeleton (Wu and Dedhar, 2001).
ILK has been shown to be a critical effector in a PI-3 kinase-dependent
signaling pathway that is downstream from both growth factor and
integrin receptor activation (for reviews see Dedhar et al., 1999; Wu,
1999). Stimulation of ILK after exposure to soluble factors or
fibronectin results in activation of AKT (also known as protein kinase
B) and inhibition of glycogen synthase kinase-3 (GSK-3) (Delcommenne et
al., 1998; Attwell et al., 2000; Dedhar, 2000; Persad et al., 2000).
Phosphoinhibition of GSK-3 by ILK may be direct because ILK has been
shown to phosphorylate GSK-3 in vitro (Delcommenne et
al., 1998; Persad et al., 2001b). Alternatively, activated AKT may, in
turn, phosphorylate and thereby negatively regulate GSK-3 (Cross et
al., 1995).
The PI-3 kinase-dependent-AKT signaling pathway has been shown
to be involved in neuronal differentiation and is downstream of both
integrins (Sarner et al., 2000) and growth factors such as NGF (Kaplan
and Miller, 2000). ILK is a known effector within the AKT signaling
pathway and has recently been shown to regulate migration and
differentiation (Ishii et al., 2001; Wu and Dedhar, 2001). Therefore,
we examined the role of ILK in NGF-induced activation of AKT and
neurite outgrowth using pheochromocytoma cells (PC12) cells,
dorsal root ganglion (DRG) neurons, and cerebrocortical neurons. We
find that ILK is activated by NGF and is an important effector of
NGF-mediated neurite outgrowth.
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Materials and Methods |
Cell culture and drug exposure. PC12 cells were grown
in DMEM supplemented with 5% FBS, 10% horse serum, and 1%
nonessential amino acids. PC12 cells overexpressing
gp140trk (cell line PC-6-24) were grown
in the same medium except that newborn calf serum was used
instead of FBS, and cells were maintained in the presence of 200 µg/ml G418 as previously described (Hempstead et al., 1992). Before
drug exposure, PC12 cells were plated onto collagen I (5 µg/ml;
Collaborative Biomedical Products, Bedford, MA), collagen
IV (2 µg/ml; Invitrogen, Burlington, Ontario, Canada), or laminin (5 µg/ml; Invitrogen) at a density of
3 × 106/100 mm dish for Western
blotting, 8.7 × 106/100 mm dish for
kinase assays or 5 × 105/35 mm dish
for neurite outgrowth assays and allowed to adhere overnight. Cells
were then exposed to NGF (Invitrogen) in serum-free DMEM with or without 100 µM of the
selective ILK inhibitor KP-392 (formerly known as KP-SD-1; Persad et
al., 2000, 2001a,b, Troussard et al., 2000; Tan et al., 2001).
Short-term exposures (4 hr) of PC12 cells to the ILK inhibitor were
preceded by a 1 hr preincubation. KP-392 was obtained from a local
pharmaceutical company (Kinetek Pharmaceuticals Inc.,
Vancouver, British Columbia, Canada) after a material transfer
agreement. For transfection experiments, E359K dominant-negative
ILK (ILK-DN), wild-type ILK (ILK-WT), or empty vector (Delcommenne et
al., 1998) were transiently expressed in PC12 cells using Lipofectamine
2000 (Invitrogen) 24 hr before cell plating. Cultures were
subsequently plated onto collagen I, serum-starved overnight, and
exposed to NGF. In experiments measuring neurite outgrowth, enhanced
green fluorescent protein (EGFP) was transiently cotransfected with
either ILK constructs or empty vector, and measurements were taken from
EGFP-positive cells. PC-6-24 cells were plated onto collagen I-coated
glass coverslips and allowed to differentiate for 2 d in the
presence of 50 ng/ml NGF. Cultures of cerebellar granule cells were
prepared from the cerebella of postnatal day 4-5 mice as previously
described (Cohen-Cory et al., 1991). Cells were plated on
laminin-coated glass coverslips in MEM containing 10% FCS and 25 mM KCl and allowed to adhere overnight.
Cerebellar cultures were then incubated in Neurobasal media
(Invitrogen) supplemented with B-27
(Invitrogen) and allowed to differentiate for 7-8 d
in vitro. DRG cells were isolated from stage
29-30 (E6-E6.5; 25) chick embryos (White Leghorn, Alberta) at lumbosacral levels. The DRG neurons were cultured on
coverslips coated with poly-L-lysine (100 µg/ml) and laminin (50 µg/ml) in DMEM-F-12 media containing
1% FBS, 20 ng/ml NGF, and 5 µg/ml insulin. One hundred micromolar
KP-392 (Kinetek Pharmaceuticals Inc.) alone or with 100 µM Boc-aspartyl (OMe)-fluoromethylketone (BAF;
Enzyme Systems Products, Dublin, CA) was added to the
explants before plating. DMSO (equal volumes) was added to control
cultures. Cells were subsequently cultured for 24 hr in the presence of drug or vehicle control. Cerebrocortical cultures were prepared from
embryonic day 15 or 16 Sprague Dawley rats as previously described (Bonfoco et al., 1995) and plated onto
poly-D-lysine-coated culture plates.
Cerebrocortical cultures were transiently transfected with ILK-DN or
ILK-WT using Lipofectamine 2000 (Invitrogen). Cultures were serum-starved 16 hr before drug addition and exposed to NGF (20 ng/ml) (Calbiochem, La Jolla, CA) for 15 min in Earle's
balanced salt solution and subsequently harvested for kinase assays.
Terminal deoxynucleotidyl transferase-mediated biotinylated
UTP nick end labeling and propidium iodide staining. For
terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick
end labeling (TUNEL) labeling, PC12 cells were plated onto
coverslips coated with poly-D-lysine (100 µg/ml) and collagen I. After a 48 hr drug treatment, DNA
fragmentation was measured in PC12 cells using the In Situ Cell Death
Detection Kit (Fluorescein; Boehringer Mannheim
Biochemicals, Indianapolis, IN) according to the methods of Miller et
al. (1997). Cells were then washed in PBS and mounted in Vectashield
mounting media containing DAPI (Vector Laboratories, Burlingame, CA). For propidium iodide staining, PC12 cells were incubated in DMEM containing propidium iodide (100 µg/ml) and Hoechst
33342 (50 µg/ml) for 15 min at room temperature, washed with PBS, and
fixed with 3% paraformaldehyde. The number of TUNEL-negative or
propidium iodide-negative cells were calculated as a percentage of
total cell number (DAPI or Hoechst-stained cells, respectively).
Assessment of neurite growth. The number of neurite-bearing
PC12 cells was assessed as previously described (Teng and Greene, 1994). In brief, cells with neurites were defined as those bearing a
process greater than twice the cell body length. The percentage of
cells with neurites for each treatment group was determined using
randomly chosen cell fields from duplicate wells. For transfected cultures, measurements were taken from PC12 cells expressing EGFP. Data
were expressed as mean ± SEM of four separate trials.
*p < 0.05 different from control cells plated onto the
same extracellular matrix. In DRG explants, the average length of
neurite bundles was measured from the outer edge of the explant to the
outer perimeter of the bulk of neurofilament-stained neurites. In
addition, individual neurite bundles were counted as they crossed each
concentric circle located at 500, 1000, and 1500 µm from the edge of
the explant. Ten DRG explants (taken from four separate platings) were
scored for both the control (DMSO) and experimental groups (KP-392). In
both PC12 cells and DRG neurons, paired t tests were used to determine the significance of observed differences.
Kinase assay and immunoprecipitations. Primary neuronal
cultures were washed in PBS and harvested in ice-cold lysis buffer (50 mM Tris-HCl, pH 8.0, 150 mM
NaCl, 1% Triton X-100, 0.1% deoxycholate, 1.1 mM PMSF, 10 µg/ml aprotinin, 2 mM orthovanadate, and 100 mM NaF). Lysates were precleared by
centrifugation (20 min at 14,000 × g), and protein
concentrations were determined using a BCA protein assay kit
(Pierce, Rockford, IL). Lysates were subsequently
immunoprecipitated with a monoclonal antibody (Upstate
Biotechnology, Lake Placid, NY) to ILK, and the protein kinase
assay was performed as previously described (Digicaylioglu and Lipton,
2001) using an N terminus, His-tagged fusion protein corresponding to
human AKT as a substrate (Upstate Biotechnology). After
the kinase assay, anti-ILK immune complexes were subjected to Western
blot analysis to measure phosphorylation of exogenous AKT at Ser-473.
ILK kinase activity was measured in PC12 cells after
immunoprecipitation with a monoclonal anti-ILK antibody (Upstate
Biotechnology) as described above or by
32P phosphorylation of exogenous AKT. The
latter ILK immunoprecipitation kinase assay is a modification of one
used for phosphoinositide-dependent kinase-1 (PDK) activity
(Upstate Biotechnology). Levels of the p85 regulatory
subunit of PI-3 kinase in anti-phosphotyrosine immunoprecipitates of
PC12 cells were analyzed as a control for KP-392. A specific antibody
against phosphotyrosine (PY20; Santa Cruz Biotechnology,
Santa Cruz, CA) was used for immunoprecipitations.
Western blotting. Rodent tissue, harvested from 6- to
8-week-old rats (250-275 gm adult male Sprague Dawley),
and PC12 cell homogenates were prepared in Tris-HCl buffer, pH 7.6, containing 1% NP-40, 150 mM NaCl, 1 mM EDTA, 3.8 µg/ml aprotinin, 1 µg/ml leupeptin, 1 mM PMSF, 2 mM
NaF, and 1 mM
Na3VO4. NP-40 buffer has
previously been shown to be suitable for the recovery of other focal
adhesion proteins (Ling et al., 1999). For Trk (tyrosine kinase)
Western blots, lysis buffer was supplemented with 0.1% SDS. After
sonication, 20 µg of protein was separated by 10% SDS-PAGE and
transferred electrophoretically to polyvinylidene difluoride. Human
tissue was solubilized in buffer containing 0.1% Triton X-100, and 15 µg of sample was separated by 15% SDS-PAGE. Membranes were probed
with antibodies to the following: ILK (StressGen Biotechnologies Corporation, Victoria, British Columbia, Canada; Upstate
Biotechnology), AKT (New England Biolabs, Mississauga,
Ontario, Canada), phospho-AKT Ser-473 (New England
Biolabs), GSK-3 (BD PharMingen, Mississauga, Ontario, Canada), phospho-GSK-3 / (Ser-21/9; New England
Biolabs), p38 MAPK (mitogen-activated protein kinase)
(New England Biolabs), phospho-p38 MAPK (New England
Biolabs), tau-1 (Chemicon, Temecula, CA), paired
helical filament (PHF-1; a kind gift from Dr. Davies, The Albert
Einstein College of Medicine), Trk (C14; Santa Cruz Biotechnology), phosphospecific TrkA
(Tyr490; New England
Biolabs), and histones (H1 and core proteins;
Chemicon). For Western blots of extracellular
signal-regulated kinase (ERK), protein was separated on 12.5% low bis
gels (acrylamide:bis ratio 118.5:1), transferred and probed using a
phospho-ERK antibody (New England Biolabs). Western blots
of AKT, GSK-3, p38 MAPK, and TrkA were probed first with
phosphospecific antibodies, stripped using Restore buffer
(Pierce), and subsequently reprobed with nonphosphospecific antibodies as controls for total protein expression. Western blots of Tau were probed first with anti-PHF-1,
a phosphorylation-dependent antibody that binds a phosphoserine residue
(phosphoserine 396) which lies next to the microtubule binding domain
of Tau and then with anti-Tau-1 a
phosphorylation-independent antibody. All antibodies, were used at a
dilution of 1:1000 except for the following: anti-PHF-1 (1:50),
anti-Tau-1 (1:500), anti-phosphospecific TrkA (1:500), and
anti-histones (1:500).
Human multiple tissue expression array. A
32P-labeled cDNA probe corresponding to
the 5' end of ILK (ATG-BamHI) was generated by random prime
labeling (Redi-prime II, Amersham Pharmacia Biotech, Baie
d-Urfé, Quebec, Canada). The specificity of the probe was assured
by standard Northern blot analysis (human 12-lane multiple tissue
Northern blot; Clontech, Palo Alto, CA). The tissue
distribution of ILK was measured by hybridization of the probe to a
multiple tissue mRNA dot blot (human multiple tissue expression array; Clontech). All hybridizations and subsequent washing steps
were performed according to the manufacturer's protocol. The resulting blot was then visualized by autoradiography. Expression was quantified with a Storm 860 PhosphorImager (Molecular Dynamics, Sunnyvale, CA) and the accompanying ImageQuant analysis software, version 4.1 (Molecular Dynamics). Data from individual spots were
then corrected for background signal (Cot 1 DNA) and normalized against the signal obtained from 100 ng of genomic DNA.
Immunocytochemistry. Human brain sections (3-5
µM) cut from paraffin-embedded tissues were
deparaffinized, permeabilized in 0.2% Triton X-100, and stained using
a polyclonal antibody against ILK (1:250; Upstate
Biotechnology). The sections were incubated with a biotinylated
anti-rabbit IgG followed by a streptavidin-horseradish peroxidase
conjugate. The final reaction product was visualized with DAB. Controls
included replacement of the primary antibody with normal rabbit IgG.
Cultured cells were fixed for 10 min in 3-4% paraformaldehyde in PBS,
pH 7.4. Depending on the antigen, cells were solubilized in 0.02% or
0.1% Triton X-100 and blocked in PBS containing 5% NGS and 1% BSA.
Primary antibodies to ILK (1:400; StressGen Biotechnologies Corporation; 1:100, Upstate Biotechnology), or
neurofilament (1:500, Sigma-Aldrich,
Oakville, Ontario, Canada) were incubated for 1 hr at 37°C or
overnight at 4°C. Protein was detected after incubation at 37°C
with anti-rabbit rhodamine-conjugated (Santa Cruz
Biotechnology) or Cy3-conjugated (Jackson
ImmunoResearch, Mississauga, Ontario, Canada)
secondary antibodies. For double-labeling studies of mouse cerebellar
granule cultures, a monoclonal antibody to ILK (Upstate Biotechnology) and rabbit polyclonal anti-1 antiserum (a kind gift from Dr. S. Carbonetto, McGill University) was incubated as stated
above, and protein was detected after incubation with anti-rabbit
rhodamine-conjugated (Santa Cruz Biotechnology) or anti-mouse fluorescein isothiocyanate-conjugated secondary antibodies (Santa Cruz Biotechnology). In the double-labeling
experiments, data were collected sequentially to prevent bleedthrough.
Specificity of the immunofluorescence was established by comparing
sister cultures incubated with the same concentration of rabbit IgG or secondary antibody alone.
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Results |
Expression levels of ILK in rat and human tissue
Messenger RNA levels of ILK are expressed in a wide variety of
tissue, including the heart, kidney, and brain (Hannigan et al., 1996).
Although ILK protein expression in various brain regions has not been
studied, high ILK immunoreactivity in tumors with primitive neural
differentiation has recently been demonstrated (Chung et al., 1998).
Hybridization of a human multiple tissue expression array of
poly(A+) selected RNA with an ILK cDNA
probe indicate that ILK is expressed in a variety of brain regions
(Fig. 1A). Furthermore,
Western blot analysis indicate protein expression to be high in various brain regions relative to tissue known to express high ILK mRNA levels
such as the heart. Areas of the brain expressing high ILK levels
include the cortex, hippocampus, and cerebellum. Immunoblot analysis of
homogenates taken from the fetal or adult human brain reveal that
protein levels of ILK increase with age (Fig. 1C). This
finding is consistent with the dot blot analysis because ILK mRNA
levels were approximately four times higher in the adult human brain
than in the fetal brain (16.4 and 4.8/100 ng of DNA, respectively).
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Figure 1.
ILK transcript and protein expression in rat and
human tissue. A, Human multiple tissue expression array.
The signals obtained by hybridization of an ILK-specific probe to the
multiple tissue expression membrane were quantified by phosphoimage
analysis, as described in Materials and Methods. The data are
represented as fold increases over the signal obtained from 100 ng of
genomic DNA. Inset, Specificity of the ILK probe was
assured by Northern blot analysis. B, Top, Rat
homogenates from neural (olfactory bulb, lane 1; frontal
cortex, lane 2; hippocampus, lane 3;
pons, lane 4; striatum, lane 5;
cerebellum, lane 6) and non-neuronal (kidney,
lane 7; heart, lane 8) tissues were
immunoblotted and probed with an ILK polyclonal antibody from Upstate
Biotechnology. Bottom, Western blots were also probed
with a histone H1 monoclonal antibody as a loading control.
C, Representative Western blot, performed in triplicate,
showing ILK expression in adult or fetal (7 week) human brain tissue.
ILK was visualized using a rabbit polyclonal antibody (Upstate
Biotechnology).
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Immunocytochemical localization of ILK in neuronal cells
Although Western blot analysis revealed high expression of ILK in
the rat CNS, the cellular and subcellular distributions of
ILK were unknown. To address these questions, human brain slices were
stained for ILK. ILK-immunoreactive cells were detected within the same
regions of the human brain that expressed ILK mRNA and ILK protein
(Fig. 2). High magnification of human
hippocampal and cerebellar coronal sections reveal intense ILK
immunoreactivity in the neuronal cell bodies and dendrites of CA1
pyramidal cells and Purkinje cells, respectively. In contrast, the
neuronal cell nucleus appeared devoid of ILK staining (Fig. 2).
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Figure 2.
Immunohistochemical staining of ILK is enhanced in
neurons from the human hippocampus and cerebellum. Coronal sections
through the hippocampus (top left panel) or
cerebellum (bottom left panel) showing high
somatodendritic ILK immunoreactivity in both CA1 pyramidal cells and
Purkinje cells, respectively. IgG controls for both sections are shown
in the adjacent panels. Scale bar, 50 µm.
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Immunocytochemical localization of ILK in cultured cells plated on
various ECM substrates was similar to the staining pattern observed in
paraffin-embedded sections. In neuronal cells grown in
vitro, ILK immunoreactivity was strong throughout the neuronal cell body and processes (Fig. 3). In
differentiated PC12 cells overexpressing gp
140trk and grown on collagen-coated
coverslips, ILK staining produced a granular pattern that was
especially evident in the soma and neurite tip (Fig. 3A).
PC12 cells overexpressing gp 140trk were
used simply for convenience because they differentiated more rapidly. A
similar staining pattern for ILK was observed for wild-type PC12 cells
cultured alone or in the presence of NGF (J. Mills and S. Dedhar,
unpublished observations). At the growth cones of DRG neurons, ILK
staining was punctate and uniformly distributed and extended to the
periphery of growth cones into the tips of filopodia (Fig.
3E). The fine punctate staining of ILK is reminiscent of
point contacts (Arregui et al., 1994) and is consistent with a
cytoskeletal associated protein. Indeed the colocalization
of ILK with the 1 integrin subunit in cerebellar granule neurons
supports this hypothesis (Fig. 3F-H). In contrast, axonal staining of ILK in DRG neurons was more continuous and appeared
to be cytoskeletal-associated (Fig. 3C,D). This tubular staining pattern extended into the neuritic shaft and central regions
of the growth cone (Fig. 3D).
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Figure 3.
Immunocytochemical localization of ILK and 1
integrin in neuronal cells. Labeling of cells with ILK reveal both a
punctate and continuous staining pattern with concentrations at the
axon, neurite tip, and periphery of the cell soma. A,
Punctate immunoreactivity was evident in differentiated PC12 cells
overexpressing gp140trk and plated onto collagen I
after incubation with a polyclonal ILK antibody
(A) but was not present in the corresponding IgG
controls (B). Immunoreactivity to an anti-ILK
antibody was continuous at the axons of DRG neurons plated onto laminin
(C, D) but appeared more patchy and granular at the
growth cone (E). Codistribution of ILK and the
1 integrin subunit occurred throughout the neuronal cell body and
processes of cerebellar granule neurons (F-H).
Area outlined by the box
(H) is shown here at a higher
magnification (I). Scale bar, 20 µm.
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NGF-induced phosphorylation of AKT on serine-473 is dependent on
ILK activity
In neuronal cell lines, integrin and NGF binding have been shown
to result in activation of the PI-3 kinase-dependent-AKT signaling
pathway (Andjelkovic et al., 1998; Ashcroft et al., 1999; Sarner et
al., 2000). To determine whether NGF stimulates ILK and leads to AKT
signaling, PC12 cells were stimulated with NGF, and ILK activity was
measured using AKT as a substrate. Using a sensitive radioactive
in vitro kinase assay, we found that ILK activation in PC12
cells plated onto laminin was maximal at 20 ng/ml NGF (Fig.
4A). Similarly, using
an alternate approach (Digicaylioglu and Lipton, 2001) ILK activity in
PC12 cells plated onto collagen I was found to increase after a 10 min
exposure to NGF (Fig. 4B). To determine the
importance of ILK in NGF-induced neuronal signaling, PC12 cells were
plated onto various ECM and stimulated with NGF in the presence
of KP-392, a pharmacological inhibitor of ILK or after transient
transfection of ILK-DN. KP-392 has previously been shown to be a highly
selective ILK inhibitor, reducing phosphorylation of AKT on
Ser-473 in a dose-dependent manner while having no effect on
phosphoinositide-dependent kinase-1 (PDK-1), a kinase that regulates
AKT by Thr-308 phosphorylation (Persad et al., 2000, 2001a,b; Troussard
et al., 2000; Tan et al., 2001). Also, this small molecule inhibitor
has been shown to be selective for ILK compared with a number of other
purified protein kinases in vitro (Persad et al., 2001a).
The IC50 of KP-392 for ILK is ~0.3
µM compared with 25 µM
or higher for the other kinases tested (Persad et al., 2001a). A higher
concentration of the inhibitor is required when used on whole cells,
probably because of poor cell permeability, but the selectivity of the
inhibitor for ILK should be maintained in vivo.
Phosphorylation of ERK and p38 MAPK in PC12 cells was not inhibited by
KP-392 at concentrations that resulted in decreased GSK-3 and AKT
phosphorylation (Fig. 4C,E). As has been shown for non-neuronal cells, Western blot analysis of PC12 cell lysates probed
with phosphospecific antibodies for AKT and GSK-3 indicate that ILK is
upstream from AKT and GSK-3 in PC12 cells. PC12 cells, plated onto
collagen I were stimulated with NGF for 4 hr in the presence of vehicle
control or increasing concentrations of KP-392. NGF-induced stimulation
of both AKT and GSK-3 phosphorylation was inhibited by KP-392 in a
concentration-dependent manner (Fig. 4C). These observations
suggest ILK resides downstream from a Trk receptor-mediated signaling
pathway and that ILK regulates both AKT and GSK-3 in neuronal cell
lines. Lysates run in parallel were also probed for phospho-p38 MAPK
because a recent study indicated that p38 MAPK was involved in
ILK-mediated signal transduction and neurite outgrowth in N1E-115 cells
deprived of serum (Ishii et al., 2001). Exposure of PC12 cells to NGF
for 4 hr induced a marked reduction in p38 MAPK phosphorylation. A
comparatively small decrease in p38 MAPK phosphorylation was evident at
the highest concentration of KP-392. This suggests that although p38 MAPK may be involved in ILK-mediated signal transduction in the absence of trophic support, in the presence of trophic factors, p38
MAPK may play a lesser role. Evidence that KP-392 is a specific inhibitor of ILK was obtained by analyzing the phosphorylation levels
of other proteins known to be important in Trk receptor-dependent signaling. A 100 µM concentration of KP-392 did
not reduce tyrosine phosphorylation levels of the p85 regulatory
subunit of PI-3 kinase and TrkA (Tyr490)
when exposed to PC12 cells for 4 hr in the presence of NGF (Fig. 4D). The effects of KP-392 on NGF-induced
phosphorylation of AKT and GSK-3 were maintained during long-term
exposure. PC12 cells plated onto various ECM substrates were stimulated
with NGF for 48 hr in the presence or absence of KP-392 (100 µM). Western blot analysis indicate that the
effects of KP-392 on AKT and GSK-3 phosphorylation were maintained
during this time course (Fig. 4E). Lysates run in
parallel were also immunoblotted with phosphospecific ERK 1 and 2 antibodies, because sustained ERK phosphorylation has been associated
with Trk receptor stimulation in PC12 cells (Qui and Green, 1992).
Further evidence for the specificity of KP-392 as an inhibitor of the
PI-3 kinase-dependent AKT signaling pathway is indicated by the
observation that ERK phosphorylation was not suppressed by ILK
inhibition (Fig. 4E). The modest increase in ERK
phosphorylation in the presence KP-392 was not consistently found
between trials (n = 3). Transient overexpression of
ILK-DN in PC12 cells also reduced NGF-stimulated cell signaling. PC12 cells were transfected with ILK-DN:V5 24 hr
before plating onto collagen I. Exposure of PC12 cells to NGF
for 15 min increased AKT and GSK phosphorylation, and this effect
was significantly reduced when ILK-DN was transiently overexpressed
(Fig. 4F).
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Figure 4.
ILK inhibition reduces AKT and GSK-3
phosphorylation in PC12 cells after NGF receptor stimulation.
A, NGF increases ILK activity in a
concentration-dependent manner. PC12 cells, plated onto laminin, were
exposed to increasing concentrations of NGF for 30 min. After
immunoprecipitation, ILK activity was measured by AKT substrate
radiolabeling. Top, Average CPM of AKT substrate
radiolabeling; n = 3 ± SEM.
Bottom, Representative in vitro kinase
assay. B, NGF increases ILK phosphorylation of AKT
Ser-473. ILK kinase activity was measured in PC12 cells plated onto
collagen I after a 10 min exposure to NGF (100 ng/ml). ILK activity was
measured using a His-tagged fusion protein corresponding to human AKT
as an exogenous substrate. Phosphorylation of the substrate by ILK is
detected using a phosphospecific anti-AKT Ser-473 antibody. The
antibody control (lane 3) corresponds to lysate
immunoprecipitated with an irrelevant antibody (anti-flag monoclonal
antibody; Upstate Biotechnology). C, KP-392
inhibits NGF stimulation of AKT and GSK phosphorylation in a
dose-dependent manner. Western blots of lysates from PC12 cells grown
on collagen I and treated with NGF (50 ng/ml) for 4 hr in the presence
of vehicle control or increasing concentrations of KP-392.
Representative Western blots of cell lysates, run in parallel and
probed with antibodies for phospho-AKT, phospho-GSK-3, or phospho-p38
MAPK; n = 3-5. These same blots were subsequently
stripped and reprobed for AKT, GSK-3, or p38 MAPK as a control for
protein expression levels. D, KP-392 does not inhibit
phosphorylation of PI-3 kinase or TrkA. Left,
Representative Western blot of PC12 cell lysates from PC12 cells
treated for 4 hr with NGF in the presence or absence of KP-392 (100 µM) and probed with a phosphospecific antibody for TrkA
(Tyr490). Right, Levels of the p85
regulatory subunit of PI-3 kinase were analyzed in anti-phosphotyrosine
immunoprecipitates by Western blotting. E, Long-term
effects of KP-392 (100 µM) on cell signaling in PC12
cells grown on collagen I (Col I), collagen IV
(Col IV), or laminin (L)
and incubated in the presence or absence of NGF (50 ng/ml) for 48 hr. Representative Western blots of cell lysates, run in
parallel and probed with antibodies for phospho-AKT, phospho-GSK-3, or
phospho-ERK; n = 3. After membrane stripping,
Western blots were subsequently reprobed for AKT, GSK-3, and ERK.
F, Overexpression of ILK-DN decreases NGF-induced
stimulation of AKT and GSK-3 phosphorylation. PC12 cells were
transfected with ILK-DN:V5 or EmptyV5.
Twenty-four hours after transfection, cells were replated onto collagen
I and were serum-starved overnight. Representative Western blots of
phospho-AKT and phospho-GSK-3 after a 15 min exposure to NGF (50 ng/ml); n = 3. These same Western blots were
subsequently stripped and reprobed with an anti-V5 or
anti-GSK-3 antibody, respectively.
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To determine whether growth factors stimulated ILK activity in primary
neurons, in vitro kinase assays were performed on rat cerebrocortical cultures using AKT as a substrate and analyzing phosphorylation at Ser-473 (Fig. 5).
A 15 min exposure to NGF (20 ng/ml) stimulated ILK
activity. NGF stimulation of ILK activity was blocked in cultures
transfected with the ILK-DN. Similarly, a concentration-dependent
reduction of kinase activity after ILK-WT transfection and ILK-DN was
observed with increasing amounts of ILK-DN plasmid.
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Figure 5.
NGF increases phosphorylation of AKT Ser-473:
effect of ILK-DN and ILK-WT overexpression in primary neurons.
Top, ILK in vitro kinase activity was
measured in rat cerebrocortical cultures after a 15 min exposure to
NGF. NGF increased ILK phosphorylation of AKT Ser-473. Growth factor
stimulation of AKT phosphorylation was inhibited after overexpression
of ILK-DN (lanes 2 and 6, respectively).
Competition of ILK-WT was observed with increasing concentrations of
ILK-DN (the ratio of ILK-WT:ILK-DN is indicated above).
Bottom, Immunoblots were stripped and subsequently
reprobed with an anti-AKT antibody as a control for His-tagged, AKT
fusion protein loading.
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ILK inhibition increases tau hyperphosphorylation
GSK-3, a kinase highly expressed in the CNS (Takahashi et al.,
1994) directly phosphorylates the microtubule-associated protein Tau, a protein involved in microtubule stability and
maintenance of neuronal processes. Activation of GSK-3 (as a result of
decreased phosphorylation) leads to Tau
hyperphosphorylation, which in turn reduces both Tau binding
to microtubules (Hong and Lee, 1997) and axon stability (Sayas et al.,
1999). These phosphorylated forms of Tau can be recognized
by monoclonal antibodies raised against the "Alzheimer's-like"
state of Tau such as the phosphorylation-dependent antibody
PHF-1 (serines 396/404). NGF has previously been shown to increase
Tau protein expression in PC12 cells (Sado et al., 1995).
Indeed, we found that both total Tau (Tau-1
immunoreactivity) and hyperphosphorylated Tau (PHF-1
immunoreactivity) increased concurrently in PC12 cells exposed to NGF
compared with media alone, a finding consistent with this previous
report (Fig. 6). However, only PHF-1
immunoreactivity was higher in KP-392-treated cultures in the presence
of NGF, suggesting that this increase was attributable to increased
phosphorylation of Tau. Densitometric analysis of PHF-1
Western blots indicate that KP-392 increased Tau
hyperphosphorylation in the presence of NGF: KP-392 increased PHF-1 in
cells plated onto collagen I, collagen IV, and laminin by 1.8, 1.7, and
1.8 ± 0.28, 0.27, and 0.54 SEM, respectively (n = 3-5) (values expressed as fold above NGF alone). The observation that
KP-392 increased hyperphosphorylation of Tau is consistent with the effect of KP-392 on the phosphorylation state of the Tau kinase GSK-3. Hyperphosphorylation of Tau is
decreased in the execution phase of apoptosis (Mills et al., 1998).
Therefore the finding that KP-392 increases Tau
hyperphosphorylation suggests that ILK inhibition does not affect PC12
cell survival and was consistent with more direct measurements of
neuronal cell viability (see Fig. 9)
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Figure 6.
ILK inhibition increases Tau
hyperphosphorylation in PC12 cells after integrin and NGF receptor
stimulation. A representative Western blot of the effect of KP-392 (100 µM) on levels of PHF-1 in PC12 cells grown on collagen I
(Col I), collagen IV (Col
IV), or laminin (L) after a 48 hr
incubation in media lacking serum with or without NGF (50 ng/ml);
n = 3. The bottom panel shows
Tau-1-immunoreactive bands from the same blot as a control for protein
expression levels.
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ILK inhibition decreases NGF-induced neurite outgrowth in PC12
cells and DRG neurons plated onto various ECM
The precise role of a PI-3 kinase-AKT-dependent pathway in
mediating NGF-induced differentiation is controversial. However, several reports suggest that although PI-3 kinase activity may not be
sufficient, it is necessary for the initiation of process formation
(Kimura et al., 1994; Jackson et al., 1996; Kobayashi et al., 1997;
Ashcroft et al., 1999). Because ILK appears to be an important effector
in this signaling pathway, we examined whether ILK was necessary for
neurite outgrowth. Therefore, we measured NGF-induced neurite outgrowth
in PC12 cells and DRG neurons with or without KP-392 to determine the
importance of ILK in neurotrophin-induced process formation. Neurite
formation in PC12 cells grown on collagen I, collagen IV, and laminin
was significantly reduced in the presence of KP-392 (Fig.
7A) (results were normalized
to growth on collagen I). Similarly, transient expression of ILK-DN in
PC12 cells significantly inhibited NGF-induced neurite formation
compared with control cells expressing the empty vector (Fig.
7B). Axonal outgrowth of DRG neurons grown on laminin in the
presence of 20 ng/ml NGF was significantly reduced in the presence of
100 µM KP-392 compared with vehicle control.
Both the average axon length and the number of cells having neurites
>500, 1000, or 1500 µm (Figs. 7C,D,
8) was significantly reduced in DRG
neurons exposed to KP-392.
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Figure 7.
Inhibition of ILK attenuates NGF-induced neurite
outgrowth in PC12 cells and DRG cells. A, NGF-induced
neurite outgrowth was assessed in PC12 cells grown for 48 hr on various
ECM [collagen I (Col I), collagen IV (Col
IV), or laminin (L)], in the
presence or absence of KP-392 (100 µM) or drug vehicle.
The number of neurite-bearing PC12 cells after NGF treatment was
significantly reduced in the presence of KP-392. Data represent four
independent experiments ± SEM and have been normalized to PC12
cells grown on collagen I. *p < 0.05, different from control cells plated onto the same extracellular matrix.
B, NGF-induced neurite outgrowth was measured in PC12
cells plated onto collagen I and transiently cotransfected with ILK-WT,
ILK-DN, or empty vector together with EGFP. The percentage of
neurite-bearing cells was determined from cells positive for EGFP
expression. Data represent four independent experiments ± SEM.
*p < 0.05, different from control cells plated on
collagen I. C, Average length of axon front cultured in
the presence of KP-392 for 24 hr was significantly decreased compared
with the drug vehicle. D, Assessment of the total
percentage of neurite bundles reaching a distance of 500, 1000, or 1500 µm shows a significant decrease at each distance in the presence of
KP-392. Data represent 18 explants from four independent
experiments ± SEM. *p < 0.05, different from
treatment groups lacking inhibitor grown on the same extracellular
matrix.
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Figure 8.
Representative explants of DRG neurons with
neurofilament (1:500, Sigma-Aldrich) labeled
neurites after 24 hr in the presence of KP-392 (A, C) or
DMSO (B, D). Outgrowth was assayed using a series of
concentric circles at radia of 500, 1000, or 1500 µm (C,
D) measured from the edge of the explant. The center of the
circles were placed around the edge of the entire explant to obtain an
accurate assessment of the total number of axon bundles crossing each
distance.
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ILK inhibition does not reduce neuronal cell survival
Inhibition of ILK has been shown to induce apoptosis by reducing
AKT activity and by stimulating caspase activity in non-neuronal cells
(Attwell et al., 2000). Therefore, to ensure that KP-392 was not
inhibiting neurite outgrowth by adversely affecting survival, we
measured survival by either TUNEL labeling or staining with the DNA dye
propidium iodide and counting nonapoptotic nuclei (Fig.
9). The percentage of either propidium
iodide-negative or TUNEL-negative PC12 cells plated onto collagen or
laminin was not reduced by a 48 hr exposure to KP-392 (Fig.
9A-H). Moreover, KP-392-induced suppression of
neurite outgrowth occurred in viable (propidium-negative) PC12 cells
(Fig. 9A-D). Finally, in DRG neurons, KP-392-induced
suppression of neurite outgrowth was not rescued by the caspase
inhibitor BAF (Fig. 9I-K). Exposure of DRG neurons to NGF together with BAF appeared to increase the total number of
neurites above control (data not shown). Taken together, these results
suggest that KP-392-induced suppression of neurite outgrowth is not
occurring as a result of compromised cell viability.
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Figure 9.
Inhibition of ILK does not decrease neuronal cell
survival in the presence of NGF. A-D, Phase-contrast
and fluorescence photomicrographs of PC12 cells plated onto laminin
(A, B) or collagen IV (C, D) and exposed
to NGF with or without KP-392. After 2 d, cells were fixed and
stained with propidium iodide and Hoechst 33342. Inhibition of neurite
outgrowth by KP-392 was independent from propidium iodide staining.
E-G, Representative fluorescence photomicrographs of
PC12 cells plated onto collagen I and exposed to NGF with or without
KP-392. After 2 d cells were labeled for TUNEL
(right). DAPI staining corresponding to each of these
fields is shown in the adjacent left panel. A positive control,
performed according the manufacturer's instructions (In Situ Cell
Death Detection Kit; Boehringer Mannheim) is included
(G). H, To assess survival, the
number of propidium iodide-negative cells or TUNEL-negative cells was
determined and expressed as a percentage of total cell number
(Hoechst-positive or DAPI-positive cells, respectively);
n = 3 ± SD. I-K, Caspase
inhibition did not block KP-392 effects on DRG neurite outgrowth. DRG
neurons with neurofilament-labeled neurites after 24 hr in the presence
of NGF alone (I), with KP-392
(J), or KP-392 combined with the caspase
inhibitor BAF (K).
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Discussion |
Our study is the first to examine a role for ILK in
neurons. We provide novel information on the expression pattern of ILK in the rodent and human brain and show that ILK colocalizes
with the 1 integrin subunit in neuronal cell bodies and processes. Moreover, we have examined a role for ILK in neuronal cell signaling and find that ILK regulates AKT during neurite growth promotion by NGF.
We show that phospho-inhibition of the Tau kinase GSK-3, a
physiological target of AKT and ILK, is also reduced by ILK inhibition
leading to Tau hyperphosphorylation. These findings provide
new insight into how growth factors may bring about cytoskeletal changes necessary for differentiation and suggest that ILK is an
important effector in NGF-mediated neurite outgrowth.
Trophic effects of growth factors such as NGF are mediated by
recruitment and activation of PI-3 kinase at the plasma membrane (Kaplan and Miller, 1997, 2000). PI-3 kinase activity promotes the
production of the second messengers PI(3, 4, 5)P3
and PI(3, 4)P2. High-affinity association
of these second messengers with AKT allows for its translocation to the
membrane and subsequent activation (Andjelkovic et al., 1997). In
non-neuronal cells, activation of AKT is regulated via
phosphorylation at two sites, Thr-308 and Ser-473, by PDK-1 (Downward,
1998; Datta et al., 1999) and ILK (Delcommenne et al., 1998; Attwell et
al., 2000; Persad et al., 2000), respectively. Despite the potential
importance of ILK and PDK-1 in regulating AKT, the role of these
kinases in neuronal AKT-dependent pathways has not been characterized. Using Western blot analysis we show that ILK regulates AKT
phosphorylation after NGF stimulation of PC12 cells grown on collagen
and laminin. Furthermore, we show that ILK kinase activity is
stimulated by this neurotrophin in primary neurons. Our findings
indicate that ILK is an important regulator of growth factor-mediated
signaling in neurons and present ILK as a potential effector, linking
PI-3 kinase activation and AKT regulation. Our observation extends the
role of ILK in growth factor signaling to include members of the
neurotrophin family.
During neurite outgrowth, soluble or substrate-bound cues must be
translated into cytoskeletal rearrangements (Gallo and Letourneau, 1999, 2000). One way extracellular cues can regulate these cytoskeletal changes is through signaling pathways that phosphorylate proteins involved in axonal stability, such as Tau. The
Tau kinase GSK-3 is negatively regulated by AKT through
phospho-inhibition. Inhibition of GSK activity is thought to be
important during neuronal differentiation (Garcia-Perez et al.,
1999; Hall et al., 2000) and prevents axonal instability by preventing
hyperphosphorylation of the microtubule-associated protein
Tau. Tau hyperphosphorylation has previously been
shown to decrease the association of Tau with microtubules
(Hong and Lee, 1997) and inhibit total neurite number (Cressman and
Shea, 1995; Malchiodi-Albedi et al., 1997; Sayas et al., 1999). Our study has demonstrated that ILK also modulates GSK-3 activity in
neuronal cells. We show that the ILK inhibitor KP-392 decreased both
NGF and integrin receptor-mediated phospho-inhibition of GSK-3. This
suggests that, as in non-neuronal cells, ILK activation results in
phospho-inhibition of GSK-3 either directly (Delcommenne et al., 1998;
Troussard et al., 1999) or indirectly via AKT (Cross et al., 1995).
Downregulation of GSK-3 by ILK was further suggested by the finding
that ILK inhibition coincidentally promoted hyperphosphorylation of the
GSK-3 substrate Tau. Furthermore, ILK inhibition was shown to reduce neurite outgrowth in both PC12 cells and DRG
neurons. Therefore, we propose that integrin and growth factor-mediated signaling upregulates ILK and AKT activity, which in turn
downregulates GSK-3 activity and Tau hyperphosphorylation.
This model supports a role for ILK in promoting increased stabilization
of axonal structures during neurite outgrowth (Fig.
10).
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Figure 10.
Schematic model of integrin and NGF-mediated ILK
regulation of differentiation. ILK activity is regulated by integrins
and growth factors in a PI-3 kinase-dependent manner. Active ILK
phosphorylates AKT on Ser-473, resulting in its activation. Activated
AKT in turn phosphorylates and inhibits GSK-3. ILK may also inhibit
GSK-3 activity directly. Inhibition of ILK by KP-392 would thus
increase GSK-3 activity and result in Tau
hyperphosphorylation, microtubule instability, and decreased neurite
growth.
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NGF is involved in multiple cellular processes, including
differentiation and cell survival. A role for PI-3 kinase/AKT signaling in NGF-induced neurite outgrowth and anti-apoptotic effects of NGF has
been found (Kimura et al., 1994; Yao and Cooper, 1995; Jackson et al.,
1996; Kobayashi et al., 1997; Ashcroft et al., 1999). In the present
study, although ILK inhibition decreased AKT activity and
phosphoinhibition of GSK-3, suppression of neurite outgrowth did not
appear to occur as a result of compromised cell viability (Fig. 9).
This finding is somewhat surprising given the fact that AKT and GSK-3
have been identified as key effectors of an NGF-induced PI-3 kinase
survival pathway (Yao and Cooper, 1995; Pap and Cooper, 1998). One
difference between these studies and ours is the presence of
extracellular matrix adhesion during long-term exposure to NGF. This
may be an important distinction because integrin engagement results in
activation of a PI-3 kinase-AKT survival pathway in neuronal cells
(Gary and Mattson, 2001). Given that NGF and integrins both activate
this signaling pathway it is likely that neuronal resistance to
apoptosis induced by AKT inhibition is higher in the presence of these
two survival signals. Similarly, comparisons between our studies and
previous studies are confounded by the fact that PI-3 kinase inhibitors
or mutant receptors that fail to activate PI-3 kinase inhibit other
phosphoinositide-dependent kinases in addition to ILK (Toker and
Newton, 2000).
To date, studies on the role of ILK have primarily emphasized the
contribution of ILK to oncogenic transformation, a process that is
tightly linked with its cell survival functions. For example, overexpression of ILK in epithelial cell suppresses anoikis and promotes anchorage-independent growth and tumorigenicity in
vivo (Dedhar, 2000). Some of these changes are likely the result
of the activation of AKT by ILK, an effect known to inhibit apoptosis. Indeed, in a number of human malignancies there is a loss in the expression or activity of the tumor suppressor PTEN (phosphatase and
tensin homolog deleted on chromosome 10), a protein phosphatase responsible for the conversion of PI(3,4,5)P3 to
PI(4, 5)P2. Because ILK is dependent on
PI(3,4,5)P3 for its full activation, absence of
PTEN results in constitutively activated ILK and AKT (Persad et al.,
2001b). Elevated basal ILK and AKT activity may make this malignant
cell model more vulnerable to KP-392-induced apoptosis. The role of ILK
in survival functions may also be dependent on trophic factors because
inhibition of ILK activity has been shown to increase apoptosis in the
absence of trophic support (Attwell et al., 2000). More recently, the
role of ILK in differentiation and motility have begun to be explored.
For example, ILK has been shown to have a role in myogenic
differentiation and Ca2+-independent
smooth muscle contraction (Huang et al., 2000; Deng et al., 2001). In
the neuronal cell line N1E-115, p38 MAPK appears to be involved in
ILK-mediated signal transduction and differentiation in the absence of
trophic support, whereas our study indicates that p38 MAPK plays a
lesser role in the presence of trophic factors such as NGF. The
neuroprotective properties of NGF may also explain why ILK inhibition,
in our study, did not appear to decrease neuronal cell survival.
Clearly involvement of ILK in these multifactorial cell processes is
both context- and cell type-specific.
Integrins, a major class of ECM receptors, often partner with growth
factors to integrate soluble and substrate-bound cues for maximal
neurite outgrowth. Mechanisms that underlie this coordinated action in
neurite outgrowth have only recently been addressed. For example, it
has been shown that NGF increases the expression of integrins (Zhang et
al., 1993) that accumulate as dense aggregates at the tips of filopodia
(Grabham and Goldberg, 1997), thereby potentially altering
integrin-cytoskeletal interactions at neuronal growth cones. Although
it has been shown that both integrins and growth factors stimulate PI-3
kinase-dependent differentiation pathways, the level of interdependence
of these extracellular cues is unknown. Because ILK appears to regulate
the microtubule-associated protein Tau and link integrins to
the actin cytoskeleton, ILK may be an important effector, regulating
various cytoskeletal rearrangements necessary for integrin and/or
growth factor-mediated neurite outgrowth.
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FOOTNOTES |
Received April 29, 2002; revised Dec. 3, 2002; accepted Dec. 6, 2002.
This work was supported by research grants to S.D. from the National
Cancer Institute of Canada and Canadian Institutes of Health Research
(CIHR) and by research grants to M.D. from the National Institutes of
Health. J.M. is supported by a fellowship from the CIHR.
Correspondence should be addressed to Shoukat Dedhar, Jack Bell
Research Centre, 2660 Oak Street, Vancouver, British Columbia, Canada
V6H 3Z6. E-mail: sdedhar{at}interchange.ubc.ca.
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TOP
ABSTRACT
Introduction
