共查询到20条相似文献,搜索用时 46 毫秒
1.
Mikael K. Schnizler Katrin Schnizler Xiang-ming Zha Duane D. Hall John A. Wemmie Johannes W. Hell Michael J. Welsh 《The Journal of biological chemistry》2009,284(5):2697-2705
The acid-sensing ion channel 1a (ASIC1a) is widely expressed in central and
peripheral neurons where it generates transient cation currents when
extracellular pH falls. ASIC1a confers pH-dependent modulation on postsynaptic
dendritic spines and has critical effects in neurological diseases associated
with a reduced pH. However, knowledge of the proteins that interact with
ASIC1a and influence its function is limited. Here, we show that
α-actinin, which links membrane proteins to the actin cytoskeleton,
associates with ASIC1a in brain and in cultured cells. The interaction
depended on an α-actinin-binding site in the ASIC1a C terminus that was
specific for ASIC1a versus other ASICs and for α-actinin-1 and
-4. Co-expressing α-actinin-4 altered ASIC1a current density, pH
sensitivity, desensitization rate, and recovery from desensitization.
Moreover, reducing α-actinin expression altered acid-activated currents
in hippocampal neurons. These findings suggest that α-actinins may link
ASIC1a to a macromolecular complex in the postsynaptic membrane where it
regulates ASIC1a activity.Acid-sensing ion channels
(ASICs)2 are
H+-gated members of the DEG/ENaC family
(1–3).
Members of this family contain cytosolic N and C termini, two transmembrane
domains, and a large cysteine-rich extracellular domain. ASIC subunits combine
as homo- or heterotrimers to form cation channels that are widely expressed in
the central and peripheral nervous systems
(1–4).
In mammals, four genes encode ASICs, and two subunits, ASIC1 and ASIC2, have
two splice forms, a and b. Central nervous system neurons express ASIC1a,
ASIC2a, and ASIC2b
(5–7).
Homomeric ASIC1a channels are activated when extracellular pH drops below 7.2,
and half-maximal activation occurs at pH 6.5–6.8
(8–10).
These channels desensitize in the continued presence of a low extracellular
pH, and they can conduct Ca2+
(9,
11–13).
ASIC1a is required for acid-evoked currents in central nervous system neurons;
disrupting the gene encoding ASIC1a eliminates H+-gated currents
unless extracellular pH is reduced below pH 5.0
(5,
7).Previous studies found ASIC1a enriched in synaptosomal membrane fractions
and present in dendritic spines, the site of excitatory synapses
(5,
14,
15). Consistent with this
localization, ASIC1a null mice manifested deficits in hippocampal
long term potentiation, learning, and memory, which suggested that ASIC1a is
required for normal synaptic plasticity
(5,
16). ASICs might be activated
during neurotransmission when synaptic vesicles empty their acidic contents
into the synaptic cleft or when neuronal activity lowers extracellular pH
(17–19).
Ion channels, including those at the synapse often interact with multiple
proteins in a macromolecular complex that incorporates regulators of their
function (20,
21). For ASIC1a, only a few
interacting proteins have been identified. Earlier work indicated that ASIC1a
interacts with another postsynaptic scaffolding protein, PICK1
(15,
22,
23). ASIC1a also has been
reported to interact with annexin II light chain p11 through its cytosolic N
terminus to increase cell surface expression
(24) and with
Ca2+/calmodulin-dependent protein kinase II to phosphorylate the
channel (25). However, whether
ASIC1a interacts with additional proteins and with the cytoskeleton remain
unknown. Moreover, it is not known whether such interactions alter ASIC1a
function.In analyzing the ASIC1a amino acid sequence, we identified cytosolic
residues that might bind α-actinins. α-Actinins cluster membrane
proteins and signaling molecules into macromolecular complexes and link
membrane proteins to the actincytoskeleton (for review, Ref.
26). Four genes encode
α-actinin-1, -2, -3, and -4 isoforms. α-Actinins contain an
N-terminal head domain that binds F-actin, a C-terminal region containing two
EF-hand motifs, and a central rod domain containing four spectrin-like motifs
(26–28).
The C-terminal portion of the rod segment appears to be crucial for binding to
membrane proteins. The α-actinins assemble into antiparallel homodimers
through interactions in their rod domain. α-Actinins-1, -2, and -4 are
enriched in dendritic spines, concentrating at the postsynaptic membrane
(29–35).
In the postsynaptic membrane of excitatory synapses, α-actinin connects
the NMDA receptor to the actin cytoskeleton, and this interaction is key for
Ca2+-dependent inhibition of NMDA receptors
(36–38).
α-Actinins can also regulate the membrane trafficking and function of
several cation channels, including L-type Ca2+ channels,
K+ channels, and TRP channels
(39–41).To better understand the function of ASIC1a channels in macromolecular
complexes, we asked if ASIC1a associates with α-actinins. We were
interested in the α-actinins because they and ASIC1a, both, are present
in dendritic spines, ASIC1a contains a potential α-actinin binding
sequence, and the related epithelial Na+ channel (ENaC) interacts
with the cytoskeleton (42,
43). Therefore, we
hypothesized that α-actinin interacts structurally and functionally with
ASIC1a. 相似文献
2.
3.
Kuen-Feng Chen Pei-Yen Yeh Chiun Hsu Chih-Hung Hsu Yen-Shen Lu Hsing-Pang Hsieh Pei-Jer Chen Ann-Lii Cheng 《The Journal of biological chemistry》2009,284(17):11121-11133
Hepatocellular carcinoma (HCC) is one of the most common and aggressive
human malignancies. Recombinant tumor necrosis factor-related
apoptosis-inducing ligand (TRAIL) is a promising anti-tumor agent. However,
many HCC cells show resistance to TRAIL-induced apoptosis. In this study, we
showed that bortezomib, a proteasome inhibitor, overcame TRAIL resistance in
HCC cells, including Huh-7, Hep3B, and Sk-Hep1. The combination of bortezomib
and TRAIL restored the sensitivity of HCC cells to TRAIL-induced apoptosis.
Comparing the molecular change in HCC cells treated with these agents, we
found that down-regulation of phospho-Akt (P-Akt) played a key role in
mediating TRAIL sensitization of bortezomib. The first evidence was that
bortezomib down-regulated P-Akt in a dose- and time-dependent manner in
TRAIL-treated HCC cells. Second, , a PI3K inhibitor, also sensitized
resistant HCC cells to TRAIL-induced apoptosis. Third, knocking down Akt1 by
small interference RNA also enhanced TRAIL-induced apoptosis in Huh-7 cells.
Finally, ectopic expression of mutant Akt (constitutive active) in HCC cells
abolished TRAIL sensitization effect of bortezomib. Moreover, okadaic acid, a
protein phosphatase 2A (PP2A) inhibitor, reversed down-regulation of P-Akt in
bortezomib-treated cells, and PP2A knockdown by small interference RNA also
reduced apoptosis induced by the combination of TRAIL and bortezomib,
indicating that PP2A may be important in mediating the effect of bortezomib on
TRAIL sensitization. Together, bortezomib overcame TRAIL resistance at
clinically achievable concentrations in hepatocellular carcinoma cells, and
this effect is mediated at least partly via inhibition of the PI3K/Akt
pathway.Hepatocellular carcinoma
(HCC) LY2940022 is currently
the fifth most common solid tumor worldwide and the fourth leading cause of
cancer-related death. To date, surgery is still the only curative treatment
but is only feasible in a small portion of patients
(1). Drug treatment is the
major therapy for patients with advanced stage disease. Unfortunately, the
response rate to traditional chemotherapy for HCC patients is unsatisfactory
(1). Novel pharmacological
therapy is urgently needed for patients with advanced HCC. In this regard, the
approval of sorafenib might open a new era of molecularly targeted therapy in
the treatment of HCC patients.Tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL), a
type II transmembrane protein and a member of the TNF family, is a promising
anti-tumor agent under clinical investigation
(2). TRAIL functions by
engaging its receptors expressed on the surface of target cells. Five
receptors specific for TRAIL have been identified, including DR4/TRAIL-R1,
DR5/TRAIL-R2, DcR1, DcR2, and osteoprotegerin. Among TRAIL receptors, only DR4
and DR5 contain an effective death domain that is essential to formation of
death-inducing signaling complex (DISC), a critical step for TRAIL-induced
apoptosis. Notably, the trimerization of the death domains recruits an adaptor
molecule, Fas-associated protein with death domain (FADD), which subsequently
recruits and activates caspase-8. In type I cells, activation of caspase-8 is
sufficient to activate caspase-3 to induce apoptosis; however, in another type
of cells (type II), the intrinsic mitochondrial pathway is essential for
apoptosis characterized by cleavage of Bid and release of cytochrome
c from mitochondria, which subsequently activates caspase-9 and
caspase-3 (3).Although TRAIL induces apoptosis in malignant cells but sparing normal
cells, some tumor cells are resistant to TRAIL-induced apoptosis. Mechanisms
responsible for the resistance include receptors and intracellular resistance.
Although the cell surface expression of DR4 or DR5 is absolutely required for
TRAIL-induced apoptosis, tumor cells expressing these death receptors are not
always sensitive to TRAIL due to intracellular mechanisms. For example, the
cellular FLICE-inhibitory protein (c-FLIP), a homologue to caspase-8 but
without protease activity, has been linked to TRAIL resistance in several
studies (4,
5). In addition, inactivation
of Bax, a proapoptotic Bcl-2 family protein, resulted in resistance to TRAIL
in MMR-deficient tumors (6,
7), and reintroduction of Bax
into Bax-deficient cells restored TRAIL sensitivity
(8), indicating that the Bcl-2
family plays a critical role in intracellular mechanisms for resistance of
TRAIL.Bortezomib, a proteasome inhibitor approved clinically for multiple myeloma
and mantle cell lymphoma, has been investigated intensively for many types of
cancer (9). Accumulating
studies indicate that the combination of bortezomib and TRAIL overcomes the
resistance to TRAIL in various types of cancer, including acute myeloid
leukemia (4), lymphoma
(10–13),
prostate
(14–17),
colon (15,
18,
19), bladder
(14,
16), renal cell carcinoma
(20), thyroid
(21), ovary
(22), non-small cell lung
(23,
24), sarcoma
(25), and HCC
(26,
27). Molecular targets
responsible for the sensitizing effect of bortezomib on TRAIL-induced cell
death include DR4 (14,
27), DR5
(14,
20,
22–23,
28), c-FLIP
(4,
11,
21–23,
29), NF-κB
(12,
24,
30), p21
(16,
21,
25), and p27
(25). In addition, Bcl-2
family also plays a role in the combinational effect of bortezomib and TRAIL,
including Bcl-2 (10,
21), Bax
(13,
22), Bak
(27), Bcl-xL
(21), Bik
(18), and Bim
(15).Recently, we have reported that Akt signaling is a major molecular
determinant in bortezomib-induced apoptosis in HCC cells
(31). In this study, we
demonstrated that bortezomib overcame TRAIL resistance in HCC cells through
inhibition of the PI3K/Akt pathway. 相似文献
4.
Jacamo R Sinnett-Smith J Rey O Waldron RT Rozengurt E 《The Journal of biological chemistry》2008,283(19):12877-12887
Protein kinase D (PKD) is a serine/threonine protein kinase rapidly
activated by G protein-coupled receptor (GPCR) agonists via a protein kinase C
(PKC)-dependent pathway. Recently, PKD has been implicated in the regulation
of long term cellular activities, but little is known about the mechanism(s)
of sustained PKD activation. Here, we show that cell treatment with the
preferential PKC inhibitors GF 109203X or Gö 6983 blocked rapid
(1–5-min) PKD activation induced by bombesin stimulation, but this
inhibition was greatly diminished at later times of bombesin stimulation
(e.g. 45 min). These results imply that GPCR-induced PKD activation
is mediated by early PKC-dependent and late PKC-independent mechanisms.
Western blot analysis with site-specific antibodies that detect the
phosphorylated state of the activation loop residues Ser744 and
Ser748 revealed striking PKC-independent phosphorylation of
Ser748 as well as Ser744 phosphorylation that remained
predominantly but not completely PKC-dependent at later times of bombesin or
vasopressin stimulation (20–90 min). To determine the mechanisms
involved, we examined activation loop phosphorylation in a set of PKD mutants,
including kinase-deficient, constitutively activated, and PKD forms in which
the activation loop residues were substituted for alanine. Our results show
that PKC-dependent phosphorylation of the activation loop Ser744
and Ser748 is the primary mechanism involved in early phase PKD
activation, whereas PKD autophosphorylation on Ser748 is a major
mechanism contributing to the late phase of PKD activation occurring in cells
stimulated by GPCR agonists. The present studies identify a novel mechanism
induced by GPCR activation that leads to late, PKC-independent PKD
activation.A rapid increase in the synthesis of lipid-derived second messengers with
subsequent activation of protein phosphorylation cascades has emerged as a
fundamental signal transduction mechanism triggered by multiple extracellular
stimuli, including hormones, neurotransmitters, chemokines, and growth factors
(1). Many of these agonists
bind to G protein-coupled receptors
(GPCRs),4 activate
heterotrimeric G proteins and stimulate isoforms of the phospholipase C
family, including β, γ, δ, and ε (reviewed in Refs.
1 and
2). Activated phospholipase Cs
catalyze the hydrolysis of phosphatidylinositol 4,5-bisphosphate to produce
the second messengers inositol 1,4,5-trisphosphate and diacylglycerol (DAG).
Inositol 1,4,5-trisphosphate mobilizes Ca2+ from intracellular
stores (3,
4) whereas DAG directly
activates the classic (α, β, and γ) and novel (δ,
ε, η, and θ) isoforms of PKC
(5–7).
Although it is increasingly recognized that each PKC isozyme has specific
functions in vivo
(5–8),
the mechanisms by which PKC-mediated signals are propagated to critical
downstream targets remain incompletely defined.PKD, also known initially as PKCμ
(9,
10), and two recently
identified serine protein kinases termed PKD2
(11) and PKCν/PKD3
(12,
13), which are similar in
overall structure and primary amino acid sequence to PKD
(14), constitute a new protein
kinase family within the Ca2+/calmodulin-dependent protein kinase
group (15) and separate from
the previously identified PKCs
(14). Salient features of PKD
structure include an N-terminal regulatory region containing a tandem repeat
of cysteine-rich zinc finger-like motifs (termed the cysteine-rich domain)
that confers high affinity binding to phorbol esters and DAG
(9,
16,
17), followed by a pleckstrin
homology (PH) domain that negatively regulates catalytic activity
(18,
19). The C-terminal region of
the PKDs contains its catalytic domain, which is distantly related to
Ca2+-regulated kinases.In unstimulated cells, PKD is in a state of low kinase catalytic activity
maintained by the N-terminal domain, which represses the catalytic activity of
the enzyme by autoinhibition. Consistent with this model, deletions or single
amino acid substitutions in the PH domain result in constitutive kinase
activity
(18–20).
Physiological activation of PKD within cells occurs via a
phosphorylation-dependent mechanism first identified in our laboratory
(21). In response to cellular
stimuli, PKD is converted from a low activity form into a persistently active
form that is retained during isolation from cells, as shown by in
vitro kinase assays performed in the absence of lipid co-activators
(21,
22). PKD activation has been
demonstrated in response to engagement of specific GPCRs either by regulatory
peptides
(23–30)
or lysophosphatidic acid (27,
31,
32); signaling through
Gq, G12, Gi, and Rho
(27,
31–34);
activation of receptor tyrosine kinases, such as the platelet-derived growth
factor receptor (23,
35,
36); cross-linking of B-cell
receptor and T-cell receptor in B and T lymphocytes, respectively
(37–40);
and oxidative stress
(41–44).Throughout these studies, multiple lines of evidence indicated that PKC
activity is necessary for rapid PKD activation within intact cells. For
example, rapid PKD activation was selectively and potently blocked by cell
treatment with preferential PKC inhibitors (e.g. GF 109203X or
Gö 6983) that do not directly inhibit PKD catalytic activity
(21,
22), implying that PKD
activation in intact cells is mediated, directly or indirectly, through PKCs.
In line with this conclusion, cotransfection of PKD with active mutant forms
of “novel” PKCs (PKCs δ, ε, η, and θ)
resulted in robust PKD activation in the absence of cell stimulation
(21,
44–46).
Many reports demonstrated the operation of a rapid PKC/PKD signaling cascade
in response to multiple GPCR agonists in a broad range of cell types,
including normal and cancer cells (reviewed in Ref.
14). Our previous studies
identified Ser744 and Ser748 in the PKD activation loop
(also referred as the activation segment or T-loop) as phosphorylation sites
critical for PKC-mediated PKD activation (reviewed in Ref.
14). Collectively, these
findings demonstrated the existence of rapidly activated PKC-PKD protein
kinase cascade(s) and raised the possibility that some PKC-dependent
biological responses involve PKD acting as a downstream effector.PKD has been reported recently to mediate several important cellular
activities and processes, including signal transduction
(30,
47–49),
chromatin modification (50),
Golgi organization and function
(51,
52), c-Jun function
(47,
53,
54), NFκB-mediated gene
expression (43,
55,
56), and cell survival,
migration, and differentiation and DNA synthesis and proliferation (reviewed
in Ref. 14). Thus, mounting
evidence indicates that PKD has a remarkable diversity of both its signal
generation and distribution and its potential for complex regulatory
interactions with multiple downstream pathways, leading to multiple responses,
including long term cellular events. Despite increasing recognition of its
importance, very little is known about the mechanism(s) of sustained PKD
activation as opposed to the well documented rapid, PKC-dependent PKD
activation.The results presented here demonstrate that prolonged GPCR-induced PKD
activation is mediated by sequential PKC-dependent and PKC-independent phases
of regulation. We report here, for the first time, that PKD
autophosphorylation on Ser748 is a major mechanism contributing to
the late phase of PKD activation occurring in cells stimulated by GPCR
agonists. The present studies expand previous models of PKD regulation by
identifying a novel mechanism induced by GPCR activation that leads to late,
PKC-independent PKD activation. 相似文献
5.
Eun-Yeong Bergsdorf Anselm A. Zdebik Thomas J. Jentsch 《The Journal of biological chemistry》2009,284(17):11184-11193
Members of the CLC gene family either function as chloride channels or as
anion/proton exchangers. The plant AtClC-a uses the pH gradient across the
vacuolar membrane to accumulate the nutrient
in this organelle. When AtClC-a was
expressed in Xenopus oocytes, it mediated
exchange
and less efficiently mediated Cl–/H+ exchange.
Mutating the “gating glutamate” Glu-203 to alanine resulted in an
uncoupled anion conductance that was larger for Cl– than
. Replacing the “proton
glutamate” Glu-270 by alanine abolished currents. These could be
restored by the uncoupling E203A mutation. Whereas mammalian endosomal ClC-4
and ClC-5 mediate stoichiometrically coupled
2Cl–/H+ exchange, their
transport is largely uncoupled from
protons. By contrast, the AtClC-a-mediated
accumulation in plant vacuoles
requires tight
coupling. Comparison of AtClC-a and ClC-5 sequences identified a proline in
AtClC-a that is replaced by serine in all mammalian CLC isoforms. When this
proline was mutated to serine (P160S), Cl–/H+
exchange of AtClC-a proceeded as efficiently as
exchange, suggesting a role of this residue in
exchange. Indeed, when the corresponding serine of ClC-5 was replaced by
proline, this Cl–/H+ exchanger gained efficient
coupling. When inserted into the model Torpedo chloride channel
ClC-0, the equivalent mutation increased nitrate relative to chloride
conductance. Hence, proline in the CLC pore signature sequence is important
for
exchange and conductance both in
plants and mammals. Gating and proton glutamates play similar roles in
bacterial, plant, and mammalian CLC anion/proton exchangers.CLC proteins are found in all phyla from bacteria to humans and either
mediate electrogenic anion/proton exchange or function as chloride channels
(1). In mammals, the roles of
plasma membrane CLC Cl– channels include transepithelial
transport
(2–5)
and control of muscle excitability
(6), whereas vesicular CLC
exchangers may facilitate endocytosis
(7) and lysosomal function
(8–10)
by electrically shunting vesicular proton pump currents
(11). In the plant
Arabidopsis thaliana, there are seven CLC isoforms
(AtClC-a–AtClC-g)2
(12–15),
which may mostly reside in intracellular membranes. AtClC-a uses the pH
gradient across the vacuolar membrane to transport the nutrient nitrate into
that organelle (16). This
secondary active transport requires a tightly coupled
exchange. Astonishingly, however, mammalian ClC-4 and -5 and bacterial EcClC-1
(one of the two CLC isoforms in Escherichia coli) display tightly
coupled Cl–/H+ exchange, but anion flux is largely
uncoupled from H+ when
is transported
(17–21).
The lack of appropriate expression systems for plant CLC transporters
(12) has so far impeded
structure-function analysis that may shed light on the ability of AtClC-a to
perform efficient
exchange. This dearth of data contrasts with the extensive mutagenesis work
performed with CLC proteins from animals and bacteria.The crystal structure of bacterial CLC homologues
(22,
23) and the investigation of
mutants (17,
19–21,
24–29)
have yielded important insights into their structure and function. CLC
proteins form dimers with two largely independent permeation pathways
(22,
25,
30,
31). Each of the monomers
displays two anion binding sites
(22). A third binding site is
observed when a certain key glutamate residue, which is located halfway in the
permeation pathway of almost all CLC proteins, is mutated to alanine
(23). Mutating this gating
glutamate in CLC Cl– channels strongly affects or even
completely suppresses single pore gating
(23), whereas CLC exchangers
are transformed by such mutations into pure anion conductances that are not
coupled to proton transport
(17,
19,
20). Another key glutamate,
located at the cytoplasmic surface of the CLC monomer, seems to be a hallmark
of CLC anion/proton exchangers. Mutating this proton glutamate to
nontitratable amino acids uncouples anion transport from protons in the
bacterial EcClC-1 protein (27)
but seems to abolish transport altogether in mammalian ClC-4 and -5
(21). In those latter
proteins, anion transport could be restored by additionally introducing an
uncoupling mutation at the gating glutamate
(21).The functional complementation by AtClC-c and -d
(12,
32) of growth phenotypes of a
yeast strain deleted for the single yeast CLC Gef1
(33) suggested that these
plant CLC proteins function in anion transport but could not reveal details of
their biophysical properties. We report here the first functional expression
of a plant CLC in animal cells. Expression of wild-type (WT) and mutant
AtClC-a in Xenopus oocytes indicate a general role of gating and
proton glutamate residues in anion/proton coupling across different isoforms
and species. We identified a proline in the CLC signature sequence of AtClC-a
that plays a crucial role in
exchange. Mutating it to serine, the residue present in mammalian CLC proteins
at this position, rendered AtClC-a Cl–/H+ exchange
as efficient as
exchange. Conversely, changing the corresponding serine of ClC-5 to proline
converted it into an efficient
exchanger. When proline replaced the critical serine in Torpedo
ClC-0, the relative conductance of
this model Cl– channel was drastically increased, and
“fast” protopore gating was slowed. 相似文献
6.
Ruben K. Dagda Salvatore J. Cherra III Scott M. Kulich Anurag Tandon David Park Charleen T. Chu 《The Journal of biological chemistry》2009,284(20):13843-13855
Mitochondrial dysregulation is strongly implicated in Parkinson disease.
Mutations in PTEN-induced kinase 1 (PINK1) are associated with familial
parkinsonism and neuropsychiatric disorders. Although overexpressed PINK1 is
neuroprotective, less is known about neuronal responses to loss of PINK1
function. We found that stable knockdown of PINK1 induced mitochondrial
fragmentation and autophagy in SH-SY5Y cells, which was reversed by the
reintroduction of an RNA interference (RNAi)-resistant plasmid for PINK1.
Moreover, stable or transient overexpression of wild-type PINK1 increased
mitochondrial interconnectivity and suppressed toxin-induced
autophagy/mitophagy. Mitochondrial oxidant production played an essential role
in triggering mitochondrial fragmentation and autophagy in PINK1 shRNA lines.
Autophagy/mitophagy served a protective role in limiting cell death, and
overexpressing Parkin further enhanced this protective mitophagic response.
The dominant negative Drp1 mutant inhibited both fission and mitophagy in
PINK1-deficient cells. Interestingly, RNAi knockdown of autophagy proteins
Atg7 and LC3/Atg8 also decreased mitochondrial fragmentation without affecting
oxidative stress, suggesting active involvement of autophagy in morphologic
remodeling of mitochondria for clearance. To summarize, loss of PINK1 function
elicits oxidative stress and mitochondrial turnover coordinated by the
autophagic and fission/fusion machineries. Furthermore, PINK1 and Parkin may
cooperate through different mechanisms to maintain mitochondrial
homeostasis.Parkinson disease is an age-related neurodegenerative disease that affects
∼1% of the population worldwide. The causes of sporadic cases are unknown,
although mitochondrial or oxidative toxins such as
1-methyl-4-phenylpyridinium, 6-hydroxydopamine
(6-OHDA),3 and
rotenone reproduce features of the disease in animal and cell culture models
(1). Abnormalities in
mitochondrial respiration and increased oxidative stress are observed in cells
and tissues from parkinsonian patients
(2,
3), which also exhibit
increased mitochondrial autophagy
(4). Furthermore, mutations in
parkinsonian genes affect oxidative stress response pathways and mitochondrial
homeostasis (5). Thus,
disruption of mitochondrial homeostasis represents a major factor implicated
in the pathogenesis of sporadic and inherited parkinsonian disorders (PD).The PARK6 locus involved in autosomal recessive and early-onset PD
encodes for PTEN-induced kinase 1 (PINK1)
(6,
7). PINK1 is a cytosolic and
mitochondrially localized 581-amino acid serine/threonine kinase that
possesses an N-terminal mitochondrial targeting sequence
(6,
8). The primary sequence also
includes a putative transmembrane domain important for orientation of the
PINK1 domain (8), a conserved
kinase domain homologous to calcium calmodulin kinases, and a C-terminal
domain that regulates autophosphorylation activity
(9,
10). Overexpression of
wild-type PINK1, but not its PD-associated mutants, protects against several
toxic insults in neuronal cells
(6,
11,
12). Mitochondrial targeting
is necessary for some (13) but
not all of the neuroprotective effects of PINK1
(14), implicating involvement
of cytoplasmic targets that modulate mitochondrial pathobiology
(8). PINK1 catalytic activity
is necessary for its neuroprotective role, because a kinase-deficient K219M
substitution in the ATP binding pocket of PINK1 abrogates its ability to
protect neurons (14). Although
PINK1 mutations do not seem to impair mitochondrial targeting, PD-associated
mutations differentially destabilize the protein, resulting in loss of
neuroprotective activities
(13,
15).Recent studies indicate that PINK1 and Parkin interact genetically
(3,
16-18)
to prevent oxidative stress
(19,
20) and regulate mitochondrial
morphology (21). Primary cells
derived from PINK1 mutant patients exhibit mitochondrial fragmentation with
disorganized cristae, recapitulated by RNA interference studies in HeLa cells
(3).Mitochondria are degraded by macroautophagy, a process involving
sequestration of cytoplasmic cargo into membranous autophagic vacuoles (AVs)
for delivery to lysosomes (22,
23). Interestingly,
mitochondrial fission accompanies autophagic neurodegeneration elicited by the
PD neurotoxin 6-OHDA (24,
25). Moreover, mitochondrial
fragmentation and increased autophagy are observed in neurodegenerative
diseases including Alzheimer and Parkinson diseases
(4,
26-28).
Although inclusion of mitochondria in autophagosomes was once believed to be a
random process, as observed during starvation, studies involving hypoxia,
mitochondrial damage, apoptotic stimuli, or limiting amounts of aerobic
substrates in facultative anaerobes support the concept of selective
mitochondrial autophagy (mitophagy)
(29,
30). In particular,
mitochondrially localized kinases may play an important role in models
involving oxidative mitochondrial injury
(25,
31,
32).Autophagy is involved in the clearance of protein aggregates
(33-35)
and normal regulation of axonal-synaptic morphology
(36). Chronic disruption of
lysosomal function results in accumulation of subtly impaired mitochondria
with decreased calcium buffering capacity
(37), implicating an important
role for autophagy in mitochondrial homeostasis
(37,
38). Recently, Parkin, which
complements the effects of PINK1 deficiency on mitochondrial morphology
(3), was found to promote
autophagy of depolarized mitochondria
(39). Conversely, Beclin
1-independent autophagy/mitophagy contributes to cell death elicited by the PD
toxins 1-methyl-4-phenylpyridinium and 6-OHDA
(25,
28,
31,
32), causing neurite
retraction in cells expressing a PD-linked mutation in leucine-rich repeat
kinase 2 (40). Whereas
properly regulated autophagy plays a homeostatic and neuroprotective role,
excessive or incomplete autophagy creates a condition of “autophagic
stress” that can contribute to neurodegeneration
(28).As mitochondrial fragmentation
(3) and increased mitochondrial
autophagy (4) have been
described in human cells or tissues of PD patients, we investigated whether or
not the engineered loss of PINK1 function could recapitulate these
observations in human neuronal cells (SH-SY5Y). Stable knockdown of endogenous
PINK1 gave rise to mitochondrial fragmentation and increased autophagy and
mitophagy, whereas stable or transient overexpression of PINK1 had the
opposite effect. Autophagy/mitophagy was dependent upon increased
mitochondrial oxidant production and activation of fission. The data indicate
that PINK1 is important for the maintenance of mitochondrial networks,
suggesting that coordinated regulation of mitochondrial dynamics and autophagy
limits cell death associated with loss of PINK1 function. 相似文献
7.
8.
Kristina Oresic Caroline L. Ng Domenico Tortorella 《The Journal of biological chemistry》2009,284(9):5905-5914
The human cytomegalovirus proteins US2 and US11 have co-opted endoplasmic
reticulum (ER) quality control to facilitate the destruction of major
histocompatibility complex class I heavy chains. The class I heavy chains are
dislocated from the ER to the cytosol, where they are deglycosylated and
subsequently degraded by the proteasome. We examined the role of TRAM1
(translocating chain-associated membrane protein-1) in the dislocation of
class I molecules using US2- and US11-expressing cells. TRAM1 is an ER protein
initially characterized for its role in processing nascent polypeptides.
Co-immunoprecipitation studies demonstrated that TRAM1 can complex with the
wild type US2 and US11 proteins as well as deglycosylated and
polyubiquitinated class I degradation intermediates. In studies using US2- and
US11-TRAM1 knockdown cells, we observed an increase in levels of class I heavy
chains. Strikingly, increased levels of glycosylated heavy chains were
observed in TRAM1 knockdown cells when compared with control cells in a
pulse-chase experiment. In fact, US11-mediated class I dislocation was more
sensitive to the lack of TRAM1 than US2. These results provide further
evidence that these viral proteins may utilize distinct complexes to
facilitate class I dislocation. For example, US11-mediated class I heavy chain
degradation requires Derlin-1 and SEL1L, whereas signal peptide peptidase is
critical for US2-induced class I destabilization. In addition, TRAM1 can
complex with the dislocation factors Derlin-1 and signal peptide peptidase.
Collectively, the data support a model in which TRAM1 functions as a cofactor
to promote efficient US2- and US11-dependent dislocation of major
histocompatibility complex class I heavy chains.HCMV2 can
down-regulate cell surface expression of the immunologically important
molecule major histocompatibility complex class I to avoid immune detection by
cytotoxic T cells (1,
2). More specifically, the HCMV
US2 and US11 gene products alone can target the ER-localized major
histocompatibility complex class I heavy chains for extraction across the ER
membrane by a process referred to as dislocation or retrograde translocation.
The N-linked glycan is then removed upon exposure to the cytosol by
N-glycanase (3),
followed by proteasomal destruction
(4,
5). The HCMV US2 and US11
proteins utilize the ER quality control process to eliminate class I heavy
cells in a similar manner as misfolded or damaged ER proteins (e.g.
genetic mutants of α1-antitrypsin
(6) and the cystic fibrosis
transmembrane conductance regulator protein
(7)) are targeted for
degradation (8). Hence,
analysis of US2- and US11-mediated destruction of class I heavy chains
provides an excellent system to delineate viral protein function as well as
the ER quality control process.ER and cytosolic proteins are required for US2- and US11-mediated
dislocation/degradation of class I heavy chains. Some of these proteins have
also been identified in the processing of aberrant ER polypeptides. The ER
chaperones calnexin, calreticulin, and BiP have been implicated in
US2-mediated class I destruction
(9) as well as in the removal
of some misfolded ER proteins
(10). The ubiquitination
machinery also participates in the extraction of class I heavy chains as
ubiquitinated heavy chains are observed prior to dislocation
(11,
12). For misfolded ER
degradation substrates, ubiquitin conjugation enzymes (e.g. Ubc6p and
Ubc7p/Cue1p) and ubiquitin ligases Hrd1p/Der3p, Doa10p, and Ubc1p have been
implicated in the dislocation reaction
(8). Interestingly, the ER
membrane protein Derlin-1 along with SEL1L are involved in US11-mediated class
I heavy chain degradation
(13-15),
whereas SPP is critical for US2-induced class I destabilization
(16). The ubiquitinated
substrates are dislocated by the AAA-ATPase complex composed of p97-Ufd1-Npl4
(17) while docked to the ER
through its interaction with VIMP
(14) followed by proteasome
destruction. The inhibition of the proteasome causes the accumulation of
deglycosylated class I heavy chain intermediate in US2 and US11 cells,
allowing the dislocation and degradation reactions to be studied as separate
processes (4,
5).Despite the identification of some cellular proteins that assist US2- and
US11-mediated class I dislocation, the dislocation pore and accessory factors
that mediate the efficient extraction of class I through the bilayer have yet
to be completely defined. The current study explores the role of TRAM1
(translocating chain-associated membrane protein-1) in US2- and US11-mediated
class I dislocation. TRAM1 is an ER-resident multispanning membrane protein
that can mediate the lateral movement of select signal peptides and
transmembrane segments from the translocon into the membrane bilayer
(18), a property that makes it
uniquely qualified to participate in the dislocation of a membrane protein.
TRAM1 has been cross-linked to signal peptides as well as transmembrane
domains of nascent polypeptides during the early stages of protein processing
(19-25).
Interestingly, unlike the Sec61 complex and the signal recognition particle
receptor, TRAM1 is not essential for the translocation of all membrane
proteins into the ER (20,
21). Hence, TRAM1 may utilize
its ability to engage hydrophobic domains to assist in the efficient
dislocation of membrane proteins. In fact, association and TRAM1 knockdown
studies demonstrate that TRAM1 participates in US2- and US11-mediated
dislocation of class I heavy chains. Collectively, our data suggest for the
first time that TRAM1 plays a role in the dislocation of a membrane
glycoprotein. 相似文献
9.
Lilly Y. W. Bourguignon Weiliang Xia Gabriel Wong 《The Journal of biological chemistry》2009,284(5):2657-2671
10.
11.
As obligate intracellular parasites, viruses exploit diverse cellular
signaling machineries, including the mitogen-activated protein-kinase pathway,
during their infections. We have demonstrated previously that the open reading
frame 45 (ORF45) of Kaposi sarcoma-associated herpesvirus interacts with p90
ribosomal S6 kinases (RSKs) and strongly stimulates their kinase activities
(Kuang, E., Tang, Q., Maul, G. G., and Zhu, F.
(2008) J. Virol. 82
,1838
-1850). Here, we define the
mechanism by which ORF45 activates RSKs. We demonstrated that binding of ORF45
to RSK increases the association of extracellular signal-regulated kinase
(ERK) with RSK, such that ORF45, RSK, and ERK formed high molecular mass
protein complexes. We further demonstrated that the complexes shielded active
pERK and pRSK from dephosphorylation. As a result, the complex-associated RSK
and ERK were activated and sustained at high levels. Finally, we provide
evidence that this mechanism contributes to the sustained activation of ERK
and RSK in Kaposi sarcoma-associated herpesvirus lytic replication.The extracellular signal-regulated kinase
(ERK)2
mitogen-activated protein kinase (MAPK) signaling pathway has been implicated
in diverse cellular physiological processes including proliferation, survival,
growth, differentiation, and motility
(1-4)
and is also exploited by a variety of viruses such as Kaposi
sarcoma-associated herpesvirus (KSHV), human cytomegalovirus, human
immunodeficiency virus, respiratory syncytial virus, hepatitis B virus,
coxsackie, vaccinia, coronavirus, and influenza virus
(5-17).
The MAPK kinases relay the extracellular signaling through sequential
phosphorylation to an array of cytoplasmic and nuclear substrates to elicit
specific responses (1,
2,
18). Phosphorylation of MAPK
is reversible. The kinetics of deactivation or duration of signaling dictates
diverse biological outcomes
(19,
20). For example, sustained
but not transient activation of ERK signaling induces the differentiation of
PC12 cells into sympathetic-like neurons and transformation of NIH3T3 cells
(20-22).
During viral infection, a unique biphasic ERK activation has been observed for
some viruses (an early transient activation triggered by viral binding or
entry and a late sustained activation correlated with viral gene expression),
but the responsible viral factors and underlying mechanism for the sustained
ERK activation remain largely unknown
(5,
8,
13,
23).The p90 ribosomal S6 kinases (RSKs) are a family of serine/threonine
kinases that lie at the terminus of the ERK pathway
(1,
24-26).
In mammals, four isoforms are known, RSK1 to RSK4. Each one has two
catalytically functional kinase domains, the N-terminal kinase domain (NTKD)
and C-terminal kinase domain (CTKD) as well as a linker region between the
two. The NTKD is responsible for phosphorylation of exogenous substrates, and
the CTKD and linker region regulate RSK activation
(1,
24,
25). In quiescent cells ERK
binds to the docking site in the C terminus of RSK
(27-29).
Upon mitogen stimulation, ERK is activated by its upstream MAPK/ERK kinase
(MEK). The active ERK phosphorylates Thr-359/Ser-363 of RSK in the linker
region (amino acid numbers refer to human RSK1) and Thr-573 in the CTKD
activation loop. The activated CTKD then phosphorylates Ser-380 in the linker
region, creating a docking site for 3-phosphoinositide-dependent protein
kinase-1. The 3-phosphoinositide-dependent protein kinase-1 phosphorylates
Ser-221 of RSK in the activation loop and activates the NTKD. The activated
NTKD autophosphorylates the serine residue near the ERK docking site, causing
a transient dissociation of active ERK from RSK
(25,
26,
28). The stimulation of
quiescent cells by a mitogen such as epidermal growth factor or a phorbol
ester such as 12-O-tetradecanoylphorbol-13-acetate (TPA) usually
results in a transient RSK activation that lasts less than 30 min. RSKs have
been implicated in regulating cell survival, growth, and proliferation.
Mutation or aberrant expression of RSK has been implicated in several human
diseases including Coffin-Lowry syndrome and prostate and breast cancers
(1,
24,
25,
30-32).KSHV is a human DNA tumor virus etiologically linked to Kaposi sarcoma,
primary effusion lymphoma, and a subset of multicentric Castleman disease
(33,
34). Infection and
reactivation of KSHV activate multiple MAPK pathways
(6,
12,
35). Noticeably, the ERK/RSK
activation is sustained late during KSHV primary infection and reactivation
from latency (5,
6,
12,
23), but the mechanism of the
sustained ERK/RSK activation is unclear. Recently, we demonstrated that ORF45,
an immediate early and also virion tegument protein of KSHV, interacts with
RSK1 and RSK2 and strongly stimulates their kinase activities
(23). We also demonstrated
that the activation of RSK plays an essential role in KSHV lytic replication
(23). In the present study we
determined the mechanism of ORF45-induced sustained ERK/RSK activation. We
found that ORF45 increases the association of RSK with ERK and protects them
from dephosphorylation, causing sustained activation of both ERK and RSK. 相似文献
12.
13.
14.
15.
Maika Deffieu Ingrid Bhatia-Ki??ová Bénédicte Salin Anne Galinier Stéphen Manon Nadine Camougrand 《The Journal of biological chemistry》2009,284(22):14828-14837
The antioxidant N-acetyl-l-cysteine prevented the
autophagy-dependent delivery of mitochondria to the vacuoles, as examined by
fluorescence microscopy of mitochondria-targeted green fluorescent protein,
transmission electron microscopy, and Western blot analysis of mitochondrial
proteins. The effect of N-acetyl-l-cysteine was specific
to mitochondrial autophagy (mitophagy). Indeed, autophagy-dependent activation
of alkaline phosphatase and the presence of hallmarks of non-selective
microautophagy were not altered by N-acetyl-l-cysteine.
The effect of N-acetyl-l-cysteine was not related to its
scavenging properties, but rather to its fueling effect of the glutathione
pool. As a matter of fact, the decrease of the glutathione pool induced by
chemical or genetical manipulation did stimulate mitophagy but not general
autophagy. Conversely, the addition of a cell-permeable form of glutathione
inhibited mitophagy. Inhibition of glutathione synthesis had no effect in the
strain Δuth1, which is deficient in selective mitochondrial
degradation. These data show that mitophagy can be regulated independently of
general autophagy, and that its implementation may depend on the cellular
redox status.Autophagy is a major pathway for the lysosomal/vacuolar delivery of
long-lived proteins and organelles, where they are degraded and recycled.
Autophagy plays a crucial role in differentiation and cellular response to
stress and is conserved in eukaryotic cells from yeast to mammals
(1,
2). The main form of autophagy,
macroautophagy, involves the non-selective sequestration of large portions of
the cytoplasm into double-membrane structures termed autophagosomes, and their
delivery to the vacuole/lysosome for degradation. Another process,
microautophagy, involves the direct sequestration of parts of the cytoplasm by
vacuole/lysosomes. The two processes coexist in yeast cells but their extent
may depend on different factors including metabolic state: for example, we
have observed that nitrogen-starved lactate-grown yeast cells develop
microautophagy, whereas nitrogen-starved glucose-grown cells preferentially
develop macroautophagy (3).Both macroautophagy and microautophagy are essentially non-selective, in
the way that autophagosomes and vacuole invaginations do not appear to
discriminate the sequestered material. However, selective forms of autophagy
have been observed (4) that
target namely peroxisomes (5,
6), chromatin
(7,
8), endoplasmic reticulum
(9), ribosomes
(10), and mitochondria
(3,
11–13).
Although non-selective autophagy plays an essential role in survival by
nitrogen starvation, by providing amino acids to the cell, selective autophagy
is more likely to have a function in the maintenance of cellular structures,
both under normal conditions as a “housecleaning” process, and
under stress conditions by eliminating altered organelles and macromolecular
structures
(14–16).
Selective autophagy targeting mitochondria, termed mitophagy, may be
particularly relevant to stress conditions. The mitochondrial respiratory
chain is both the main site and target of
ROS4 production
(17). Consequently, the
maintenance of a pool of healthy mitochondria is a crucial challenge for the
cells. The progressive accumulation of altered mitochondria
(18) caused by the loss of
efficiency of the maintenance process (degradation/biogenesis de
novo) is often considered as a major cause of cellular aging
(19–23).
In mammalian cells, autophagic removal of mitochondria has been shown to be
triggered following induction/blockade of apoptosis
(23), suggesting that
autophagy of mitochondria was required for cell survival following
mitochondria injury (14).
Consistent with this idea, a direct alteration of mitochondrial permeability
properties has been shown to induce mitochondrial autophagy
(13,
24,
25). Furthermore, inactivation
of catalase induced the autophagic elimination of altered mitochondria
(26). In the yeast
Saccharomyces cerevisiae, the alteration of
F0F1-ATPase biogenesis in a conditional mutant has been
shown to trigger autophagy
(27). Alterations of
mitochondrial ion homeostasis caused by the inactivation of the
K+/H+ exchanger was shown to cause both autophagy and
mitophagy (28). We have
reported that treatment of cells with rapamycin induced early ROS production
and mitochondrial lipid oxidation that could be inhibited by the hydrophobic
antioxidant resveratrol (29).
Furthermore, resveratrol treatment impaired autophagic degradation of both
cytosolic and mitochondrial proteins and delayed rapamycin-induced cell death,
suggesting that mitochondrial oxidation events may play a crucial role in the
regulation of autophagy. This existence of regulation of autophagy by ROS has
received molecular support in HeLa cells
(30): these authors showed
that starvation stimulated ROS production, namely H2O2,
which was essential for autophagy. Furthermore, they identified the cysteine
protease hsAtg4 as a direct target for oxidation by
H2O2. This provided a possible connection between the
mitochondrial status and regulation of autophagy.Investigations of mitochondrial autophagy in nitrogen-starved lactate-grown
yeast cells have established the existence of two distinct processes: the
first one occurring very early, is selective for mitochondria and is dependent
on the presence of the mitochondrial protein Uth1p; the second one occurring
later, is not selective for mitochondria, is not dependent on Uth1p, and is a
form of bulk microautophagy
(3). The absence of the
selective process in the Δuth1 mutant strongly delays and
decreases mitochondrial protein degradation
(3,
12). The putative protein
phosphatase Aup1p has been also shown to be essential in inducing mitophagy
(31). Additionally several Atg
proteins were shown to be involved in vacuolar sequestration of mitochondrial
GFP (3,
12,
32,
33). Recently, the protein
Atg11p, which had been already identified as an essential protein for
selective autophagy has also been reported as being essential for mitophagy
(33).The question remains as to identify of the signals that trigger selective
mitophagy. It is particularly intriguing that selective mitophagy is activated
very early after the shift to a nitrogen-deprived medium
(3). Furthermore, selective
mitophagy is very active on lactate-grown cells (with fully differentiated
mitochondria) but is nearly absent in glucose-grown cells
(3). In the present paper, we
investigated the relationships between the redox status of the cells and
selective mitophagy, namely by manipulating glutathione. Our results support
the view that redox imbalance is a trigger for the selective elimination of
mitochondria. 相似文献
16.
Christian Rosker Gargi Meur Emily J. A. Taylor Colin W. Taylor 《The Journal of biological chemistry》2009,284(8):5186-5194
Ryanodine receptors (RyR) are Ca2+ channels that mediate
Ca2+ release from intracellular stores in response to diverse
intracellular signals. In RINm5F insulinoma cells, caffeine, and
4-chloro-m-cresol (4CmC), agonists of RyR, stimulated Ca2+
entry that was independent of store-operated Ca2+ entry, and
blocked by prior incubation with a concentration of ryanodine that inactivates
RyR. Patch-clamp recording identified small numbers of large-conductance
(γK = 169 pS) cation channels that were activated by
caffeine, 4CmC or low concentrations of ryanodine. Similar channels were
detected in rat pancreatic β-cells. In RINm5F cells, the channels were
blocked by cytosolic, but not extracellular, ruthenium red. Subcellular
fractionation showed that type 3 IP3 receptors (IP3R3)
were expressed predominantly in endoplasmic reticulum, whereas RyR2 were
present also in plasma membrane fractions. Using RNAi selectively to reduce
expression of RyR1, RyR2, or IP3R3, we showed that RyR2 mediates
both the Ca2+ entry and the plasma membrane currents evoked by
agonists of RyR. We conclude that small numbers of RyR2 are selectively
expressed in the plasma membrane of RINm5F pancreatic β-cells, where they
mediate Ca2+ entry.Ryanodine receptors
(RyR)3 and inositol
1,4,5-trisphosphate receptors (IP3R)
(1,
2) are the archetypal
intracellular Ca2+ channels. Both are widely expressed, although
RyR are more restricted in their expression than IP3R
(3,
4). In common with many cells,
pancreatic β-cells and insulin-secreting cell lines express both
IP3R (predominantly IP3R3)
(5,
6) and RyR (predominantly RyR2)
(7). Both RyR and
IP3R are expressed mostly within membranes of the endoplasmic (ER),
where they mediate release of Ca2+. Functional RyR are also
expressed in the secretory vesicles
(8,
9) or, and perhaps more likely,
in the endosomes of β-cells
(10). Despite earlier
suggestions (11),
IP3R are probably not present in the secretory vesicles of
β-cells (8,
12,
13).All three subtypes of IP3R are stimulated by IP3 with
Ca2+ (1), and the
three subtypes of RyR are each directly regulated by Ca2+. However,
RyR differ in whether their most important physiological stimulus is
depolarization of the plasma membrane (RyR1), Ca2+ (RyR2) or
additional intracellular messengers like cyclic ADP-ribose. The latter
stimulates both Ca2+ release and insulin secretion in β-cells
(8,
14). The activities of both
families of intracellular Ca2+ channels are also modulated by many
additional signals that act directly or via phosphorylation
(15,
16). Although they commonly
mediate release of Ca2+ from the ER, both IP3R and RyR
select rather poorly between Ca2+ and other cations (permeability
ratio, PCa/PK ∼7)
(1,
17). This may allow
electrogenic Ca2+ release from the ER to be rapidly compensated by
uptake of K+ (18),
and where RyR or IP3R are expressed in other membranes it may allow
them to affect membrane potential.Both Ca2+ entry and release of Ca2+ from
intracellular stores contribute to the oscillatory increases in cytosolic
Ca2+ concentration ([Ca2+]i) that
stimulate exocytosis of insulin-containing vesicles in pancreatic β-cells
(7). Glucose rapidly
equilibrates across the plasma membrane (PM) of β-cells and its oxidative
metabolism by mitochondria increases the cytosolic ATP/ADP ratio, causing
KATP channels to close
(19). This allows an
unidentified leak current to depolarize the PM
(20) and activate
voltage-gated Ca2+ channels, predominantly L-type Ca2+
channels (21). The resulting
Ca2+ entry is amplified by Ca2+-induced Ca2+
release from intracellular stores
(7), triggering exocytotic
release of insulin-containing dense-core vesicles
(22). The importance of this
sequence is clear from the widespread use of sulfonylurea drugs, which close
KATP channels, in the treatment of type 2 diabetes. Ca2+
uptake by mitochondria beneath the PM further stimulates ATP production,
amplifying the initial response to glucose and perhaps thereby contributing to
the sustained phase of insulin release
(23). However, neither the
increase in [Ca2+]i nor the insulin release
evoked by glucose or other nutrients is entirely dependent on Ca2+
entry (7,
24) or closure of
KATP channels (25).
This suggests that glucose metabolism may also more directly activate RyR
(7,
26) and/or IP3R
(27) to cause release of
Ca2+ from intracellular stores. A change in the ATP/ADP ratio is
one means whereby nutrient metabolism may be linked to opening of
intracellular Ca2+ channels because both RyR
(28) and IP3R
(1) are stimulated by ATP.The other major physiological regulators of insulin release are the
incretins: glucagon-like peptide-1 and glucose-dependent insulinotropic
hormone (29). These hormones,
released by cells in the small intestine, stimulate synthesis of cAMP in
β-cells and thereby potentiate glucose-evoked insulin release
(30). These pathways are also
targets of drugs used successfully to treat type 2 diabetes
(29). The responses of
β-cells to cAMP involve both cAMP-dependent protein kinase and epacs
(exchange factors activated by cAMP)
(31,
32). The effects of the latter
are, at least partly, due to release of Ca2+ from intracellular
stores via RyR
(33–35)
and perhaps also via IP3R
(36). The interplays between
Ca2+ and cAMP signaling generate oscillatory changes in the
concentrations of both messengers
(37). RyR and IP3R
are thus implicated in mediating responses to each of the major physiological
regulators of insulin secretion: glucose and incretins.Here we report that in addition to expression in intracellular stores,
which probably include both the ER and secretory vesicles and/or endosomes,
functional RyR2 are also expressed in small numbers in the PM of RINm5F
insulinoma cells and rat pancreatic β-cells. 相似文献
17.
18.
Sophie Pattingre Chantal Bauvy St��phane Carpentier Thierry Levade Beth Levine Patrice Codogno 《The Journal of biological chemistry》2009,284(5):2719-2728
Macroautophagy is a vacuolar lysosomal catabolic pathway that is stimulated
during periods of nutrient starvation to preserve cell integrity. Ceramide is
a bioactive sphingolipid associated with a large range of cell processes. Here
we show that short-chain ceramides (C2-ceramide and
C6-ceramide) and stimulation of the de novo ceramide
synthesis by tamoxifen induce the dissociation of the complex formed between
the autophagy protein Beclin 1 and the anti-apoptotic protein Bcl-2. This
dissociation is required for macroautophagy to be induced either in response
to ceramide or to starvation. Three potential phosphorylation sites,
Thr69, Ser70, and Ser87, located in the
non-structural N-terminal loop of Bcl-2, play major roles in the dissociation
of Bcl-2 from Beclin 1. We further show that activation of c-Jun N-terminal
protein kinase 1 by ceramide is required both to phosphorylate Bcl-2 and to
stimulate macroautophagy. These findings reveal a new aspect of sphingolipid
signaling in up-regulating a major cell process involved in cell adaptation to
stress.Macroautophagy (referred to below as “autophagy”) is a
vacuolar, lysosomal degradation pathway for cytoplasmic constituents that is
conserved in eukaryotic cells
(1–3).
Autophagy is initiated by the formation of a multimembrane-bound autophagosome
that engulfs cytoplasmic proteins and organelles. The last stage in the
process results in fusion with the lysosomal compartments, where the
autophagic cargo undergoes degradation. Basal autophagy is important in
controlling the quality of the cytoplasm by removing damaged organelles and
protein aggregates. Inhibition of basal autophagy in the brain is deleterious,
and leads to neurodegeneration in mouse models
(4,
5). Stimulation of autophagy
during periods of nutrient starvation is a physiological response present at
birth and has been shown to provide energy in various tissues of newborn pups
(6). In cultured cells,
starvation-induced autophagy is an autonomous cell survival mechanism, which
provides nutrients to maintain a metabolic rate and level of ATP compatible
with cell survival (7). In
addition, starvation-induced autophagy blocks the induction of apoptosis
(8). In other contexts, such as
drug treatment and a hypoxic environment, autophagy has also been shown to be
cytoprotective in cancer cells
(9,
10). However, autophagy is
also part of cell death pathways in certain situations
(11). Autophagy can be a
player in apoptosis-independent type-2 cell death (type-1 cell death is
apoptosis), also known as autophagic cell death. This situation has been shown
to occur when the apoptotic machinery is crippled in mammalian cells
(12,
13). Autophagy can also be
part of the apoptotic program, for instance in tumor necrosis
factor-α-induced cell death when NF-κB is inhibited
(14), or in human
immunodeficiency virus envelope-mediated cell death in bystander naive CD4 T
cells (15). Moreover autophagy
has recently been shown to be required for the externalization of
phosphatidylserine, the eat-me signal for phagocytic cells, at the surface of
apoptotic cells (16).The complex relationship between autophagy and apoptosis reflects the
intertwined regulation of these processes
(17,
18). Many signaling pathways
involved in the regulation of autophagy also regulate apoptosis. This
intertwining has recently been shown to occur at the level of the molecular
machinery of autophagy. In fact the anti-apoptotic protein Bcl-2 has been
shown to inhibit starvation-induced autophagy by interacting with the
autophagy protein Beclin 1
(19). Beclin 1 is one of the
Atg proteins conserved from yeast to humans (it is the mammalian orthologue of
yeast Atg6) and is involved in autophagosome formation
(20). Beclin 1 is a platform
protein that interacts with several different partners, including hVps34
(class III phosphatidylinositol 3-kinase), which is responsible for the
synthesis of phosphatidylinositol 3-phosphate. The production of this lipid is
important for events associated with the nucleation of the isolation membrane
before it elongates and closes to form autophagosomes in response to other Atg
proteins, including the Atg12 and
LC32
(microtubule-associated protein light chain 3 is the mammalian orthologue of
the yeast Atg8) ubiquitin-like conjugation systems
(3,
21). Various partners
associated with the Beclin 1 complex modulate the activity of hVps34. For
instance, Bcl-2 inhibits the activity of this enzyme, whereas UVRAG, Ambra-1,
and Bif-1 all up-regulate it
(22,
23).In view of the intertwining between autophagy and apoptosis, it is
noteworthy that Beclin 1 belongs to the BH3-only family of proteins
(24–26).
However, and unlike most of the proteins in this family, Beclin 1 is not able
to trigger apoptosis when its expression is forced in cells
(27). A BH3-mimetic drug,
ABT-737, is able to dissociate the Beclin 1-Bcl-2 complex, and to trigger
autophagy by mirroring the effect of starvation
(25).The sphingolipids constitute a family of bioactive lipids
(28–32)
of which several members, such as ceramide and sphingosine 1-phosphate, are
signaling molecules. These molecules constitute a “sphingolipid
rheostat” that determines the fate of the cell, because in many settings
ceramide is pro-apoptotic and sphingosine 1-phosphate mitigates this apoptotic
effect (31,
32). However, ceramide is also
engaged in a wide variety of other cell processes, such as the formation of
exosomes (33),
differentiation, cell proliferation, and senescence
(34). Recently we showed that
both ceramide and sphingosine 1-phosphate are able to stimulate autophagy
(35,
36). It has also been shown
that ceramide triggers autophagy in a large panel of mammalian cells
(37–39).
However, elucidation of the mechanism by which ceramide stimulates autophagy
is still in its infancy. We have previously demonstrated that ceramide induces
autophagy in breast and colon cancer cells by inhibiting the Class I
phosphatidylinositol 3-phosphate/mTOR signaling pathway, which plays a central
role in inhibiting autophagy
(36). Inhibition of mTOR is
another hallmark of starvation-induced autophagy
(17). This finding led us to
investigate the effect of ceramide on the Beclin 1-Bcl-2 complex. The results
presented here show that ceramide is more potent than starvation in
dissociating the Beclin 1-Bcl-2 complex (see Ref.
40). This dissociation is
dependent on three phosphorylation sites (Thr69, Ser70,
and Ser87) located in a non-structural loop of Bcl-2. Ceramide
induces the c-Jun N-terminal kinase 1-dependent phosphorylation of Bcl-2.
Expression of a dominant negative form of JNK1 blocks Bcl-2 phosphorylation,
and thus the induction of autophagy by ceramide. These findings help to
explain how autophagy is regulated by a major lipid second messenger. 相似文献
19.
20.
Hongjie Yuan Katie M. Vance Candice E. Junge Matthew T. Geballe James P. Snyder John R. Hepler Manuel Yepes Chian-Ming Low Stephen F. Traynelis 《The Journal of biological chemistry》2009,284(19):12862-12873
Zinc is hypothesized to be co-released with glutamate at synapses of the
central nervous system. Zinc binds to NR1/NR2A
N-methyl-d-aspartate (NMDA) receptors with high affinity
and inhibits NMDAR function in a voltage-independent manner. The serine
protease plasmin can cleave a number of substrates, including
protease-activated receptors, and may play an important role in several
disorders of the central nervous system, including ischemia and spinal cord
injury. Here, we demonstrate that plasmin can cleave the native NR2A
amino-terminal domain (NR2AATD), removing the functional high
affinity Zn2+ binding site. Plasmin also cleaves recombinant
NR2AATD at lysine 317 (Lys317), thereby producing a
∼40-kDa fragment, consistent with plasmin-induced NR2A cleavage fragments
observed in rat brain membrane preparations. A homology model of the
NR2AATD predicts that Lys317 is near the surface of the
protein and is accessible to plasmin. Recombinant expression of NR2A with an
amino-terminal deletion at Lys317 is functional and Zn2+
insensitive. Whole cell voltage-clamp recordings show that Zn2+
inhibition of agonist-evoked NMDA receptor currents of NR1/NR2A-transfected
HEK 293 cells and cultured cortical neurons is significantly reduced by
plasmin treatment. Mutating the plasmin cleavage site Lys317 on
NR2A to alanine blocks the effect of plasmin on Zn2+ inhibition.
The relief of Zn2+ inhibition by plasmin occurs in
PAR1-/- cortical neurons and thus is independent of interaction
with protease-activated receptors. These results suggest that plasmin can
directly interact with NMDA receptors, and plasmin may increase NMDA receptor
responses through disruption or removal of the amino-terminal domain and
relief of Zn2+ inhibition.N-Methyl-d-aspartate
(NMDA)2 receptors are
one of three types of ionotropic glutamate receptors that play critical roles
in excitatory neurotransmission, synaptic plasticity, and neuronal death
(1–3).
NMDA receptors are comprised of glycine-binding NR1 subunits in combination
with at least one type of glutamate-binding NR2 subunit
(1,
4). Each subunit contains three
transmembrane domains, one cytoplasmic re-entrant membrane loop, one bi-lobed
domain that forms the ligand binding site, and one bi-lobed amino-terminal
domain (ATD), thought to share structural homology to periplasmic amino
acid-binding proteins
(4–6).
Activation of NMDA receptors requires combined stimulation by glutamate and
the co-agonist glycine in addition to membrane depolarization to overcome
voltage-dependent Mg2+ block of the ion channel
(7). The activity of NMDA
receptors is negatively modulated by a variety of extracellular ions,
including Mg2+, polyamines, protons, and Zn2+ ions,
which can exert tonic inhibition under physiological conditions
(1,
4). Several extracellular
modulators such as Zn2+ and ifenprodil are thought to act at the
ATD of the NMDA receptor
(8–14).Zinc is a transition metal that plays key roles in both catalytic and
structural capacities in all mammalian cells
(15). Zinc is required for
normal growth and survival of cells. In addition, neuronal death in
hypoxia-ischemia and epilepsy has been associated with Zn2+
(16–18).
Abnormal metabolism of zinc may contribute to induction of cytotoxicity in
neurodegenerative diseases, such as Alzheimer''s disease, Parkinson''s disease,
and amyotrophic lateral sclerosis
(19). Zinc is co-released with
glutamate at excitatory presynaptic terminals and inhibits native NMDA
receptor activation (20,
21). Zn2+ inhibits
NMDA receptor function through a dual mechanism, which includes
voltage-dependent block and voltage-independent inhibition
(22–24).
Voltage-independent Zn2+ inhibition at low nanomolar concentrations
(IC50, 20 nm) is observed for NR2A-containing NMDA
receptors
(25–28).
Evidence has accumulated that the amino-terminal domain of the NR2A subunit
controls high-affinity Zn2+ inhibition of NMDA receptors, and
several histidine residues in this region may constitute part of an
NR2A-specific Zn2+ binding site
(8,
9,
11,
12). For the NR2A subunit,
several lines of evidence suggest that Zn2+ acts by enhancing
proton inhibition (8,
11,
29,
30).Serine proteases present in the circulation, mast cells, and elsewhere
signal directly to cells by cleaving protease-activated receptors (PARs),
members of a subfamily of G-protein-coupled receptors. Cleavage exposes a
tethered ligand domain that binds to and activates the cleaved receptors
(31,
32). Protease receptor
activation has been studied extensively in relation to coagulation and
thrombolysis (33). In addition
to their circulation in the bloodstream, some serine proteases and PARs are
expressed in the central nervous system, and have been suggested to play roles
in physiological conditions (e.g. long-term potentiation or memory)
and pathophysiological states such as glial scarring, edema, seizure, and
neuronal death (31,
34–36).Functional interactions between proteases and NMDA receptors have
previously been suggested. Earlier studies reported that the blood-derived
serine protease thrombin potentiates NMDA receptor response more than 2-fold
through activation of PAR1
(37). Plasmin, another serine
protease, similarly potentiates NMDA receptor response
(38). Tissue-plasminogen
activator (tPA), which catalyzes the conversion of the zymogen precursor
plasminogen to plasmin and results in PAR1 activation, also interacts with and
cleaves the ATD of the NR1 subunit of the NMDA receptor
(39,
40). This raises the
possibility that plasmin may also interact directly with the NMDA receptor
subunits to modulate receptor response. We therefore investigated the ability
of plasmin to cleave the NR2A NMDA receptor subunit. We found that nanomolar
concentrations of plasmin can cleave within the ATD, a region that mediates
tonic voltage-independent Zn2+ inhibition of NR2A-containing NMDA
receptors. We hypothesized that plasmin cleavage reduces the
Zn2+-mediated inhibition of NMDA receptors by removing the
Zn2+ binding domain. In the present study, we have demonstrated
that Zn2+ inhibition of agonist-evoked NMDA currents is decreased
significantly by plasmin treatment in recombinant NR1/NR2A-transfected HEK 293
cells and cultured cortical neurons. These concentrations of plasmin may be
pathophysiologically relevant in situations in which the blood-brain barrier
is compromised, which could allow blood-derived plasmin to enter brain
parenchyma at concentrations in excess of these that can cleave NR2A. Thus,
ability of plasmin to potentiate NMDA function through the relief of the
Zn2+ inhibition could exacerbate the harmful actions of NMDA
receptor overactivation in pathological situations. In addition, if newly
cleaved NR2AATD enters the bloodstream during ischemic injury, it
could serve as a biomarker of central nervous system injury. 相似文献