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Leonard Kaysser Liane Lutsch Stefanie Siebenberg Emmanuel Wemakor Bernd Kammerer Bertolt Gust 《The Journal of biological chemistry》2009,284(22):14987-14996
Caprazamycins are potent anti-mycobacterial liponucleoside antibiotics
isolated from Streptomyces sp. MK730-62F2 and belong to the
translocase I inhibitor family. Their complex structure is derived from
5′-(β-O-aminoribosyl)-glycyluridine and comprises a unique
N-methyldiazepanone ring. The biosynthetic gene cluster has been
identified, cloned, and sequenced, representing the first gene cluster of a
translocase I inhibitor. Sequence analysis revealed the presence of 23 open
reading frames putatively involved in export, resistance, regulation, and
biosynthesis of the caprazamycins. Heterologous expression of the gene cluster
in Streptomyces coelicolor M512 led to the production of
non-glycosylated bioactive caprazamycin derivatives. A set of gene deletions
validated the boundaries of the cluster and inactivation of cpz21
resulted in the accumulation of novel simplified liponucleoside antibiotics
that lack the 3-methylglutaryl moiety. Therefore, Cpz21 is assigned to act as
an acyltransferase in caprazamycin biosynthesis. In vivo and in
silico analysis of the caprazamycin biosynthetic gene cluster allows a
first proposal of the biosynthetic pathway and provides insights into the
biosynthesis of related uridyl-antibiotics.Caprazamycins
(CPZs)2
(Fig. 1, 1) are
liponucleoside antibiotics isolated from a fermentation broth of
Streptomyces sp. MK730-62F2
(1,
2). They show excellent
activity in vitro against Gram-positive bacteria, in particular
against the genus Mycobacterium including Mycobacterium
intracellulare, Mycobacterium avium, and Mycobacterium
tuberculosis (3). In a
pulmonary mouse model with M. tuberculosis H37Rv, administration of
caprazamycin B exhibited a therapeutic effect but no significant toxicity
(4). Structural elucidation
(2) revealed a complex and
unique composition of elements the CPZs share only with the closely related
liposidomycins (LPMs, 2)
(5). The core skeleton is the
(+)-caprazol (5)
composed of an N-alkylated
5′-(β-O-aminoribosyl)-glycyluridine, also known from
FR-900493 (6)
(6) and the muraymycins
(7)
(7), which is cyclized to form
a rare diazepanone ring. Attached to the 3′″-OH are β-hydroxy
fatty acids of different chain length resulting in CPZs A–G
(1). They differ from
the LPMs in the absence of a sulfate group at the 2″-position of the
aminoribose and the presence of a permethylated l-rhamnose
β-glycosidically linked to the 3-methylglutaryl (3-MG) moiety.Open in a separate windowFIGURE 1.Nucleoside antibiotics of the translocase I inhibitor family.The LPMs have been shown to inhibit biosynthesis of the bacterial cell wall
by targeting the formation of lipid I
(8). The CPZs are expected to
act in the same way and are assigned to the growing number of translocase I
inhibitors that include other nucleoside antibiotics, like the tunicamycins
and mureidomycins (9). During
peptidoglycan formation, translocase I catalyzes the transfer of
UDP-MurNAc-pentapeptide to the undecaprenyl phosphate carrier to
generate lipid I (10). This
reaction is considered an unexploited and promising target for new
anti-infective drugs (11).Recent investigations indicate that the 3″-OH group
(12), the amino group of the
aminoribosyl-glycyluridine, and an intact uracil moiety
(13) are essential for the
inhibition of the Escherichia coli translocase I MraY. The chemical
synthesis of the (+)-caprazol
(5) was recently
accomplished (14), however,
this compound only shows weak antibacterial activity. In contrast, the
acylated compounds 3 and 4 exhibit strong growth inhibition of
mycobacteria, suggesting a potential role of the fatty acid side chain in
penetration of the bacterial cell
(15,
16). Apparently, the
acyl-caprazols (4)
represent the most simplified antibiotically active liponucleosides and a good
starting point for further optimization of this class of potential
therapeutics.Although chemical synthesis and biological activity of CPZs and LPMs has
been studied in some detail, their biosynthesis remains speculative and only
few data exists about the formation of other translocase I inhibitors
(17,
18). Nevertheless, we assume
that the CPZ biosynthetic pathway is partially similar to that of LPMs,
FR-90043 (6), and
muraymycins (7) and
presents a model for the comprehension and manipulation of liponucleoside
formation. Considering the unique structural features of the CPZs we also
expect some unusual biotransformations to be involved in the formation of,
e.g. the (+)-caprazol.Here we report the identification and analysis of the CPZ gene cluster, the
first cluster of a translocase I inhibitor. A set of gene disruption
experiments provide insights into the biosynthetic origin of the CPZs and
moreover, heterologous expression of the gene cluster allows the generation of
novel bioactive derivatives by pathway engineering. 相似文献
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.
5.
6.
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
7.
Graham H. Diering John Church Masayuki Numata 《The Journal of biological chemistry》2009,284(20):13892-13903
NHE5 is a brain-enriched Na+/H+ exchanger that
dynamically shuttles between the plasma membrane and recycling endosomes,
serving as a mechanism that acutely controls the local pH environment. In the
current study we show that secretory carrier membrane proteins (SCAMPs), a
group of tetraspanning integral membrane proteins that reside in multiple
secretory and endocytic organelles, bind to NHE5 and co-localize predominantly
in the recycling endosomes. In vitro protein-protein interaction
assays revealed that NHE5 directly binds to the N- and C-terminal cytosolic
extensions of SCAMP2. Heterologous expression of SCAMP2 but not SCAMP5
increased cell-surface abundance as well as transporter activity of NHE5
across the plasma membrane. Expression of a deletion mutant lacking the
SCAMP2-specific N-terminal cytosolic domain, and a mini-gene encoding the
N-terminal extension, reduced the transporter activity. Although both Arf6 and
Rab11 positively regulate NHE5 cell-surface targeting and NHE5 activity across
the plasma membrane, SCAMP2-mediated surface targeting of NHE5 was reversed by
dominant-negative Arf6 but not by dominant-negative Rab11. Together, these
results suggest that SCAMP2 regulates NHE5 transit through recycling endosomes
and promotes its surface targeting in an Arf6-dependent manner.Neurons and glial cells in the central and peripheral nervous systems are
especially sensitive to perturbations of pH
(1). Many voltage- and
ligand-gated ion channels that control membrane excitability are sensitive to
changes in cellular pH
(1-3).
Neurotransmitter release and uptake are also influenced by cellular and
organellar pH (4,
5). Moreover, the intra- and
extracellular pH of both neurons and glia are modulated in a highly transient
and localized manner by neuronal activity
(6,
7). Thus, neurons and glia
require sophisticated mechanisms to finely tune ion and pH homeostasis to
maintain their normal functions.Na+/H+ exchangers
(NHEs)3 were
originally identified as a class of plasma membrane-bound ion transporters
that exchange extracellular Na+ for intracellular H+,
and thereby regulate cellular pH and volume. Since the discovery of NHE1 as
the first mammalian NHE (8),
eight additional isoforms (NHE2-9) that share 25-70% amino acid identity have
been isolated in mammals (9,
10). NHE1-5 commonly exhibit
transporter activity across the plasma membrane, whereas NHE6-9 are mostly
found in organelle membranes and are believed to regulate organellar pH in
most cell types at steady state
(11). More recently, NHE10 was
identified in human and mouse osteoclasts
(12,
13). However, the cDNA
encoding NHE10 shares only a low degree of sequence similarity with other
known members of the NHE gene family, raising the possibility that
this sodium-proton exchanger may belong to a separate gene family distantly
related to NHE1-9 (see Ref.
9).NHE gene family members contain 12 putative transmembrane domains
at the N terminus followed by a C-terminal cytosolic extension that plays a
role in regulation of the transporter activity by protein-protein interactions
and phosphorylation. NHEs have been shown to regulate the pH environment of
synaptic nerve terminals and to regulate the release of neurotransmitters from
multiple neuronal populations
(14-16).
The importance of NHEs in brain function is further exemplified by the
findings that spontaneous or directed mutations of the ubiquitously expressed
NHE1 gene lead to the progression of epileptic seizures, ataxia, and
increased mortality in mice
(17,
18). The progression of the
disease phenotype is associated with loss of specific neuron populations and
increased neuronal excitability. However, NHE1-null mice appear to
develop normally until 2 weeks after birth when symptoms begin to appear.
Therefore, other mechanisms may compensate for the loss of NHE1
during early development and play a protective role in the surviving neurons
after the onset of the disease phenotype.NHE5 was identified as a unique member of the NHE gene
family whose mRNA is expressed almost exclusively in the brain
(19,
20), although more recent
studies have suggested that NHE5 might be functional in other cell
types such as sperm (21,
22) and osteosarcoma cells
(23). Curiously, mutations
found in several forms of congenital neurological disorders such as
spinocerebellar ataxia type 4
(24-26)
and autosomal dominant cerebellar ataxia
(27-29)
have been mapped to chromosome 16q22.1, a region containing NHE5.
However, much remains unknown as to the molecular regulation of NHE5 and its
role in brain function.Very few if any proteins work in isolation. Therefore identification and
characterization of binding proteins often reveal novel functions and
regulation mechanisms of the protein of interest. To begin to elucidate the
biological role of NHE5, we have started to explore NHE5-binding proteins.
Previously, β-arrestins, multifunctional scaffold proteins that play a
key role in desensitization of G-protein-coupled receptors, were shown to
directly bind to NHE5 and promote its endocytosis
(30). This study demonstrated
that NHE5 trafficking between endosomes and the plasma membrane is regulated
by protein-protein interactions with scaffold proteins. More recently, we
demonstrated that receptor for activated
C-kinase 1 (RACK1), a scaffold protein that links
signaling molecules such as activated protein kinase C, integrins, and Src
kinase (31), directly
interacts with and activates NHE5 via integrin-dependent and independent
pathways (32). These results
further indicate that NHE5 is partly associated with focal adhesions and that
its targeting to the specialized microdomain of the plasma membrane may be
regulated by various signaling pathways.Secretory carrier membrane proteins (SCAMPs) are a family of evolutionarily
conserved tetra-spanning integral membrane proteins. SCAMPs are found in
multiple organelles such as the Golgi apparatus, trans-Golgi network,
recycling endosomes, synaptic vesicles, and the plasma membrane
(33,
34) and have been shown to
play a role in exocytosis
(35-38)
and endocytosis (39).
Currently, five isoforms of SCAMP have been identified in mammals. The
extended N terminus of SCAMP1-3 contain multiple Asn-Pro-Phe (NPF) repeats,
which may allow these isoforms to participate in clathrin coat assembly and
vesicle budding by binding to Eps15 homology (EH)-domain proteins
(40,
41). Further, SCAMP2 was shown
recently to bind to the small GTPase Arf6
(38), which is believed to
participate in traffic between the recycling endosomes and the cell surface
(42,
43). More recent studies have
suggested that SCAMPs bind to organellar membrane type NHE7
(44) and the serotonin
transporter SERT (45) and
facilitate targeting of these integral membrane proteins to specific
intracellular compartments. We show in the current study that SCAMP2 binds to
NHE5, facilitates the cell-surface targeting of NHE5, and elevates
Na+/H+ exchange activity at the plasma membrane, whereas
expression of a SCAMP2 deletion mutant lacking the N-terminal domain
containing the NPF repeats suppresses the effect. Further we show that this
activity of SCAMP2 requires an active form of a small GTPase Arf6, but not
Rab11. We propose a model in which SCAMPs bind to NHE5 in the endosomal
compartment and control its cell-surface abundance via an Arf6-dependent
pathway. 相似文献
8.
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
9.
Tushar K. Beuria Srinivas Mullapudi Eugenia Mileykovskaya Mahalakshmi Sadasivam William Dowhan William Margolin 《The Journal of biological chemistry》2009,284(21):14079-14086
Cytokinesis in bacteria depends upon the contractile Z ring, which is
composed of dynamic polymers of the tubulin homolog FtsZ as well as other
membrane-associated proteins such as FtsA, a homolog of actin that is required
for membrane attachment of the Z ring and its subsequent constriction. Here we
show that a previously characterized hypermorphic mutant FtsA (FtsA*)
partially disassembled FtsZ polymers in vitro. This effect was
strictly dependent on ATP or ADP binding to FtsA* and occurred at
substoichiometric levels relative to FtsZ, similar to cellular levels.
Nucleotide-bound FtsA* did not affect FtsZ GTPase activity or the critical
concentration for FtsZ assembly but was able to disassemble preformed FtsZ
polymers, suggesting that FtsA* acts on FtsZ polymers. Microscopic examination
of the inhibited FtsZ polymers revealed a transition from long, straight
polymers and polymer bundles to mainly short, curved protofilaments. These
results indicate that a bacterial actin, when activated by adenine
nucleotides, can modify the length distribution of bacterial tubulin polymers,
analogous to the effects of actin-depolymerizing factor/cofilin on
F-actin.Bacterial cell division requires a large number of proteins that colocalize
to form a putative protein machine at the cell membrane
(1). This machine, sometimes
called the divisome, recruits enzymes to synthesize the septum cell wall and
to initiate and coordinate the invagination of the cytoplasmic membrane (and
in Gram-negative bacteria, the outer membrane). The most widely conserved and
key protein for this process is FtsZ, a homolog of tubulin that forms a ring
structure called the Z ring, which marks the site of septum formation
(2,
3). Like tubulin, FtsZ
assembles into filaments with GTP but does not form microtubules
(4). The precise assembly state
and conformation of these FtsZ filaments at the division ring is not clear,
although recent electron tomography work suggests that the FtsZ ring consists
of multiple short filaments tethered to the membrane at discrete junctures
(5), which may represent points
along the filaments bridged by membrane anchor proteins.In Escherichia coli, two of these anchor proteins are known. One
of these, ZipA, is not well conserved but is an essential protein in E.
coli. ZipA binds to the C-terminal tail of FtsZ
(6–8),
and purified ZipA promotes bundling of FtsZ filaments in vitro
(9,
10). The other, FtsA, is also
essential in E. coli and is more widely conserved among bacterial
species. FtsA is a member of the HSP70/actin superfamily
(11,
12), and like ZipA, it
interacts with the C-terminal tail of FtsZ
(7,
13–15).
FtsA can self-associate (16,
17) and bind ATP
(12,
18), but reports of ATPase
activity vary, with Bacillus subtilis FtsA having high activity
(19) and Streptococcus
pneumoniae FtsA exhibiting no detectable activity
(20). There are no reports of
any other in vitro activities of FtsA, including effects on FtsZ
assembly.Understanding how FtsA affects FtsZ assembly is important because FtsA has
a number of key activities in the cell. It is required for recruitment of a
number of divisome proteins
(21,
22) and helps to tether the Z
ring to the membrane via a C-terminal membrane-targeting sequence
(23). FtsA, like ZipA and
other divisome proteins, is necessary to activate the contraction of the Z
ring (24,
25). In E. coli, the
FtsA:FtsZ ratio is crucial for proper cell division, with either too high or
too low a ratio inhibiting septum formation
(26,
27). This ratio is roughly
1:5, with ∼700 molecules of FtsA and 3200 molecules of FtsZ per cell
(28), which works out to
concentrations of 1–2 and 5–10 μm, respectively.Another interesting property of FtsA is that single residue alterations in
the protein can result in significant enhancement of divisome activity. For
example, the R286W mutation of FtsA, also called FtsA*, can substitute for the
native FtsA and divide the cell. However, this mutant FtsA causes E.
coli cells to divide at less than 80% of their normal length
(29) and allows efficient
division of E. coli cells in the absence of ZipA
(30), indicating that it has
gain-of-function activity. FtsA* and other hypermorphic mutations such as
E124A and I143L can also increase division activity in cells lacking other
essential divisome components
(31–33).
The R286W and E124A mutants of FtsA also bypass the FtsA:FtsZ ratio rule,
allowing cell division to occur at higher ratios than with
WT2 FtsA. This may be
because the altered FtsA proteins self-associate more readily than WT FtsA,
which may cause different changes in FtsZ assembly state as compared with WT
FtsA (17,
34).In this study, we use an in vitro system with purified FtsZ and a
purified tagged version of FtsA* to elucidate the role of FtsA in activating
constriction of the Z ring in vivo. We show that FtsA*, at
physiological concentrations in the presence of ATP or ADP, has significant
effects on the assembly of FtsZ filaments. 相似文献
10.
11.
Isabel Molina-Ortiz Rub��n A. Bartolom�� Pablo Hern��ndez-Varas Georgina P. Colo Joaquin Teixid�� 《The Journal of biological chemistry》2009,284(22):15147-15157
Melanoma cells express the chemokine receptor CXCR4 that confers high
invasiveness upon binding to its ligand CXCL12. Melanoma cells at initial
stages of the disease show reduction or loss of E-cadherin expression, but
recovery of its expression is frequently found at advanced phases. We
overexpressed E-cadherin in the highly invasive BRO lung metastatic cell
melanoma cell line to investigate whether it could influence CXCL12-promoted
cell invasion. Overexpression of E-cadherin led to defective invasion of
melanoma cells across Matrigel and type I collagen in response to CXCL12. A
decrease in individual cell migration directionality toward the chemokine and
reduced adhesion accounted for the impaired invasion. A p190RhoGAP-dependent
inhibition of RhoA activation was responsible for the impairment in
chemokine-stimulated E-cadherin melanoma transfectant invasion. Furthermore,
we show that p190RhoGAP and p120ctn associated predominantly on the plasma
membrane of cells overexpressing E-cadherin, and that E-cadherin-bound p120ctn
contributed to RhoA inactivation by favoring p190RhoGAP-RhoA association.
These results suggest that melanoma cells at advanced stages of the disease
could have reduced metastatic potency in response to chemotactic stimuli
compared with cells lacking E-cadherin, and the results indicate that
p190RhoGAP is a central molecule controlling melanoma cell invasion.Cadherins are a family of Ca2+-dependent adhesion molecules that
mediate cell-cell contacts and are expressed in most solid tissues providing a
tight control of morphogenesis
(1,
2). Classical cadherins, such
as epithelial (E) cadherin, are found in adherens junctions, forming core
protein complexes with β-catenin, α-catenin, and p120 catenin
(p120ctn). Both β-catenin and p120ctn directly interact with E-cadherin,
whereas α-catenin associates with the complex through its binding to
β-catenin, providing a link with the actin cytoskeleton
(1,
2). E-cadherin is frequently
lost or down-regulated in many human tumors, coincident with morphological
epithelial to mesenchymal transition and acquisition of invasiveness
(3-6).Although melanoma only accounts for 5% of skin cancers, when metastasis
starts, it is responsible for 80% of deaths from skin cancers
(7). Melanocytes express
E-cadherin
(8-10),
but melanoma cells at early radial growth phase show a large reduction in the
expression of this cadherin, and surprisingly, expression has been reported to
be partially recovered by vertical growth phase and metastatic melanoma cells
(9,
11,
12).Trafficking of cancer cells from primary tumor sites to intravasation into
blood circulation and later to extravasation to colonize distant organs
requires tightly regulated directional cues and cell migration and invasion
that are mediated by chemokines, growth factors, and adhesion molecules
(13). Solid tumor cells
express chemokine receptors that provide guidance of these cells to organs
where their chemokine ligands are expressed, constituting a homing model
resembling the one used by immune cells to exert their immune surveillance
functions (14). Most solid
cancer cells express CXCR4, a receptor for the chemokine CXCL12 (also called
SDF-1), which is expressed in lungs, bone marrow, and liver
(15). Expression of CXCR4 in
human melanoma has been detected in the vertical growth phase and on regional
lymph nodes, which correlated with poor prognosis and increased mortality
(16,
17). Previous in vivo
experiments have provided evidence supporting a crucial role for CXCR4 in the
metastasis of melanoma cells
(18).Rho GTPases control the dynamics of the actin cytoskeleton during cell
migration (19,
20). The activity of Rho
GTPases is tightly regulated by guanine-nucleotide exchange factors
(GEFs),4 which
stimulate exchange of bound GDP by GTP, and inhibited by GTPase-activating
proteins (GAPs), which promote GTP hydrolysis
(21,
22), whereas guanine
nucleotide dissociation inhibitors (GDIs) appear to mediate blocking of
spontaneous activation (23).
Therefore, cell migration is finely regulated by the balance between GEF, GAP,
and GDI activities on Rho GTPases. Involvement of Rho GTPases in cancer is
well documented (reviewed in Ref.
24), providing control of both
cell migration and growth. RhoA and RhoC are highly expressed in colon,
breast, and lung carcinoma
(25,
26), whereas overexpression of
RhoC in melanoma leads to enhancement of cell metastasis
(27). CXCL12 activates both
RhoA and Rac1 in melanoma cells, and both GTPases play key roles during
invasion toward this chemokine
(28,
29).Given the importance of the CXCL12-CXCR4 axis in melanoma cell invasion and
metastasis, in this study we have addressed the question of whether changes in
E-cadherin expression on melanoma cells might affect cell invasiveness. We
show here that overexpression of E-cadherin leads to impaired melanoma cell
invasion to CXCL12, and we provide mechanistic characterization accounting for
the decrease in invasion. 相似文献
12.
13.
14.
15.
Ivana I. Knezevic Sanda A. Predescu Radu F. Neamu Matvey S. Gorovoy Nebojsa M. Knezevic Cordus Easington Asrar B. Malik Dan N. Predescu 《The Journal of biological chemistry》2009,284(8):5381-5394
It is known that platelet-activating factor (PAF) induces severe
endothelial barrier leakiness, but the signaling mechanisms remain unclear.
Here, using a wide range of biochemical and morphological approaches applied
in both mouse models and cultured endothelial cells, we addressed the
mechanisms of PAF-induced disruption of interendothelial junctions (IEJs) and
of increased endothelial permeability. The formation of interendothelial gaps
filled with filopodia and lamellipodia is the cellular event responsible for
the disruption of endothelial barrier. We observed that PAF ligation of its
receptor induced the activation of the Rho GTPase Rac1. Following PAF
exposure, both Rac1 and its guanine nucleotide exchange factor Tiam1 were
found associated with a membrane fraction from which they
co-immunoprecipitated with PAF receptor. In the same time frame with
Tiam1-Rac1 translocation, the junctional proteins ZO-1 and VE-cadherin were
relocated from the IEJs, and formation of numerous interendothelial gaps was
recorded. Notably, the response was independent of myosin light chain
phosphorylation and thus distinct from other mediators, such as histamine and
thrombin. The changes in actin status are driven by the PAF-induced localized
actin polymerization as a consequence of Rac1 translocation and activation.
Tiam1 was required for the activation of Rac1, actin polymerization,
relocation of junctional associated proteins, and disruption of IEJs. Thus,
PAF-induced IEJ disruption and increased endothelial permeability requires the
activation of a Tiam1-Rac1 signaling module, suggesting a novel therapeutic
target against increased vascular permeability associated with inflammatory
diseases.The endothelial barrier is made up of endothelial cells
(ECs)4 connected to
each other by interendothelial junctions (IEJs) consisting of protein
complexes organized as tight junctions (TJs) and adherens junctions (AJs). In
addition, the focal adhesion complex located at the basal plasma membrane
enables firm contact of ECs with the underlying basement membrane and also
contributes to the barrier function
(1-3).
The glycocalyx, the endothelial monolayer, and the basement membrane all
together constitute the vascular barrier.The structural integrity of the ECs along with their proper functionality
are the two most important factors controlling the tightness of the
endothelial barrier. Changes affecting these factors cause loss of barrier
restrictiveness and leakiness. Therefore, defining and understanding the
cellular and molecular mechanisms controlling these processes is of paramount
importance. Increased width of IEJs in response to permeability-increasing
mediators (4) regulates the
magnitude of transendothelial exchange of fluid and solutes. Disruption of
IEJs and the resultant barrier leakiness contribute to the genesis of diverse
pathological conditions, such as inflammation
(5), metastasis
(6,
7), and uncontrolled
angiogenesis (8,
9).Accumulated evidence demonstrated that IEJs changes are responsible for
increased or decreased vascular permeability, and the generally accepted
mechanism responsible for them was the myosin light chain (MLC)-mediated
contraction of ECs (5,
10). However, published
evidence showed that an increase in vascular permeability could be obtained
without a direct involvement of any contractile mechanism
(11-16).The main component of the vascular barrier, the ECs, has more than 10% of
their total protein represented by actin
(17), which under
physiological salt concentrations subsists as monomers (G-actin) and assembled
into filaments (F-actin). A large number of actin-interacting proteins may
modulate the assembly, disassembly, and organization of G-actin and of actin
filaments within a given cell type. Similar to the complexity of
actin-interacting proteins found in other cell types, the ECs utilize their
actin binding proteins to stabilize the endothelial monolayer in order to
efficiently function as a selective barrier
(11). In undisturbed ECs, the
actin microfilaments are organized as different networks with distinctive
functional and morphological characteristics: the peripheral filaments also
known as peripheral dense band (PDB), the cytoplasmic fibers identified as
stress fibers (SF), and the actin from the membrane cytoskeleton
(18). The peripheral web,
localized immediately under the membrane, is associated with (i) the luminal
plasmalemma (on the apical side), (ii) the IEJ complexes on the lateral
surfaces, and (iii) the focal adhesion complexes on the abluminal side (the
basal part) of polarized ECs. The SF reside inside the endothelial cytoplasm
and are believed to be directly connected with the plasmalemma proper on the
luminal as well as on the abluminal side of the cell. As described, the
endothelial actin cytoskeleton (specifically the SF) seems to be a stable
structure helping the cells to remain flat under flow
(19). It is also established
that the actin fibers participate in correct localization of different
junctional complexes while keeping them in place
(20). However, it was
suggested that the dynamic equilibrium between F- and G-actin might modulate
the tightness of endothelial barrier in response to different challenges
(13).Mediators effective at nanomolar concentrations or less that disrupt the
endothelial barrier and increase vascular permeability include C2 toxin of
Clostridium botulinum, vascular permeability factor, better known as
vascular endothelial growth factor, and PAF
(21). C2 toxin increases
endothelial permeability by ribosylating monomeric G-actin at Arg-177
(22). This results in the
impairment of actin polymerization
(23), followed by rounding of
ECs (16) and the disruption of
junctional integrity. Vascular permeability factor was shown to open IEJs by
redistribution of junctional proteins
(24,
25) and by interfering with
the equilibrium of actin pools
(26). PAF
(1-O-alkyl-2-acetyl-sn-glycero-3-phosphocoline), a naturally
synthesized phospholipid is active at 10-10 m or less
(27). PAF is synthesized by
and acts on a variety of cell types, including platelets
(28), neutrophils
(29), monocytes
(30), and ECs
(31). PAF-mediated activation
of ECs induced cell migration
(32), angiogenesis
(7), and vascular
hyperpermeability (33)
secondary to disassembly of IEJs
(34). The effects of PAF on
the endothelium are initiated through a G protein-coupled receptor (PAF-R)
localized at the plasmalemma, in a large endosomal compartment inside the cell
(34), and also in the nuclear
membrane (35). In ECs, PAF-R
was shown to signal through Gαq and downstream activation of
phospholipase C isozymes (PLCβ3 and PLCγ1),
and via cSrc (32,
36). Studies have shown that
PAF challenge induced endothelial actin cytoskeletal rearrangement
(37) and marked vascular
leakiness (38); however, the
signaling pathways have not been elucidated.Therefore, in the present study, we carried out a systematic analysis of
PAF-induced morphological and biochemical changes of endothelial barrier
in vivo and in cultured ECs. We found that the opening of endothelial
barrier and the increased vascular leakiness induced by PAF are the result of
a shift in actin pools without involvement of EC contraction, followed by a
redistribution of tight junctional associated protein ZO-1 and adherens
junctional protein VE-cadherin. 相似文献
16.
17.
18.
19.
Christopher P. Gayer Lakshmi S. Chaturvedi Shouye Wang David H. Craig Thomas Flanigan Marc D. Basson 《The Journal of biological chemistry》2009,284(4):2001-2011
The intestinal epithelium is repetitively deformed by shear, peristalsis,
and villous motility. Such repetitive deformation stimulates the proliferation
of intestinal epithelial cells on collagen or laminin substrates via ERK, but
the upstream mediators of this effect are poorly understood. We hypothesized
that the phosphatidylinositol 3-kinase (PI3K)/AKT cascade mediates this
mitogenic effect. PI3K, AKT, and glycogen synthase kinase-3β
(GSK-3β) were phosphorylated by 10 cycles/min strain at an average 10%
deformation, and pharmacologic blockade of these molecules or reduction by
small interfering RNA (siRNA) prevented the mitogenic effect of strain in
Caco-2 or IEC-6 intestinal epithelial cells. Strain MAPK activation required
PI3K but not AKT. AKT isoform-specific siRNA transfection demonstrated that
AKT2 but not AKT1 is required for GSK-3β phosphorylation and the strain
mitogenic effect. Furthermore, overexpression of AKT1 or an AKT chimera
including the PH domain and hinge region of AKT2 and the catalytic domain and
C-tail of AKT1 prevented strain activation of GSK-3β, but overexpression
of AKT2 or a chimera including the PH domain and hinge region of AKT1 and the
catalytic domain and C-tail of AKT2 did not. These data delineate a role for
PI3K, AKT2, and GSK-3β in the mitogenic effect of strain. PI3K is
required for both ERK and AKT2 activation, whereas AKT2 is sequentially
required for GSK-3β. Furthermore, AKT2 specificity requires its catalytic
domain and tail region. Manipulating this pathway may prevent mucosal atrophy
and maintain the mucosal barrier in conditions such as ileus, sepsis, and
prolonged fasting when peristalsis and villous motility are decreased and the
mucosal barrier fails.Mechanical forces are part of the normal intestinal epithelial environment.
Numerous different forces deform these cells including shear stress from
endoluminal chyme, bowel peristalsis, and villous motility
(1,
2). During normal bowel
function the mucosa is subjected to injury that must be repaired to maintain
the mucosal barrier (3,
4). Deformation patterns of the
bowel are altered in conditions such as prolonged fasting, post-surgical
ileus, and sepsis states, resulting in profoundly reduced mucosal deformation.
When such states are prolonged, proliferation slows, the mucosa becomes
atrophic, and bacterial translocation may ensue as the mucosal barrier of the
gut breaks down
(5–7).In vitro, repetitive deformation is trophic for intestinal
epithelial cells (8) cultured
on type I or type IV collagen or laminin. Human Caco-2 intestinal epithelial
cells (9), non-transformed rat
IEC-6 intestinal epithelial cells
(10), and primary human
intestinal epithelial cells isolated from surgical specimens
(11) proliferate more rapidly
in response to cyclic strain
(12) unless substantial
quantities of fibronectin are added to the media or matrix
(11) to mimic the acute phase
reaction of acute or chronic inflammation and injury. Cyclic strain also
stimulates proliferation in HCT 116 colon cancer cells
(13) and differentiation of
Caco-2 cells cultured on a collagen substrate
(9). This phenomenon has also
been observed in vivo
(14). Thus, repetitive
deformation may help to maintain the normal homeostasis of the gut mucosa
under non-inflammatory conditions. Previous work in our laboratory has
implicated Src, focal adhesion kinase, and the mitogen-activated protein
kinase (MAPK)2
extracellular signal-related kinase (ERK) in the mitogenic effect of strain
(10). Although p38 is also
activated in Caco-2 cells subjected to cyclic strain on a collagen matrix, its
activity is not required for the mitogenic effect of strain
(12).Although often the PI3K/AKT pathway is thought of as a parallel pathway to
the MAPK, this is not always the case. Protein kinase C isoenzymes
differentially modulate thrombin effect on MAPK-dependent retinal pigment
epithelial cell (RPE) proliferation, and it has been shown that PI3K or AKT
inhibition prevented thrombin-induced ERK activation and RPE proliferation
(15).PI3K, AKT, and glycogen synthase kinase (GSK), a downstream target of AKT
(16), have been implemented in
intestinal epithelial cell proliferation in numerous cell systems not
involving strain
(17–19)
including uncontrolled proliferation in gastrointestinal cancers
(20–22).
Mechanical forces activate this pathway as well. PI3K and AKT are required for
increased extracellular pressure to stimulate colon cancer cell adhesion
(23), although the pathway by
which pressure stimulates colon cancer cells in suspension differs from the
response of adherent intestinal epithelial cells to repetitive deformation
(24), and GSK is not involved
in this effect.3
Repetitive strain also stimulates vascular endothelial cell proliferation via
PI3K and AKT (25,
26), whereas respiratory
strain stimulates angiogenic responses via PI3K
(27). We, therefore,
hypothesized that the PI3K/AKT/GSK axis would be involved in the mitogenic
effects of repetitive deformation on a collagen matrix.To test this hypothesis, we used the Flexcell apparatus to rhythmically
deform Caco-2 intestinal epithelial cells. IEC-6 cells were used to confirm
key results. A frequency of 10 cycles per min was used, which is similar in
order of magnitude to the frequency that the intestinal mucosa might be
deformed by peristalsis or villous motility in vivo
(28,
29). Mechanical forces such as
repetitive deformation are likely cell-type and frequency-specific, as
different cell types respond to different frequencies. Vascular endothelial
cells respond to frequencies of 60–80 cycles/min
(25), whereas intestinal
epithelial cells may actually decrease proliferation in response to
frequencies of 5 cycles/min
(30). We characterized PI3K,
AKT, and GSK phosphorylation with strain, blocked these molecules
pharmacologically or by siRNA, and delineated the specificity of the AKT
effect using isozyme-specific siRNA and transfection of AKT1/2 chimeras. We
also characterized the interaction of this pathway with the activation of ERK
by strain, which has previously been implicated in the mitogenic response
(12). 相似文献