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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
3.
Denise A. Berti Cain Morano Lilian C. Russo Leandro M. Castro Fernanda M. Cunha Xin Zhang Juan Sironi Cl��cio F. Klitzke Emer S. Ferro Lloyd D. Fricker 《The Journal of biological chemistry》2009,284(21):14105-14116
Thimet oligopeptidase (EC 3.4.24.15; EP24.15) is an intracellular enzyme
that has been proposed to metabolize peptides within cells, thereby affecting
antigen presentation and G protein-coupled receptor signal transduction.
However, only a small number of intracellular substrates of EP24.15 have been
reported previously. Here we have identified over 100 peptides in human
embryonic kidney 293 (HEK293) cells that are derived from intracellular
proteins; many but not all of these peptides are substrates or products of
EP24.15. First, cellular peptides were extracted from HEK293 cells and
incubated in vitro with purified EP24.15. Then the peptides were
labeled with isotopic tags and analyzed by mass spectrometry to obtain
quantitative data on the extent of cleavage. A related series of experiments
tested the effect of overexpression of EP24.15 on the cellular levels of
peptides in HEK293 cells. Finally, synthetic peptides that corresponded to 10
of the cellular peptides were incubated with purified EP24.15 in
vitro, and the cleavage was monitored by high pressure liquid
chromatography and mass spectrometry. Many of the EP24.15 substrates
identified by these approaches are 9–11 amino acids in length,
supporting the proposal that EP24.15 can function in the degradation of
peptides that could be used for antigen presentation. However, EP24.15 also
converts some peptides into products that are 8–10 amino acids, thus
contributing to the formation of peptides for antigen presentation. In
addition, the intracellular peptides described here are potential candidates
to regulate protein interactions within cells.Intracellular protein turnover is a crucial step for cell functioning, and
if this process is impaired, the elevated levels of aged proteins usually lead
to the formation of intracellular insoluble aggregates that can cause severe
pathologies (1). In mammalian
cells, most proteins destined for degradation are initially tagged with a
polyubiquitin chain in an energy-dependent process and then digested to small
peptides by the 26 S proteasome, a large proteolytic complex involved in the
regulation of cell division, gene expression, and other key processes
(2,
3). In eukaryotes, 30–90%
of newly synthesized proteins may be degraded by proteasomes within minutes of
synthesis (3,
4). In addition to proteasomes,
other extralysosomal proteolytic systems have been reported
(5,
6). The proteasome cleaves
proteins into peptides that are typically 2–20 amino acids in length
(7). In most cases, these
peptides are thought to be rapidly hydrolyzed into amino acids by
aminopeptidases
(8–10).
However, some intracellular peptides escape complete degradation and are
imported into the endoplasmic reticulum where they associate with major
histocompatibility complex class I
(MHC-I)3 molecules and
traffic to the cell surface for presentation to the immune system
(10–12).
Additionally, based on the fact that free peptides added to the intracellular
milieu can regulate cellular functions mediated by protein interactions such
as gene regulation, metabolism, cell signaling, and protein targeting
(13,
14), intracellular peptides
generated by proteasomes that escape degradation have been suggested to play a
role in regulating protein interactions
(15). Indeed, oligopeptides
isolated from rat brain tissue using the catalytically inactive EP24.15 (EC
3.4.24.15) were introduced into Chinese hamster ovarian-S and HEK293 cells and
were found capable of altering G protein-coupled receptor signal transduction
(16). Moreover, EP24.15
overexpression itself changed both angiotensin II and isoproterenol signal
transduction, suggesting a physiological function for its intracellular
substrates/products (16).EP24.15 is a zinc-dependent peptidase of the metallopeptidase M3 family
that contains the HEXXH motif
(17). This enzyme was first
described as a neuropeptide-degrading enzyme present in the soluble fraction
of brain homogenates (18).
Whereas EP24.15 can be secreted
(19,
20), its predominant location
in the cytosol and nucleus suggests that the primary function of this enzyme
is not the extracellular degradation of neuropeptides and hormones
(21,
22). EP24.15 was shown in
vivo to participate in antigen presentation through MHC-I
(23–25)
and in vitro to bind
(26) or degrade
(27) some MHC-I associated
peptides. EP24.15 has also been shown in vitro to degrade peptides
containing 5–17 amino acids produced after proteasome digestion of
β-casein (28). EP24.15
shows substrate size restriction to peptides containing from 5 to 17 amino
acids because of its catalytic center that is located in a deep channel
(29). Despite the size
restriction, EP24.15 has a broad substrate specificity
(30), probably because a
significant portion of the enzyme-binding site is lined with potentially
flexible loops that allow reorganization of the active site following
substrate binding (29).
Recently, it has also been suggested that certain substrates may be cleaved by
an open form of EP24.15 (31).
This characteristic is supported by the ability of EP24.15 to accommodate
different amino acid residues at subsites S4 to S3′, which even includes
the uncommon post-proline cleavage
(30). Such biochemical and
structural features make EP24.15 a versatile enzyme to degrade structurally
unrelated oligopeptides.Previously, brain peptides that bound to catalytically inactive EP24.15
were isolated and identified using mass spectrometry
(22). The majority of peptides
captured by the inactive enzyme were intracellular protein fragments that
efficiently interacted with EP24.15; the smallest peptide isolated in these
assays contained 5 and the largest 17 amino acids
(15,
16,
22,
32), which is within the size
range previously reported for natural and synthetic substrates of EP24.15
(18,
30,
33,
34). Interestingly, the
peptides released by the proteasome are in the same size range of EP24.15
competitive inhibitors/substrates
(7,
35,
36). Taken altogether, these
data suggest that in the intracellular environment EP24.15 could further
cleave proteasome-generated peptides unrelated to MHC-I antigen presentation
(15).Although the mutated inactive enzyme “capture” assay was
successful in identifying several cellular protein fragments that were
substrates for EP24.15, it also found some interacting peptides that were not
substrates. In this study, we used several approaches to directly screen for
cellular peptides that were cleaved by EP24.15. The first approach involved
the extraction of cellular peptides from the HEK293 cell line, incubation
in vitro with purified EP24.15, labeling with isotopic tags, and
analysis by mass spectrometry to obtain quantitative data on the extent of
cleavage. The second approach examined the effect of EP24.15 overexpression on
the cellular levels of peptides in the HEK293 cell line. The third set of
experiments tested synthetic peptides with purified EP24.15 in vitro,
and examined cleavage by high pressure liquid chromatography and mass
spectrometry. Collectively, these studies have identified a large number of
intracellular peptides, including those that likely represent the endogenous
substrates and products of EP24.15, and this original information contributes
to a better understanding of the function of this enzyme in vivo. 相似文献
4.
S��bastien Thomas Brigitte Ritter David Verbich Claire Sanson Lyne Bourbonni��re R. Anne McKinney Peter S. McPherson 《The Journal of biological chemistry》2009,284(18):12410-12419
Intersectin-short (intersectin-s) is a multimodule scaffolding protein
functioning in constitutive and regulated forms of endocytosis in non-neuronal
cells and in synaptic vesicle (SV) recycling at the neuromuscular junction of
Drosophila and Caenorhabditis elegans. In vertebrates,
alternative splicing generates a second isoform, intersectin-long
(intersectin-l), that contains additional modular domains providing a guanine
nucleotide exchange factor activity for Cdc42. In mammals, intersectin-s is
expressed in multiple tissues and cells, including glia, but excluded from
neurons, whereas intersectin-l is a neuron-specific isoform. Thus,
intersectin-I may regulate multiple forms of endocytosis in mammalian neurons,
including SV endocytosis. We now report, however, that intersectin-l is
localized to somatodendritic regions of cultured hippocampal neurons, with
some juxtanuclear accumulation, but is excluded from synaptophysin-labeled
axon terminals. Consistently, intersectin-l knockdown (KD) does not affect SV
recycling. Instead intersectin-l co-localizes with clathrin heavy chain and
adaptor protein 2 in the somatodendritic region of neurons, and its KD reduces
the rate of transferrin endocytosis. The protein also co-localizes with
F-actin at dendritic spines, and intersectin-l KD disrupts spine maturation
during development. Our data indicate that intersectin-l is indeed an
important regulator of constitutive endocytosis and neuronal development but
that it is not a prominent player in the regulated endocytosis of SVs.Clathrin-mediated endocytosis
(CME)4 is a
major mechanism by which cells take up nutrients, control the surface levels
of multiple proteins, including ion channels and transporters, and regulate
the coupling of signaling receptors to downstream signaling cascades
(1-5).
In neurons, CME takes on additional specialized roles; it is an important
process regulating synaptic vesicle (SV) availability through endocytosis and
recycling of SV membranes (6,
7), it shapes synaptic
plasticity
(8-10),
and it is crucial in maintaining synaptic membranes and membrane structure
(11).Numerous endocytic accessory proteins participate in CME, interacting with
each other and with core components of the endocytic machinery such as
clathrin heavy chain (CHC) and adaptor protein-2 (AP-2) through specific
modules and peptide motifs
(12). One such module is the
Eps15 homology domain that binds to proteins bearing NPF motifs
(13,
14). Another is the Src
homology 3 (SH3) domain, which binds to proline-rich domains in protein
partners (15). Intersectin is
a multimodule scaffolding protein that interacts with a wide range of
proteins, including several involved in CME
(16). Intersectin has two
N-terminal Eps15 homology domains that are responsible for binding to epsin,
SCAMP1, and numb
(17-19),
a central coil-coiled domain that interacts with Eps15 and SNAP-23 and -25
(17,
20,
21), and five SH3 domains in
its C-terminal region that interact with multiple proline-rich domain
proteins, including synaptojanin, dynamin, N-WASP, CdGAP, and mSOS
(16,
22-25).
The rich binding capability of intersectin has linked it to various functions
from CME (17,
26,
27) and signaling
(22,
28,
29) to mitogenesis
(30,
31) and regulation of the
actin cytoskeleton (23).Intersectin functions in SV recycling at the neuromuscular junction of
Drosophila and C. elegans where it acts as a scaffold,
regulating the synaptic levels of endocytic accessory proteins
(21,
32-34).
In vertebrates, the intersectin gene is subject to alternative splicing, and a
longer isoform (intersectin-l) is generated that is expressed exclusively in
neurons (26,
28,
35,
36). This isoform has all the
binding modules of its short (intersectin-s) counterpart but also has
additional domains: a DH and a PH domain that provide guanine nucleotide
exchange factor (GEF) activity specific for Cdc42
(23,
37) and a C2 domain at the C
terminus. Through its GEF activity and binding to actin regulatory proteins,
including N-WASP, intersectin-l has been implicated in actin regulation and
the development of dendritic spines
(19,
23,
24). In addition, because the
rest of the binding modules are shared between intersectin-s and -l, it is
generally thought that the two intersectin isoforms have the same endocytic
functions. In particular, given the well defined role for the invertebrate
orthologs of intersectin-s in SV endocytosis, it is thought that intersectin-l
performs this role in mammalian neurons, which lack intersectin-s. Defining
the complement of intersectin functional activities in mammalian neurons is
particularly relevant given that the protein is involved in the
pathophysiology of Down syndrome (DS). Specifically, the intersectin gene is
localized on chromosome 21q22.2 and is overexpressed in DS brains
(38). Interestingly,
alterations in endosomal pathways are a hallmark of DS neurons and neurons
from the partial trisomy 16 mouse, Ts65Dn, a model for DS
(39,
40). Thus, an endocytic
trafficking defect may contribute to the DS disease process.Here, the functional roles of intersectin-l were studied in cultured
hippocampal neurons. We find that intersectin-l is localized to the
somatodendritic regions of neurons, where it co-localizes with CHC and AP-2
and regulates the uptake of transferrin. Intersectin-l also co-localizes with
actin at dendritic spines and disrupting intersectin-l function alters
dendritic spine development. In contrast, intersectin-l is absent from
presynaptic terminals and has little or no role in SV recycling. 相似文献
5.
6.
Jonathan M. Budzik So-Young Oh Olaf Schneewind 《The Journal of biological chemistry》2009,284(19):12989-12997
Bacillus cereus and other Gram-positive bacteria elaborate pili
via a sortase D-catalyzed transpeptidation mechanism from major and minor
pilin precursor substrates. After cleavage of the LPXTG sorting
signal of the major pilin, BcpA, sortase D forms an amide bond between the
C-terminal threonine and the amino group of lysine within the YPKN motif of
another BcpA subunit. Pilus assembly terminates upon sortase A cleavage of the
BcpA sorting signal, resulting in a covalent bond between BcpA and the cell
wall cross-bridge. Here, we show that the IPNTG sorting signal of BcpB, the
minor pilin, is cleaved by sortase D but not by sortase A. The C-terminal
threonine of BcpB is amide-linked to the YPKN motif of BcpA, thereby
positioning BcpB at the tip of pili. Thus, unique attributes of the sorting
signals of minor pilins provide Gram-positive bacteria with a universal
mechanism ordering assembly of pili.Sortases catalyze transpeptidation reactions to assemble proteins in the
envelope of Gram-positive bacteria
(1). Secreted proteins require
a C-terminal sorting signal for sortase recognition such that sortase cleaves
the substrate at a short peptide motif and forms a thioester-linked
intermediate to its active site cysteine
(2–4).
Nucleophilic attack by an amino group within the bacterial envelope resolves
the thioester intermediate, generating an amide bond tethering surface
proteins at their C terminus onto Gram-positive bacteria
(5). Four classes of sortases
can be distinguished on the basis of sequence homology and substrate
recognition (6,
7). Sortase A cleaves secreted
protein at LPXTG sorting signals and recognizes the amino group of
lipid II peptidoglycan precursors as a nucleophile
(8,
9). Sortase B cleaves protein
substrates at NPQTN sorting signals
(10). This enzyme immobilizes
proteins within fully assembled cell walls, utilizing the cell wall
cross-bridge as a nucleophile
(11). Sortase C cuts LPNTA
sorting signals and anchors proteins to the peptidoglycan cross-bridges in
sporulating bacteria (12,
13). Finally, sortase D
catalyzes transpeptidation reactions in the assembly of pili
(14,
15). Sortase D recognizes the
amino group of lysine residues within the YPKN motif of pilin subunits as
nucleophiles (16). The
resultant sortase D-catalyzed amide bond links adjacent pilin subunits to grow
the pilus fiber (16,
17).Pili of Gram-positive bacteria comprised either two or three different
pilin subunits synthesized as cytoplasmic precursors with N-terminal signal
peptides and C-terminal sorting signals (P1 precursors)
(14,
18). After translocation
across the plasma membrane, P2 precursor species arise from removal of the
signal peptide from P1 precursors by a signal peptidase
(16). Bacillus cereus
pili are composed of two subunits; that is, the major pilin, BcpA, and the
minor pilin, BcpB (15). In
contrast to BcpA, which is deposited throughout the pilus, BcpB is found at
fiber tip (15). Sortase D
cleaves the BcpA LPXTG motif sorting signal between the threonine and
glycine residues to form an amide bond to the ε-amino group of the lysine
within the YPKN motif of adjacent BcpA subunits
(16). However, sortase A also
cleaves BcpA precursors, which are subsequently linked to the side chain amino
group of meso-diaminopimelic acid within lipid II
(19). The latter reaction
serves to terminate fiber elongation, immobilizing BcpA pili in the cell wall
envelope (19).The conservation of sortase D, the YPKN motif, and C-terminal sorting
signal in major pilin subunits suggest a universal pilus assembly mechanism
among Gram-positive bacteria
(14,
20). However, the molecular
mechanism whereby bacilli deposit BcpB, the minor pilin, at the tip of BcpA
pili is not known. Although the BcpB precursor harbors an N-terminal signal
peptide and a C-terminal IPNTG sorting signal, it lacks the YPKN pilin motif
of the major subunit (15).
Furthermore, the substrate properties of the BcpB IPNTG sorting signal for the
four classes of sortases expressed by bacilli has yet to be established. 相似文献
7.
ATP-binding cassette (ABC) transporters transduce the free energy of ATP
hydrolysis to power the mechanical work of substrate translocation across cell
membranes. MsbA is an ABC transporter implicated in trafficking lipid A across
the inner membrane of Escherichia coli. It has sequence similarity
and overlapping substrate specificity with multidrug ABC transporters that
export cytotoxic molecules in humans and prokaryotes. Despite rapid advances
in structure determination of ABC efflux transporters, little is known
regarding the location of substrate-binding sites in the transmembrane segment
and the translocation pathway across the membrane. In this study, we have
mapped residues proximal to the daunorubicin (DNR)-binding site in MsbA using
site-specific, ATP-dependent quenching of DNR intrinsic fluorescence by spin
labels. In the nucleotide-free MsbA intermediate, DNR-binding residues cluster
at the cytoplasmic end of helices 3 and 6 at a site accessible from the
membrane/water interface and extending into an aqueous chamber formed at the
interface between the two transmembrane domains. Binding of a nonhydrolyzable
ATP analog inverts the transporter to an outward-facing conformation and
relieves DNR quenching by spin labels suggesting DNR exclusion from proximity
to the spin labels. The simplest model consistent with our data has DNR
entering near an elbow helix parallel to the water/membrane interface,
partitioning into the open chamber, and then translocating toward the
periplasm upon ATP binding.ATP-binding cassette
(ABC)2 transporters
transduce the energy of ATP hydrolysis to power the movement of a wide range
of substrates across the cell membranes
(1,
2). They constitute the largest
family of prokaryotic transporters, import essential cell nutrients, flip
lipids, and export toxic molecules
(3). Forty eight human ABC
transporters have been identified, including ABCB1, or P-glycoprotein, which
is implicated in cross-resistance to drugs and cytotoxic molecules
(4,
5). Inherited mutations in
these proteins are linked to diseases such as cystic fibrosis, persistent
hypoglycemia of infancy, and immune deficiency
(6).The functional unit of an ABC transporter consists of four modules. Two
highly conserved ABCs or nucleotide-binding domains (NBDs) bind and hydrolyze
ATP to supply the active energy for transport
(7). ABCs drive the mechanical
work of proteins with diverse functions ranging from membrane transport to DNA
repair (3,
5). Substrate specificity is
determined by two transmembrane domains (TMDs) that also provide the
translocation pathway across the bilayer
(7). Bacterial ABC exporters
are expressed as monomers, each consisting of one NBD and one TMD, that
dimerize to form the active transporter
(3). The number of
transmembrane helices and their organization differ significantly between ABC
importers and exporters reflecting the divergent structural and chemical
nature of their substrates (1,
8,
9). Furthermore, ABC exporters
bind substrates directly from the cytoplasm or bilayer inner leaflet and
release them to the periplasm or bilayer outer leaflet
(10,
11). In contrast, bacterial
importers have their substrates delivered to the TMD by a dedicated high
affinity substrate-binding protein
(12).In Gram-negative bacteria, lipid A trafficking from its synthesis site on
the inner membrane to its final destination in the outer membrane requires the
ABC transporter MsbA (13).
Although MsbA has not been directly shown to transport lipid A, suppression of
MsbA activity leads to cytoplasmic accumulation of lipid A and inhibits
bacterial growth strongly suggesting a role in translocation
(14-16).
In addition to this role in lipid A transport, MsbA shares sequence similarity
with multidrug ABC transporters such as human ABCB1, LmrA of Lactococcus
lactis, and Sav1866 of Staphylococcus aureus
(16-19).
ABCB1, a prototype of the ABC family, is a plasma membrane protein whose
overexpression provides resistance to chemotherapeutic agents in cancer cells
(1). LmrA and MsbA have
overlapping substrate specificity with ABCB1 suggesting that both proteins can
function as drug exporters
(18,
20). Indeed, cells expressing
MsbA confer resistance to erythromycin and ethidium bromide
(21). MsbA can be photolabeled
with the ABCB1/LmrA substrate azidopine and can transport Hoechst 33342
() across membrane vesicles in an energy-dependent manner
( H3334221).The structural mechanics of ABC exporters was revealed from comparison of
the MsbA crystal structures in the apo- and nucleotide-bound states as well as
from analysis by spin labeling EPR spectroscopy in liposomes
(17,
19,
22,
23). The energy harnessed from
ATP binding and hydrolysis drives a cycle of NBD association and dissociation
that is transmitted to induce reorientation of the TMD from an inward- to
outward-facing conformation
(17,
19,
22). Large amplitude motion
closes the cytoplasmic end of a chamber found at the interface between the two
TMDs and opens it to the periplasm
(23). These rearrangements
lead to significant changes in chamber hydration, which may drive substrate
translocation (22).Substrate binding must precede energy input, otherwise the cycle is futile,
wasting the energy of ATP hydrolysis without substrate extrusion
(7). Consistent with this
model, ATP binding reduces ABCB1 substrate affinity, potentially through
binding site occlusion
(24-26).
Furthermore, the TMD substrate-binding event signals the NBD to stimulate ATP
hydrolysis increasing transport efficiency
(1,
27,
28). However, there is a
paucity of information regarding the location of substrate binding, the
transport pathway, and the structural basis of substrate recognition by ABC
exporters. In vitro studies of MsbA substrate specificity identify a
broad range of substrates that stimulate ATPase activity
(29). In addition to the
putative physiological substrates lipid A and lipopolysaccharide (LPS), the
ABCB1 substrates Ilmofosine, , and verapamil differentially enhance ATP
hydrolysis of MsbA ( H3334229,
30). Intrinsic MsbA tryptophan
(Trp) fluorescence quenching by these putative substrate molecules provides
further support of interaction
(29).Extensive biochemical analysis of ABCB1 and LmrA provides a general model
of substrate binding to ABC efflux exporters. This so-called
“hydrophobic cleaner model” describes substrates binding from the
inner leaflet of the bilayer and then translocating through the TMD
(10,
31,
32). These studies also
identified a large number of residues involved in substrate binding and
selectivity (33). When these
crucial residues are mapped onto the crystal structures of MsbA, a subset of
homologous residues clusters to helices 3 and 6 lining the putative substrate
pathway (34). Consistent with
a role in substrate binding and specificity, simultaneous replacement of two
serines (Ser-289 and Ser-290) in helix 6 of MsbA reduces binding and transport
of ethidium and taxol, although and erythromycin interactions remain
unaffected ( H3334234).The tendency of lipophilic substrates to partition into membranes confounds
direct analysis of substrate interactions with ABC exporters
(35,
36). Such partitioning may
promote dynamic collisions with exposed Trp residues and nonspecific
cross-linking in photo-affinity labeling experiments. In this study, we
utilize a site-specific quenching approach to identify residues in the
vicinity of the daunorubicin (DNR)-binding site
(37). Although the data on DNR
stimulation of ATP hydrolysis is inconclusive
(20,
29,
30), the quenching of MsbA Trp
fluorescence suggests a specific interaction. Spin labels were introduced
along transmembrane helices 3, 4, and 6 of MsbA to assess their ATP-dependent
quenching of DNR fluorescence. Residues that quench DNR cluster along the
cytoplasmic end of helices 3 and 6 consistent with specific binding of DNR.
Furthermore, many of these residues are not lipid-exposed but face the
putative substrate chamber formed between the two TMDs. These residues are
proximal to two Trps, which likely explains the previously reported quenching
(29). Our results suggest DNR
partitions to the membrane and then binds MsbA in a manner consistent with the
hydrophobic cleaner model. Interpretation in the context of the crystal
structures of MsbA identifies a putative translocation pathway through the
transmembrane segment. 相似文献
8.
9.
Tatsuhiro Sato Akio Nakashima Lea Guo Fuyuhiko Tamanoi 《The Journal of biological chemistry》2009,284(19):12783-12791
Rheb G-protein plays critical roles in the TSC/Rheb/mTOR signaling pathway
by activating mTORC1. The activation of mTORC1 by Rheb can be faithfully
reproduced in vitro by using mTORC1 immunoprecipitated by the use of
anti-raptor antibody from mammalian cells starved for nutrients. The low
in vitro kinase activity against 4E-BP1 of this mTORC1 preparation is
dramatically increased by the addition of recombinant Rheb. On the other hand,
the addition of Rheb does not activate mTORC2 immunoprecipitated from
mammalian cells by the use of anti-rictor antibody. The activation of mTORC1
is specific to Rheb, because other G-proteins such as KRas, RalA/B, and Cdc42
did not activate mTORC1. Both Rheb1 and Rheb2 activate mTORC1. In addition,
the activation is dependent on the presence of bound GTP. We also find that
the effector domain of Rheb is required for the mTORC1 activation. FKBP38, a
recently proposed mediator of Rheb action, appears not to be involved in the
Rheb-dependent activation of mTORC1 in vitro, because the preparation
of mTORC1 that is devoid of FKBP38 is still activated by Rheb. The addition of
Rheb results in a significant increase of binding of the substrate protein
4E-BP1 to mTORC1. PRAS40, a TOR signaling (TOS) motif-containing protein that
competes with the binding of 4EBP1 to mTORC1, inhibits Rheb-induced activation
of mTORC1. A preparation of mTORC1 that is devoid of raptor is not activated
by Rheb. Rheb does not induce autophosphorylation of mTOR. These results
suggest that Rheb induces alteration in the binding of 4E-BP1 with mTORC1 to
regulate mTORC1 activation.Rheb defines a unique member of the Ras superfamily G-proteins
(1). We have shown that Rheb
proteins are conserved and are found from yeast to human
(2). Although yeast and fruit
fly have one Rheb, mouse and human have two Rheb proteins termed Rheb1 (or
simply Rheb) and Rheb2 (RhebL1)
(2). Structurally, these
proteins contain G1-G5 boxes, short stretches of amino acids that define the
function of the Ras superfamily G-proteins including guanine nucleotide
binding (1,
3,
4). Rheb proteins have a
conserved arginine at residue 15 that corresponds to residue 12 of Ras
(1). The effector domain
required for the binding with downstream effectors encompasses the G2 box and
its adjacent sequences (1,
5). Structural analysis by
x-ray crystallography further shows that the effector domain is exposed to
solvent, is located close to the phosphates of GTP especially at residues
35–38, and undergoes conformational change during GTP/GDP exchange
(6). In addition, all Rheb
proteins end with the CAAX (C is cysteine, A is an aliphatic amino
acid, and X is the C-terminal amino acid) motif that signals
farnesylation. In fact, we as well as others have shown that these proteins
are farnesylated
(7–9).Rheb plays critical roles in the TSC/Rheb/mTOR signaling, a signaling
pathway that plays central roles in regulating protein synthesis and growth in
response to nutrient, energy, and growth conditions
(10–14).
Rheb is down-regulated by a TSC1·TSC2 complex that acts as a
GTPase-activating protein for Rheb
(15–19).
Recent studies established that the GAP domain of TSC2 defines the functional
domain for the down-regulation of Rheb
(20). Mutations in the
Tsc1 or Tsc2 gene lead to tuberous sclerosis whose symptoms
include the appearance of benign tumors called hamartomas at different parts
of the body as well as neurological symptoms
(21,
22). Overexpression of Rheb
results in constitutive activation of mTOR even in the absence of nutrients
(15,
16). Two mTOR complexes,
mTORC1 and mTORC2, have been identified
(23,
24). Whereas mTORC1 is
involved in protein synthesis activation mediated by S6K and 4EBP1, mTORC2 is
involved in the phosphorylation of Akt in response to insulin. It has been
suggested that Rheb is involved in the activation of mTORC1 but not mTORC2
(25).Although Rheb is clearly involved in the activation of mTOR, the mechanism
of activation has not been established. We as well as others have suggested a
model that involves the interaction of Rheb with the TOR complex
(26–28).
Rheb activation of mTOR kinase activity using immunoprecipitated mTORC1 was
reported (29). Rheb has been
shown to interact with mTOR
(27,
30), and this may involve
direct interaction of Rheb with the kinase domain of mTOR
(27). However, this Rheb/mTOR
interaction is a weak interaction and is not dependent on the presence of GTP
bound to Rheb (27,
28). Recently, a different
model proposing that FKBP38 (FK506-binding protein
38) mediates the activation of
mTORC1 by Rheb was proposed
(31,
32). In this model, FKBP38
binds mTOR and negatively regulates mTOR activity, and this negative
regulation is blocked by the binding of Rheb to FKBP38. However, recent
reports dispute this idea
(33).To further characterize Rheb activation of mTOR, we have utilized an in
vitro system that reproduces activation of mTORC1 by the addition of
recombinant Rheb. We used mTORC1 immunoprecipitated from nutrient-starved
cells using anti-raptor antibody and have shown that its kinase activity
against 4E-BP1 is dramatically increased by the addition of recombinant Rheb.
Importantly, the activation of mTORC1 is specific to Rheb and is dependent on
the presence of bound GTP as well as an intact effector domain. FKBP38 is not
detected in our preparation and further investigation suggests that FKBP38 is
not an essential component for the activation of mTORC1 by Rheb. Our study
revealed that Rheb enhances the binding of a substrate 4E-BP1 with mTORC1
rather than increasing the kinase activity of mTOR. 相似文献
10.
11.
Jaemin Lee Xiaofan Wang Bruno Di Jeso Peter Arvan 《The Journal of biological chemistry》2009,284(19):12752-12761
The carboxyl-terminal cholinesterase-like (ChEL) domain of thyroglobulin
(Tg) has been identified as critically important in Tg export from the
endoplasmic reticulum. In a number of human kindreds suffering from congenital
hypothyroidism, and in the cog congenital goiter mouse and
rdw rat dwarf models, thyroid hormone synthesis is inhibited because
of mutations in the ChEL domain that block protein export from the endoplasmic
reticulum. We hypothesize that Tg forms homodimers through noncovalent
interactions involving two predicted α-helices in each ChEL domain that
are homologous to the dimerization helices of acetylcholinesterase. This has
been explored through selective epitope tagging of dimerization partners and
by inserting an extra, unpaired Cys residue to create an opportunity for
intermolecular disulfide pairing. We show that the ChEL domain is necessary
and sufficient for Tg dimerization; specifically, the isolated ChEL domain can
dimerize with full-length Tg or with itself. Insertion of an N-linked
glycan into the putative upstream dimerization helix inhibits homodimerization
of the isolated ChEL domain. However, interestingly, co-expression of upstream
Tg domains, either in cis or in trans, overrides the
dimerization defect of such a mutant. Thus, although the ChEL domain provides
a nidus for Tg dimerization, interactions of upstream Tg regions with the ChEL
domain actively stabilizes the Tg dimer complex for intracellular
transport.The synthesis of thyroid hormone in the thyroid gland requires secretion of
thyroglobulin (Tg)2 to
the apical luminal cavity of thyroid follicles
(1). Once secreted, Tg is
iodinated via the activity of thyroid peroxidase
(2). A coupling reaction
involving a quinol-ether linkage especially engages di-iodinated tyrosyl
residues 5 and 130 to form thyroxine within the amino-terminal portion of the
Tg polypeptide (3,
4). Preferential iodination of
Tg hormonogenic sites is dependent not on the specificity of the peroxidase
(5) but upon the native
structure of Tg (6,
7). To date, no other thyroidal
proteins have been shown to effectively substitute in this role for Tg.The first 80% of the primary structure of Tg (full-length murine Tg: 2,746
amino acids) involves three regions called I-II-III comprised of
disulfide-rich repeat domains held together by intradomain disulfide bonds
(8,
9). The final 581 amino acids
of Tg are strongly homologous to acetylcholinesterase
(10–12).
Rate-limiting steps in the overall process of Tg secretion involve its
structural maturation within the endoplasmic reticulum (ER)
(13). Interactions between
regions I-II-III and the cholinesterase-like (ChEL) domain have recently been
suggested to be important in this process, with ChEL functioning as an
intramolecular chaperone and escort for I-II-III
(14). In addition, Tg
conformational maturation culminates in Tg homodimerization
(15,
16) with progression to a
cylindrical, and ultimately, a compact ovoid structure
(17–19).In human congenital hypothyroidism with deficient Tg, the ChEL domain is a
commonly affected site of mutation, including the recently described A2215D
(20,
21), R2223H
(22), G2300D, R2317Q
(23), G2355V, G2356R, and the
skipping of exon 45 (which normally encodes 36 amino acids), as well as the
Q2638stop mutant (24) (in
addition to polymorphisms including P2213L, W2482R, and R2511Q that may be
associated with thyroid overgrowth
(25)). As best as is currently
known, all of the congenital hypothyroidism-inducing Tg mutants are defective
for intracellular transport
(26). A homozygous G2300R
mutation (equivalent to residue 2,298 of mouse Tg) in the ChEL domain is
responsible for congenital hypothyroidism in rdw rats
(27,
28), whereas we identified the
Tg-L2263P point mutation as the cause of hypothyroidism in the cog
mouse (29). Such mutations
perturb intradomain structure
(30), and interestingly, block
homodimerization (31).
Acquisition of quaternary structure has long been thought to be required for
efficient export from the ER
(32) as exemplified by
authentic acetylcholinesterase
(33,
34) in which dimerization
enhances protein stability and export
(35).Tg comprised only of regions I-II-III (truncated to lack the ChEL domain)
is blocked within the ER (30),
whereas a secretory version of the isolated ChEL domain of Tg devoid of
I-II-III undergoes rapid and efficient intracellular transport and secretion
(14). A striking homology
positions two predicted α-helices of the ChEL domain to the identical
relative positions of the dimerization helices in acetylcholinesterase. This
raises the possibility that ChEL may serve as a homodimerization domain for
Tg, providing a critical function in maturation for Tg transport to the site
of thyroid hormone synthesis
(1).In this study, we provide unequivocal evidence for homodimerization of the
ChEL domain and “hetero”-dimerization of that domain with
full-length Tg, and we provide significant evidence that the predicted ChEL
dimerization helices provide a nidus for Tg assembly. On the other hand, our
data also suggest that upstream Tg regions known to interact with ChEL
(14) actively stabilize the Tg
dimer complex. Together, I-II-III and ChEL provide unique contributions to the
process of intracellular transport of Tg through the secretory pathway. 相似文献
12.
13.
14.
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
15.
Daniel Lingwood Sebastian Schuck Charles Ferguson Mathias J. Gerl Kai Simons 《The Journal of biological chemistry》2009,284(18):12041-12048
Cell membranes predominantly consist of lamellar lipid bilayers. When
studied in vitro, however, many membrane lipids can exhibit
non-lamellar morphologies, often with cubic symmetries. An open issue is how
lipid polymorphisms influence organelle and cell shape. Here, we used
controlled dimerization of artificial membrane proteins in mammalian tissue
culture cells to induce an expansion of the endoplasmic reticulum (ER) with
cubic symmetry. Although this observation emphasizes ER architectural
plasticity, we found that the changed ER membrane became sequestered into
large autophagic vacuoles, positive for the autophagy protein LC3. Autophagy
may be targeting irregular membrane shapes and/or aggregated protein. We
suggest that membrane morphology can be controlled in cells.The observation that simple mixtures of amphiphilic (polar) lipids and
water yield a rich flora of phase structures has opened a long-standing debate
as to whether such membrane polymorphisms are relevant for living organisms
(1–7).
Lipid bilayers with planar geometry, termed lamellar symmetry, dominate the
membrane structure of cells. However, this architecture comprises only a
fraction of the structures seen with in vitro lipid-water systems
(7–11).
The propensity to form lamellar bilayers (a property exclusive to
cylindrically shaped lipids) is flanked by a continuum of lipid structures
that occur in a number of exotic and probably non-physiological
non-bilayer configurations
(3,
12). However, certain lipids,
particularly those with smaller head groups and more bulky hydrocarbon chains,
can adopt bilayered non-lamellar phases called cubic phases. Here the
bilayer is curved everywhere in the form of saddle shapes corresponding to an
energetically favorable minimal surface of zero mean curvature
(1,
7). Because a substantial
number of the lipids present in biological membranes, when studied as
individual pure lipids, form cubic phases
(13), cubic membranes have
received particular interest in cell biology.Since the application of electron microscopy
(EM)3 to the study of
cell ultrastructure, unusual membrane morphologies have been reported for
virtually every organelle (14,
15). However, interpretation
of three-dimensional structures from two-dimensional electron micrographs is
not easy (16). In seminal
work, Landh (17) developed the
method of direct template correlative matching, a technique that unequivocally
assesses the presence of cubic membranes in biological specimens
(16). Cubic phases adopt
mathematically well defined three-dimensional configurations whose
two-dimensional analogs have been derived
(4,
17). In direct template
correlative matching, electron micrographs are matched to these analogs. Cubic
cell membrane geometries and in vitro cubic phases of purified lipid
mixtures do differ in their lattice parameters; however, such deviations are
thought to relate to differences in water activity and lipid to protein ratios
(10,
14,
18). Direct template
correlative matching has revealed thousands of examples of cellular cubic
membranes in a broad survey of electron micrographs ranging from protozoa to
human cells (14,
17) and, more recently, in the
mitochondria of amoeba (19)
and in subcellular membrane compartments associated with severe acute
respiratory syndrome virus
(20). Analysis of cellular
cubic membranes has also been furthered by the development of EM tomography
that confirmed the presence of cubic bilayers in the mitochondrial membranes
of amoeba (21,
22).Although it is now clear that cubic membranes can exist in living cells,
the generation of such architecture would appear tightly regulated, as
evidenced by the dominance of lamellar bilayers in biology. In this light, we
examined the capability and implications of generating cubic membranes in the
endoplasmic reticulum (ER) of mammalian tissue culture cells. The ER is a
spatially interconnected complex consisting of two domains, the nuclear
envelope and the peripheral ER
(23–26).
The nuclear envelope surrounds the nucleus and is composed of two continuous
sheets of membranes, an inner and outer nuclear membrane connected to each
other at nuclear pores. The peripheral ER constitutes a network of branching
trijunctional tubules that are continuous with membrane sheet regions that
occur in closer proximity to the nucleus. Recently it has been suggested that
the classical morphological definition of rough ER (ribosome-studded) and
smooth ER (ribosome-free) may correspond to sheet-like and tubular ER domains,
respectively (27). The ER has
a strong potential for cubic architectures, as demonstrated by the fact that
the majority of cubic cell membranes in the EM record come from ER-derived
structures (14,
17). Furthermore, ER cubic
symmetries are an inducible class of organized smooth ER (OSER), a definition
collectively referring to ordered smooth ER membranes (=stacked cisternae on
the outer nuclear membrane, also called Karmelle
(28–30),
packed sinusoidal ER (31),
concentric membrane whorls
(30,
32–34),
and arrays of crystalloid ER
(35–37)).
Specifically, weak homotypic interactions between membrane proteins produce
both a whorled and a sinusoidal OSER phenotype
(38), the latter exhibiting a
cubic symmetry (16,
39).We were able to produce OSER with cubic membrane morphology via induction
of homo-dimerization of artificial membrane proteins. Interestingly, the
resultant cubic membrane architecture was removed from the ER system by
incorporation into large autophagic vacuoles. To assess whether these cubic
symmetries were favored in the absence of cellular energy, we depleted ATP. To
our surprise, the cells responded by forming large domains of tubulated
membrane, suggesting that a cubic symmetry was not the preferred conformation
of the system. Our results suggest that whereas the endoplasmic reticulum is
capable of adopting cubic symmetries, both the inherent properties of the ER
system and active cellular mechanisms, such as autophagy, can tightly control
their appearance. 相似文献
16.
17.
18.
John W. Hardin Francis E. Reyes Robert T. Batey 《The Journal of biological chemistry》2009,284(22):15317-15324
In archaea and eukarya, box C/D ribonucleoprotein (RNP) complexes are
responsible for 2′-O-methylation of tRNAs and rRNAs. The
archaeal box C/D small RNP complex requires a small RNA component (sRNA)
possessing Watson-Crick complementarity to the target RNA along with three
proteins: L7Ae, Nop5p, and fibrillarin. Transfer of a methyl group from
S-adenosylmethionine to the target RNA is performed by fibrillarin,
which by itself has no affinity for the sRNA-target duplex. Instead, it is
targeted to the site of methylation through association with Nop5p, which in
turn binds to the L7Ae-sRNA complex. To understand how Nop5p serves as a
bridge between the targeting and catalytic functions of the box C/D small RNP
complex, we have employed alanine scanning to evaluate the interaction between
the Pyrococcus horikoshii Nop5p domain and an L7Ae box C/D RNA
complex. From these data, we were able to construct an isolated RNA-binding
domain (Nop-RBD) that folds correctly as demonstrated by x-ray crystallography
and binds to the L7Ae box C/D RNA complex with near wild type affinity. These
data demonstrate that the Nop-RBD is an autonomously folding and functional
module important for protein assembly in a number of complexes centered on the
L7Ae-kinkturn RNP.Many biological RNAs require extensive modification to attain full
functionality in the cell (1).
Currently there are over 100 known RNA modification types ranging from small
functional group substitutions to the addition of large multi-cyclic ring
structures (2). Transfer RNA,
one of many functional RNAs targeted for modification
(3-6),
possesses the greatest modification type diversity, many of which are
important for proper biological function
(7). Ribosomal RNA, on the
other hand, contains predominantly two types of modified nucleotides:
pseudouridine and 2′-O-methylribose
(8). The crystal structures of
the ribosome suggest that these modifications are important for proper folding
(9,
10) and structural
stabilization (11) in
vivo as evidenced by their strong tendency to localize to regions
associated with function (8,
12,
13). These roles have been
verified biochemically in a number of cases
(14), whereas newly emerging
functional modifications are continually being investigated.Box C/D ribonucleoprotein
(RNP)3 complexes serve
as RNA-guided site-specific 2′-O-methyltransferases in both
archaea and eukaryotes (15,
16) where they are referred to
as small RNP complexes and small nucleolar RNPs, respectively. Target RNA
pairs with the sRNA guide sequence and is methylated at the 2′-hydroxyl
group of the nucleotide five bases upstream of either the D or D′ box
motif of the sRNA (Fig. 1,
star) (17,
18). In archaea, the internal
C′ and D′ motifs generally conform to a box C/D consensus sequence
(19), and each sRNA contains
two guide regions ∼12 nucleotides in length
(20). The bipartite
architecture of the RNP potentially enables the complex to methylate two
distinct RNA targets (21) and
has been shown to be essential for site-specific methylation
(22).Open in a separate windowFIGURE 1.Organization of the archaeal box C/D complex. The protein components
of this RNP are L7Ae, Nop5p, and fibrillarin, which together bind a box C/D
sRNA. The regions of the Box C/D sRNA corresponding to the conserved C, D,
C′, and D′ boxes are labeled. The target RNA binds the sRNA
through Watson-Crick pairing and is methylated by fibrillarin at the fifth
nucleotide from the D/D′ boxes (star).In addition to the sRNA, the archaeal box C/D complex requires three
proteins for activity (23):
the ribosomal protein L7Ae
(24,
25), fibrillarin, and the
Nop56/Nop58 homolog Nop5p (Fig.
1). L7Ae binds to both box C/D and the C′/D′ motifs
(26), which respectively
comprise kink-turn (27) or
k-loop structures (28), to
initiate the assembly of the RNP
(29,
30). Fibrillarin performs the
methyl group transfer from the cofactor S-adenosylmethionine to the
target RNA
(31-33).
For this to occur, the active site of fibrillarin must be positioned precisely
over the specific 2′-hydroxyl group to be methylated. Although
fibrillarin methylates this functional group in the context of a Watson-Crick
base-paired helix (guide/target), it has little to no binding affinity for
double-stranded RNA or for the L7Ae-sRNA complex
(22,
26,
33,
34). Nop5p serves as an
intermediary protein bringing fibrillarin to the complex through its
association with both the L7Ae-sRNA complex and fibrillarin
(22). Along with its role as
an intermediary between fibrillarin and the L7Ae-sRNA complex, Nop5p possesses
other functions not yet fully understood. For example, Nop5p self-dimerizes
through a coiled-coil domain
(35) that in most archaea and
eukaryotic homologs includes a small insertion sequence of unknown function
(36,
37). However, dimerization and
fibrillarin binding have been shown to be mutually exclusive in
Methanocaldococcus jannaschii Nop5p, potentially because of the
presence of this insertion sequence
(36). Thus, whether Nop5p is a
monomer or a dimer in the active RNP is still under debate.In this study, we focus our attention on the Nop5p protein to investigate
its interaction with a L7Ae box C/D RNA complex because both the
fibrillarin-Nop5p and the L7Ae box C/D RNA interfaces are known from crystal
structures (29,
35,
38). Individual residues on
the surface of a monomeric form of Nop5p (referred to as mNop5p)
(22) were mutated to alanine,
and the effect on binding affinity for a L7Ae box C/D motif RNA complex was
assessed through the use of electrophoretic mobility shift assays. These data
reveal that residues important for binding cluster within the highly conserved
NOP domain (39,
40). To demonstrate that this
domain is solely responsible for the affinity of Nop5p for the preassembled
L7Ae box C/D RNA complex, we expressed and purified it in isolation from the
full Nop5p protein. The isolated Nop-RBD domain binds to the L7Ae box C/D RNA
complex with nearly wild type affinity, demonstrating that the Nop-RBD is
truly an autonomously folding and functional module. Comparison of our data
with the crystal structure of the homologous spliceosomal hPrp31-15.5K
protein-U4 snRNA complex (41)
suggests the adoption of a similar mode of binding, further supporting a
crucial role for the NOP domain in RNP complex assembly. 相似文献
19.
Kelvin B. Luther Hermann Schindelin Robert S. Haltiwanger 《The Journal of biological chemistry》2009,284(5):3294-3305
The Notch receptor is critical for proper development where it orchestrates
numerous cell fate decisions. The Fringe family of
β1,3-N-acetylglucosaminyltransferases are regulators of this
pathway. Fringe enzymes add N-acetylglucosamine to O-linked
fucose on the epidermal growth factor repeats of Notch. Here we have analyzed
the reaction catalyzed by Lunatic Fringe (Lfng) in detail. A mutagenesis
strategy for Lfng was guided by a multiple sequence alignment of Fringe
proteins and solutions from docking an epidermal growth factor-like
O-fucose acceptor substrate onto a homology model of Lfng. We
targeted three main areas as follows: residues that could help resolve where
the fucose binds, residues in two conserved loops not observed in the
published structure of Manic Fringe, and residues predicted to be involved in
UDP-N-acetylglucosamine (UDP-GlcNAc) donor specificity. We utilized a
kinetic analysis of mutant enzyme activity toward the small molecule acceptor
substrate 4-nitrophenyl-α-l-fucopyranoside to judge their
effect on Lfng activity. Our results support the positioning of
O-fucose in a specific orientation to the catalytic residue. We also
found evidence that one loop closes off the active site coincident with, or
subsequent to, substrate binding. We propose a mechanism whereby the ordering
of this short loop may alter the conformation of the catalytic aspartate.
Finally, we identify several residues near the UDP-GlcNAc-binding site, which
are specifically permissive toward UDP-GlcNAc utilization.Defects in Notch signaling have been implicated in numerous human diseases,
including multiple sclerosis
(1), several forms of cancer
(2-4),
cerebral autosomal dominant arteriopathy with sub-cortical infarcts and
leukoencephalopathy (5), and
spondylocostal dysostosis
(SCD)3
(6-8).
The transmembrane Notch signaling receptor is activated by members of the DSL
(Delta, Serrate, Lag2) family of ligands
(9,
10). In the endoplasmic
reticulum, O-linked fucose glycans are added to the epidermal growth
factor-like (EGF) repeats of the Notch extracellular domain by protein
O-fucosyltransferase 1
(11-13).
These O-fucose monosaccharides can be elongated in the Golgi
apparatus by three highly conserved
β1,3-N-acetylglucosaminyltransferases of the Fringe family
(Lunatic (Lfng), Manic (Mfng), and Radical Fringe (Rfng) in mammals)
(14-16).
The formation of this GlcNAc-β1,3-Fuc-α1,
O-serine/threonine disaccharide is necessary and sufficient for
subsequent elongation to a tetrasaccharide
(15,
19), although elongation past
the disaccharide in Drosophila is not yet clear
(20,
21). Elongation of
O-fucose by Fringe is known to potentiate Notch signaling from Delta
ligands and inhibit signaling from Serrate ligands
(22). Delta ligands are termed
Delta-like (Delta-like1, -2, and -4) in mammals, and the homologs of Serrate
are known as Jagged (Jagged1 and -2) in mammals. The effects of Fringe on
Drosophila Notch can be recapitulated in Notch ligand in
vitro binding assays using purified components, suggesting that the
elongation of O-fucose by Fringe alters the binding of Notch to its
ligands (21). Although Fringe
also appears to alter Notch-ligand interactions in mammals, the effects of
elongation of the glycan past the O-fucose monosaccharide is more
complicated and appears to be cell type-, receptor-, and ligand-dependent (for
a recent review see Ref.
23).The Fringe enzymes catalyze the transfer of GlcNAc from the donor substrate
UDP-α-GlcNAc to the acceptor fucose, forming the GlcNAc-β1,3-Fuc
disaccharide
(14-16).
They belong to the GT-A-fold of inverting glycosyltransferases, which includes
N-acetylglucosaminyltransferase I and β1,4-galactosyltransferase
I (17,
18). The mechanism is presumed
to proceed through the abstraction of a proton from the acceptor substrate by
a catalytic base (Asp or Glu) in the active site. This creates a nucleophile
that attacks the anomeric carbon of the nucleotide-sugar donor, inverting its
configuration from α (on the nucleotide sugar) to β (in the
product) (24,
25). The enzyme then releases
the acceptor substrate modified with a disaccharide and UDP. The Mfng
structure (26) leaves little
doubt as to the identity of the catalytic residue, which in all likelihood is
aspartate 289 in mouse Lfng (we will use numbering for mouse Lunatic Fringe
throughout, unless otherwise stated). The structure of Mfng with UDP-GlcNAc
soaked into the crystals (26)
showed density only for the UDP portion of the nucleotide-sugar donor and no
density for two loops flanking either side of the active site. The presence of
flexible loops that become ordered upon substrate binding is a common
observation with glycosyltransferases in the GT-A fold family
(18,
25). Density for the entire
donor was observed in the structure of rabbit
N-acetylglucosaminyltransferase I
(27). In this case, ordering
of a previously disordered loop upon UDP-GlcNAc binding may have contributed
to increased stability of the donor. In the case of bovine
β1,4-galactosyltransferase I, a section of flexible random coil from the
apo-structure was observed to change its conformation to α-helical upon
donor substrate binding (28).
Both loops in Lfng are highly conserved, and we have mutated a number of
residues in each to test the hypothesis that they interact with the
substrates. The mutagenesis strategy was also guided by docking of an
EGF-O-fucose acceptor substrate into the active site of the Lfng
model as well as comparison of the Lfng model with a homology model of the
β1,3-glucosyltransferase (β3GlcT) that modifies O-fucose on
thrombospondin type 1 repeats
(29,
30). The β3GlcT is
predicted to be a GT-A fold enzyme related to the Fringe family
(17,
18,
29). 相似文献
20.
Dong Han Hamid Y. Qureshi Yifan Lu Hemant K. Paudel 《The Journal of biological chemistry》2009,284(20):13422-13433
In Alzheimer disease (AD), frontotemporal dementia and parkinsonism linked
to chromosome 17 (FTDP-17) and other tauopathies, tau accumulates and forms
paired helical filaments (PHFs) in the brain. Tau isolated from PHFs is
phosphorylated at a number of sites, migrates as ∼60-, 64-, and 68-kDa
bands on SDS-gel, and does not promote microtubule assembly. Upon
dephosphorylation, the PHF-tau migrates as ∼50–60-kDa bands on
SDS-gels in a manner similar to tau that is isolated from normal brain and
promotes microtubule assembly. The site(s) that inhibits microtubule
assembly-promoting activity when phosphorylated in the diseased brain is not
known. In this study, when tau was phosphorylated by Cdk5 in vitro,
its mobility shifted from ∼60-kDa bands to ∼64- and 68-kDa bands in a
time-dependent manner. This mobility shift correlated with phosphorylation at
Ser202, and Ser202 phosphorylation inhibited tau
microtubule-assembly promoting activity. When several tau point mutants were
analyzed, G272V, P301L, V337M, and R406W mutations associated with FTDP-17,
but not nonspecific mutations S214A and S262A, promoted Ser202
phosphorylation and mobility shift to a ∼68-kDa band. Furthermore,
Ser202 phosphorylation inhibited the microtubule assembly-promoting
activity of FTDP-17 mutants more than of WT. Our data indicate that FTDP-17
missense mutations, by promoting phosphorylation at Ser202, inhibit
the microtubule assembly-promoting activity of tau in vitro,
suggesting that Ser202 phosphorylation plays a major role in the
development of NFT pathology in AD and related tauopathies.Neurofibrillary tangles
(NFTs)4 and senile
plaques are the two characteristic neuropathological lesions found in the
brains of patients suffering from Alzheimer disease (AD). The major fibrous
component of NFTs are paired helical filaments (PHFs) (for reviews see Refs.
1–3).
Initially, PHFs were found to be composed of a protein component referred to
as “A68” (4).
Biochemical analysis reveled that A68 is identical to the
microtubule-associated protein, tau
(4,
5). Some characteristic
features of tau isolated from PHFs (PHF-tau) are that it is abnormally
hyperphosphorylated (phosphorylated on more sites than the normal brain tau),
does not bind to microtubules, and does not promote microtubule assembly
in vitro. Upon dephosphorylation, PHF-tau regains its ability to bind
to and promote microtubule assembly
(6,
7). Tau hyperphosphorylation is
suggested to cause microtubule instability and PHF formation, leading to NFT
pathology in the brain
(1–3).PHF-tau is phosphorylated on at least 21 proline-directed and
non-proline-directed sites (8,
9). The individual contribution
of these sites in converting tau to PHFs is not entirely clear. However, some
sites are only partially phosphorylated in PHFs
(8), whereas phosphorylation on
specific sites inhibits the microtubule assembly-promoting activity of tau
(6,
10). These observations
suggest that phosphorylation on a few sites may be responsible and sufficient
for causing tau dysfunction in AD.Tau purified from the human brain migrates as ∼50–60-kDa bands on
SDS-gel due to the presence of six isoforms that are phosphorylated to
different extents (2). PHF-tau
isolated from AD brain, on the other hand, displays ∼60-, 64-, and 68
kDa-bands on an SDS-gel (4,
5,
11). Studies have shown that
∼64- and 68-kDa tau bands (the authors have described the ∼68-kDa tau
band as an ∼69-kDa band in these studies) are present only in brain areas
affected by NFT degeneration
(12,
13). Their amount is
correlated with the NFT densities at the affected brain regions. Moreover, the
increase in the amount of ∼64- and 68-kDa band tau in the brain correlated
with a decline in the intellectual status of the patient. The ∼64- and
68-kDa tau bands were suggested to be the pathological marker of AD
(12,
13). Biochemical analyses
determined that ∼64- and 68-kDa bands are hyperphosphorylated tau, which
upon dephosphorylation, migrated as normal tau on SDS-gel
(4,
5,
11). Tau sites involved in the
tau mobility shift to ∼64- and 68-kDa bands were suggested to have a role
in AD pathology (12,
13). It is not known whether
phosphorylation at all 21 PHF-sites is required for the tau mobility shift in
AD. However, in vitro the tau mobility shift on SDS-gel is sensitive
to phosphorylation only on some sites
(6,
14). It is therefore possible
that in the AD brain, phosphorylation on some sites also causes a tau mobility
shift. Identification of such sites will significantly enhance our knowledge
of how NFT pathology develops in the brain.PHFs are also the major component of NFTs found in the brains of patients
suffering from a group of neurodegenerative disorders collectively called
tauopathies (2,
11). These disorders include
frontotemporal dementia and Parkinsonism linked to chromosome 17 (FTDP-17),
corticobasal degeneration, progressive supranuclear palsy, and Pick disease.
Each PHF-tau isolated from autopsied brains of patients suffering from various
tauopathies is hyperphosphorylated, displays ∼60-, 64-, and 68-kDa bands
on SDS-gel, and is incapable of binding to microtubules. Upon
dephosphorylation, the above referenced PHF-tau migrates as a normal tau on
SDS-gel, binds to microtubules, and promotes microtubule assembly
(2,
11). These observations
suggest that the mechanisms of NFT pathology in various tauopathies may be
similar and the phosphorylation-dependent mobility shift of tau on SDS-gel may
be an indicator of the disease. The tau gene is mutated in familial FTDP-17,
and these mutations accelerate NFT pathology in the brain
(15–18).
Understanding how FTDP-17 mutations promote tau phosphorylation can provide a
better understanding of how NFT pathology develops in AD and various
tauopathies. However, when expressed in CHO cells, G272V, R406W, V337M, and
P301L tau mutations reduce tau phosphorylation
(19,
20). In COS cells, although
G272V, P301L, and V337M mutations do not show any significant affect, the
R406W mutation caused a reduction in tau phosphorylation
(21,
22). When expressed in SH-SY5Y
cells subsequently differentiated into neurons, the R406W, P301L, and V337M
mutations reduce tau phosphorylation
(23). In contrast, in
hippocampal neurons, R406W increases tau phosphorylation
(24). When phosphorylated by
recombinant GSK3β in vitro, the P301L and V337M mutations do not
have any effect, and the R406W mutation inhibits phosphorylation
(25). However, when incubated
with rat brain extract, all of the G272V, P301L, V337M, and R406W mutations
stimulate tau phosphorylation
(26). The mechanism by which
FTDP-17 mutations promote tau phosphorylation leading to development of NFT
pathology has remained unclear.Cyclin-dependent protein kinase 5 (Cdk5) is one of the major kinases that
phosphorylates tau in the brain
(27,
28). In this study, to
determine how FTDP-17 missense mutations affect tau phosphorylation, we
phosphorylated four FTDP-17 tau mutants (G272V, P301L, V337M, and R406W) by
Cdk5. We have found that phosphorylation of tau by Cdk5 causes a tau mobility
shift to ∼64- and 68 kDa-bands. Although the mobility shift to a
∼64-kDa band is achieved by phosphorylation at Ser396/404 or
Ser202, the mobility shift to a 68-kDa band occurs only in response
to phosphorylation at Ser202. We show that in
vitro, FTDP-17 missense mutations, by promoting phosphorylation at
Ser202, enhance the mobility shift to ∼64- and 68-kDa bands and
inhibit the microtubule assembly-promoting activity of tau. Our data suggest
that Ser202 phosphorylation is the major event leading to NFT
pathology in AD and related tauopathies. 相似文献