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J. Biol. Chem., Vol. 275, Issue 46, 36341-36349, November 17, 2000
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From the
Received for publication, April 19, 2000, and in revised form, August 10, 2000
Lysyl oxidase is an extracellular enzyme that
controls the maturation of collagen and elastin. Lysyl oxidase and
collagen III often show similar expression patterns in fibrotic
tissues. Therefore, we investigated the influence of lysyl oxidase
overexpression on the promoter activity of human COL3A1 gene. Our
results showed that when COS-7 cells overexpressed the mature form of
lysyl oxidase, the activity of the human COL3A1 promoter was increased
up to an average of 12 times when tested by luciferase reporter assay. The effect was specific, because other promoters were not affected. Moreover, lysyl oxidase effect was abolished by Lysyl oxidase (LOX)1
(protein-6-oxidase; EC 1.4.3.13) is the key enzyme that controls
collagen and elastin maturation (1, 2). It catalyzes the oxidative
deamination of peptidyl-lysine and hydroxylysine to
peptidyl- Another aspect regarding LOX activity refers to its putative cell
phenotype control and/or tumor suppressor activity. In many naturally
occurring and oncogene-induced tumors and cellular models, LOX is
down-regulated, whereas on the other hand is one of the main genes
induced in concomitance with the reversion process (14-18). In
particular, it seems that LOX is down-regulated in cells transformed by
ras or ras-related oncogenes, so that it was
first identified as a "ras recision gene" (rrg) (14, 15, 17). Moreover, LOX expression and activity are proved to be regulated by several growth factors, including
transforming growth factor- The localization of the enzyme is mainly extracellular, where its
acknowledged substrates are located. Yet, this does not imply that
regulation of ECM cross-linking is the only biochemical role of LOX. It
is not known whether LOX has substrates other than collagen and
elastin, although it has been proved that in vitro LOX can
catalyze the oxidative deamination in several peptides and complex
proteins (27, 28). Recently, it has been confirmed that processed LOX
is localized intracellularly and inside the nucleus as well. Therefore,
LOX might have an intracellular substrate(s), which would mediate its
ability to control the cell phenotype (29, 30).
Considering the critical role of collagen III in organ fibrosis
(31-34) and that its expression level changes are often preceded or
paralleled by similar modifications of LOX activity (17, 35, 36), we
investigated the effects of LOX overexpression on the activity of human
collagen III Cell Culture--
Monkey renal fibroblast COS-7 cell line was
obtained from American Type Culture Collection (Manassas, VA) and was
grown under humidified atmosphere of 5% CO2 at 37 °C in
Dulbecco's modified Eagle's medium supplemented with 10% fetal calf
serum, 1% glutamine, 100 µg/ml streptomycin, 100 units/ml
penicillin. Human skin fibroblasts were a primary culture and grown in
the same conditions as described above for COS-7 cells.
Expression Vectors--
The different fragments of COL3A1
promoter described in the text were derived from the IdF8 clone kindly
provided by Dr. F. Ramirez (Mt. Sinai School of Medicine, New York, NY)
both by endonuclease restriction and PCR amplification. The fragments
were then subcloned into pGL2-basic vector (Promega Inc., Madison, WI)
upstream the luciferase reporter gene (39). The construct pFV1 was
mutated into pFV1m by PCR, using overlapping primers containing the
mutated nucleotide sequence. The mutation, encompassing the region from
Lysyl oxidase coding sequence for the mature 32-kDa protein, obtained
by PCR, was previously cloned into pTrc-His vector (30). The fragment
NcoI-BglII including the poly-His tag with LOX
coding sequence was subcloned into pSG5 vector (kind gift of Dr. D. Guerini, Swiss Federal Institute of Technology, Zurich, Switzerland),
using a NcoI-EcoRI adapter. All sequences were
checked by restriction analysis and DNA sequencing (40).
Transient Transfections--
COS-7 cells were transfected with 4 µg of the indicated plasmids by DEAE-dextran method (41). Briefly,
for a 100-mm Petri dish 1-4 µg of each supercoiled plasmid
resuspended in 1.2 ml of Dulbecco's modified Eagle's medium
supplemented with 10% of NU-SerumTM, 1% glutamine, 100 µg/ml
streptomycin, 100 units/ml penicillin was added to the cells,
previously washed with phosphate-buffered saline. An equal volume of
the above medium buffered with 10 mM HEPES, pH 7.15, containing 1 mg/ml DEAE-dextran was then added to the dish. The cells
were incubated for 30 min at the usual growth conditions, and after the
addition of 6 ml of the above medium were incubated for 3 h more.
To improve the efficiency of the transfection, the medium added for the
second incubation contained also 100 µM chloroquine,
which inhibits the lysosomal degradation of the DNA. The incubation was
ended by aspirating the DNA/DEAE-dextran solution and washing the cells
for 3 min with phosphate-buffered saline containing 10% of dimethyl
sulfoxide. The cells were then incubated for 48 h with its normal
medium and at the normal growth conditions, before being processed for luciferase assay. To normalize each experiment for transfection efficiency, 1-2 µg of pCMV-lacZ expressing the Luciferase Assay Luciferase Assay--
Luciferase activity was
determined by measuring luminescence in a TD-20/20 luminometer (Turner
Designs, Sunnyvale, CA), according to the luciferase assay kit
(Promega) directions. The results were normalized on the basis of
Nuclear Extracts and Cellular Fractionation--
The cells,
previously washed with phosphate-buffered saline, were collected by
scraping with a rubber policeman. The cells were pelleted at 600 × g for 10 min and resuspended in 200 µl/100 mm plate of
20 mM HEPES, pH 7.9, 1 mM EDTA, 1 mM dithiotreitol, 0.5 mM phenylmethylsulfonyl
fluoride, 1 µg/ml each of leupeptin, pepstatin, and aprotinin, 1 mM sodium vanadate, 10 mM sodium fluoride and
kept at 4 °C for 15 min. The cell suspension was then added with
Electrophoresis Mobility Shift Assay--
The assay was
performed as described previously (43), using 2-5 µg of nuclear
extract proteins in a total volume of 20 µl containing 20 mM Tris-HCl, pH 7.5, 0.1 M NaCl, 0.35 mM dithiotreitol, 0.5 mM EDTA, 0.5 mM phenylmethylsulfonyl fluoride, 10% glycerol, and 0.5 µl of 2 mg/ml of double-stranded poly(dI-dC) (1 µg/reaction). Where
indicated the poly(dI-dC) was substituted with 5 µg/reaction of calf
thymus DNA (Sigma), heat denatured at 95 °C for 5 min, and then
rapidly cooled on ice. The sequences of the oligonucleotide used were
the following: 31, 5'-TAC TGC TGA GGG GAT GGG TGC GGC-3'; 11, 5'-AGG
GGC TGG AAA GTG AGG GAA GCC A-3'; and 414, 5'-TGG CTG AGT TTT ATG
ACG-3'. All oligonucleotides employed were labeled at their 5' ends
with [ Microcircle Construction--
To introduce the oligonucleotide
31 in a circular DNA structure, it was modified, adding at its ends
XbaI and PstI restriction sites and subsequentely
subcloned into pSK+ plasmid digested in the corresponding
restriction sites. After selection of the pSK+ clones
carrying the oligonucleotide 31 insert, the plasmid was cut in
EcoRI and PvuII restriction sites external to
oligonucleotide 31, and the released fragment was purified from 3%
agarose gel. Then the fragment was circularized by T4 ligation,
producing a 280-bp circularized DNA molecule (44). The circular product was purified again from agarose gel after digestion with Bal31 to
remove the remaining linear DNA. The obtained microcircles were used to
compete the binding of Ku to the oligonucleotide 31. Microcircles
obtained from wild type pSK+ (without oligonucleotide 31)
were used as negative control.
Protein Analysis--
Approximately 30 µg of proteins from the
indicated cell fractions were separated by SDS-PAGE on a 10% gel (45)
and blotted to a Hybond-Super C nitrocellulose membrane (Amersham
Pharmacia Biotech). The blots were probed with Omni-Probe/M21, an
anti-(His)6 tag polyclonal antibody (Santa Cruz Biotechnology Inc.,
Santa Cruz, CA) to detect recombinant LOX. To detect Ku80 and Ku70 in the indicated cell extracts, anti-Ku80 polyclonal (M-20) and anti-Ku70 polyclonal (C-19) antibodies (Santa Cruz Biotechnology Inc.) were used.
The blots were developed using an alkaline phosphatase-conjugated species-specific anti-immunoglobulin antibody.
RT-PCR Analysis--
Total RNA was extracted (RNA Fast,
Molecular Systems, San Diego, CA) from about 1-2 million subconfluent
human skin fibroblast cells after 2 days from the transfection of pSG5
or pSG5-LOX vector. 1 µg of total RNA was reverse-transcribed by
Maloney murine leukemia virus reverse transcriptase, using random
hexamers as primers (cDNA 1st Strand synthesis kit,
CLONTECH, Palo Alto, CA). The resulting cDNA
was diluted to a ratio of 1:5 and used as template for the following
PCR. The PCR was performed in 10 mM Tris-HCl, pH 8.2, containing 1.5 mM MgCl2, 50 mM KCl,
1 µM of each primer, 200 µM dNTP, 5%
Me2SO, and 1.5 units of Taq Polymerase
reactions (Taq DNA Polymerase from Termus Aquaticus strain
YT1; Promega). The primers used to amplify Col3A1 messenger were:
forward, 5'-CTG AAA TTC TGC CAT CCT GAG-3'; reverse, 5'-CCA AGG TCC ACA
CCA AAT TC-3'. The PCR conditions used to amplify the Col3A1 were:
preincubation for 5 min at 95 °C and then 24 cycles of 1 min at
95 °C, 30 s at 57 °C, and 1 min at 72 °C, followed by a
final step of 5 min at 72 °C. The expected product was of 590 bp
long. Parallel PCR reactions were performed to amplify the housekeeping
gene G3PDH and to normalize the results obtained for Col3A1. The
primers used for the amplification of G3PDH were the following:
forward, 5'-TGA AGG TCG GAG TCA ACG GAT-3'; reverse, 5'-CAT GTG GGC CAT GAG GTC C-3'. To amplify the G3PDH we used the same conditions as
above, but a temperature of 60 °C for the annealing and 90 s of
elongation at 72 °C. The expected product was 980 bp long. Several
amplifications for both messengers were performed to define the range
of template amount and cycle number that would give the best linear
results. The PCR products were quantified by densitometric analysis
(National Institutes of Health Image v1.62 for Macintosh), and Col3A1
product was expressed as a Col3A1:G3PDH ratio.
Several fragments of COL3A1 promoter, ranging at their 5' ends
from All of the above constructs showed a comparable basal activity, except
for pDD2, which was significantly two times higher (Fig.
2). COS-7 cells were transfected with
pSG5-HLOX, a SV40-driven mammalian expression vector that expresses the
mature form of LOX tagged with poly(His)6 at the
NH2 terminus. Interestingly, the recombinant LOX protein,
although expressed in the cytoplasm as expected, was also largely
expressed in the nuclear compartment, which is in agreement with the
most recent findings (29) (Fig. 3). We
were unable to detect by any means the recombinant LOX in the
extracellular compartment (data not shown), confirming the importance
of the pro-peptide sequence in the secretion of the enzyme. This suited
our aim of studying the putative intracellular activity of LOX.
Lysyl Oxidase Activates the Transcription Activity of Human
Collagene III Promoter
POSSIBLE INVOLVEMENT OF Ku ANTIGEN*
,,,,,
Department of Nephrology and
§ Fondo Malattie Renali del Bambino, Gaslini Children's
Hospital and ¶ Laboratory of Molecular Genetics, Gaslini
Children's Hospital, Genova and Department of Oncology, Biology and
Genetics, University of Genova, 16147 Genova, Italy
ABSTRACT
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-aminopropionitrile, a specific inhibitor of its catalytic activity. Electrophoretic mobility shift assay showed a binding activity in the region from 
101
to 77 that was significantly increased by lysyl oxidase overexpression. The binding was specifically competed by the cold probe, and the mutagenesis of this region abolished both the binding activity in gel retardation and lysyl oxidase stimulation of COL3A1 promoter in transfection experiments. We identified the binding activity as Ku antigen in its two components: Ku80 and Ku70. This study
suggests a new coordinated mechanism by which lysyl oxidase might
control the development of fibrosis.
INTRODUCTION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-aminoadipic-
-semialdehyde into elastin and collagen
chains. The consequent aldheydes lead to a spontaneous condensation
forming inter- and intra-chain cross-links into these important
extracellular matrix (ECM) components. This post-translational
modification of the ECM molecules seems to have a very important role
both for collagen and elastin structural aspects and likely triggers
some still unknown signal transduction pathways. Because of its action
on ECM, deficit of normal LOX expression has been described in many
polygenic and monogenic disorders such as atherosclerosis, type IX
Ehlers-Danlos syndrome, and Menkes disease (3, 4). On the other hand,
an enhanced level of LOX as well seems to be involved in human
pathology. Several reports have recently suggested a clear association
between organ fibrosis and increased LOX activity. This has been
described in several chronic human liver diseases (5), in rat
experimental hepatic fibrosis (CCl4) (6), in idiopathic and
experimental lung fibrosis (7), in adriamycin-induced kidney fibrosis
in rat (8), and in other pathologies resulting in fibrosis (9-13).
1, interleukin-1,
prostaglandins, insulin-like growth factor 1 (19-25),
and even the well defined tumor suppressor interferon responsive
factor-1 (26), which puts this protein in a critical pathway for cell
growth and phenotype control. Despite all these intriguing findings,
there are no hypotheses so far about the mechanisms through which LOX
might actually work as a tumor suppressor.
1 (COL3A1) promoter. To address this issue we used a
reporter gene approach, transfecting COL3A1 promoter cloned upstream of
luciferase gene into COS-7 cells. The influence of LOX expression was
evaluated comparing the same cells co-transfected with the expression
vector alone or carrying LOX coding sequence for the mature 32-kDa
protein (30, 37, 38). Our results showed a dramatic increase in COL3A1
promoter activity when the recombinant LOX was overexpressed. Furthermore, we defined the region of COL3A1 promoter most likely involved in this LOX-dependent activation and some of the
possible mechanisms involved.
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
97 to 75 in the COL3A1 promoter insert, transformed the original sequence 5'-GCT GAG GGG ATG GGT GCG-3' into 5'-CAA TCT CCT GCC TAG
ATT-3'.
-galactosidase enzyme was always co-transfected.
-galactosidase activity, which was assayed by spectrophotometric
conversion of resorufin--galactopiranoside (Sigma) at 572 nm.
volume of 1% Nonidet P-40 to obtain a final concentration
of 0.2% Nonidet P-40 and incubated at 4 °C for 15 min. The cell
lysate was then centrifuged at 700 × g for 15 min. The
supernatant (S1) was saved for further processing, whereas the pellet
(P1), mostly containing the unbroken nuclei, was resuspended in the
previous buffer, added with 0.2% Nonidet P-40, 0.4 M NaCl,
10% glycerol and incubated at 4 °C for 15 min. P1 was centrifuged
at 20,000 × g for 30 min. The supernatant fraction (S2) was collected and used as nuclear extract for gel retardation assay. S1 was then centrifuged at 20,000 × g for
1 h, to obtain a partially purified cytosolic (S3) fraction. The
protein concentration was determined using a classical Coomassie
Blue-based assay (42).
-32P]ATP (PerkinElmer Life Sciences) using T4
polynucleotide kinase. The binding to the double-stranded
oligonucleotides corresponding to the different regions of COL3A1
promoter was performed by incubation at 4 °C for 30 min with 10 ftmol of 32P-labeled probes with the previous nuclear
extract mix. The DNA-protein complexes were separated by
electrophoresis on a 5% polyacrylamide gel and detected by
autoradiography of the dried gel. Competitions were performed by the
addition of 100-300-fold molar excess of unlabeled double-stranded
oligonucleotide competitor to the incubation mixture. Where indicated,
the nuclear extracts were preincubated with the specified antibody for
30 min at 4 °C and then used for the gel retardation assay. The
antibodies were the same used in Western blot analysis.
RESULTS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
1375 to -35 bp from the transcription start site and extending
up to +61 bp, were cloned into pGL2-basic vector. In length order the
constructs are: pRUP4, pRUP6, pFV1, pDD1, and pDD2, respectively
starting at 1375, 257, 117, 55, and 35 (Fig.
1, A and B).
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Fig. 1.
A, the scheme shows the different
fragments of COL3A1 promoter subcloned into pGL2-basic vector.
B, FV1 fragment of Col3A1 promoter. The homology among
oligonucleotides 31, 11, and 414 is underlined.
C, alignment between NRE1 (nuclear regulatory element of the
long terminal repeat of MMTV) and oligonucleotide 31.
View larger version (33K):
[in a new window]
Fig. 2.
Luciferase activity of the indicated pGL2
constructs carrying different fragments of COL3A1 promoter in the
absence or presence of recombinant LOX co-expression. Luciferase
activity is expressed as arbitrary units (A.U.). The results
are the averages of at the least three independent experiments
performed in triplicate ± S.E. The significance of the difference
between the activities in presence of LOX expression and their relative
controls has been evaluated by t test analysis.
View larger version (18K):
[in a new window]
Fig. 3.
SDS-PAGE of fractionated cell extracts from
COS-7 transfected with LOX (pSG5-LOX) or with the vector alone
(pSG5). The recombinant LOX was detected by Western blot with
polyclonal anti-His tag antibodies.
When COS-7 cells were co-transfected with pSG5-LOX and the other
different COL3A1 promoter constructs, the activity of the promoter was
increased up to an average of 12 times, depending on the construct. In
Fig. 2 a summary of the responses of the different promoter
fragments to LOX expression is shown. The FV1 and DD1 regions are the
most responsive, although pDD2 construct still retains a significant
2-3-fold inducibility upon LOX expression. The Fig.
4A shows that LOX induction of
COL3A1 promoter is dependent on LOX catalytic activity, being
completely suppressed by its inhibitor, the -amino-propionitrile (7,
46, 47). Additionally, to rule out any generic effects on the basic
transcription machinery, we co-transfected pSG5-LOX with pGL2-control
vector, which is deprived of any promoter region, or with two short
minimal unrelated promoters, the SV40 contained in pGL2-promoter vector
and the interleukin-4 minimal promoter, also subcloned into pGL2
plasmid. Fig. 4B shows that in all cases, except with pFV1,
LOX expression did not cause any increase in luciferase activity. Based
on these functional findings (Fig. 2), we guessed that a LOX-responsive sequence must be present in repeated copies in the FV1 fragment, because we observed the highest response to LOX expression in all three
tested fragments, FV1, DD1, and DD2. Moreover, the response decreased
with the shortening of COL3A1 fragment, probably due also to an
increased basal activity. We therefore analyzed the homology among the
three fragments. The homologous regions are shown underlined
in Fig. 1B. The resulting consensus sequence can be
indicated as: (A/G)CT(G/A)A(G/A)GG(A/G)A. Although there are some
differences within the three sequences, there is a strict conservation
of the purines, which accounts for 80% of the overlapping sequences.
To probe the ability of this consensus sequence to bind some
transcription factor(s), we performed a classic EMSA analysis approach.
The experiment was performed using the nuclear extracts from COS-7
transfected with the vector expressing the recombinant LOX or with the
empty vector as negative control, and the three consensus DNA
sequences, respectively named 31, 11, and 414, were used as probes.
Fig. 5A shows clearly a
retarded DNA-protein(s) complex that is increased 3-4 times when LOX
is overexpressed. Although LOX induces the highest binding with probe 31, the relative increase seems within the same range for all three
sequences. Fig. 5B shows the specific competition of the DNA-protein complex bound to probe 31 by a molar excess of the cold
oligonucleotide 31 or the other two consensus sequences, 11 and 414. The mutation of oligonucleotide 31 (31m) resulted in the abolition of
the above described complex (Fig.
6A). The same mutation was
also introduced in the pFV1 construct (FV1m) to test its effect in the
luciferase gene reporter assay. The basal promoter activity of FV1m was
almost double the one of the FV1, but, as expected, there was a much
lower response to LOX expression (Fig. 6B).
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Although we did not find any similarity between our consensus sequence
and the ones described in a transcription factor data base
(MatInspector version 2.1), we performed a homology search against the
EMBL DNA data base. Among the many possible nucleotide sequences that
partially matched the oligonucleotide 31 sequence, our attention was
drown by NRE1 (nuclear regulatory element), which is a sequence in the
long terminal repeat of MMTV responsible for the inhibition of
its induction by glucocorticoids (Fig. 1C). Recent
investigations (44, 48-51) showed that NRE1 is able to bind the Ku
antigen heterodimer complex (Ku80 and Ku70). Ku antigen usually binds
to DNA-free ends or nicked double-stranded DNA and mediates the binding
of the DNA-dependent protein kinase (DNA-PK). The whole
complex is involved in some of the main DNA repair and recombination
processes (52-54). Based on this evidence, we tested the presence of
Ku in the DNA-protein complex that appears in our EMSA experiments,
using anti-Ku80-specific and anti-Ku70-specific antibodies. Fig.
7A shows, indeed, that both
antibodies were able to induce a supershifted complex. In the case of
anti-Ku80, the antibody supershifted the entire complex. This might
indicate a special role of Ku80 in the binding of the whole complex to the target DNA sequence. The antibodies alone did not produce any
retarded complex (data not shown).
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Because Ku can bind in a nonspecific manner to the ends of
double-stranded DNA, we wanted to test the extent of the specificity of
the binding of Ku to oligonucleotide 31. First, we performed the EMSA
in higher stringency conditions, substituting the poly(dI-dC) with a
higher concentration of shredded calf thymus DNA to compete the
nonspecific binding (44). In Fig. 8, the
first two lanes show that the Ku complex is barely visible in the
control transfection, whereas it appears clearly in the presence
of LOX expression. Moreover, to eliminate any possibility of
nonspecific binding to the DNA ends, oligonucleotide 31, modified with
suitable restriction sites, was subcloned into pSK+
plasmid, excised with EcoRI/PvuII, and
circularized by T4 ligase, producing a 280-bp circularized DNA molecule
(44). The obtained microcircles were used to compete Ku binding to
oligonucleotide 31. Similar microcircles obtained from wild type
pSK+ (without oligonucleotide 31) were used as negative
control. In Fig. 8, we can see that only the microcircles containing
the sequence 31 were able to compete the retarded band
(third and fourth lanes). Taken together these
results prove a specific binding of Ku to the identified consensus
sequence.
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Looking for an explanation for the increased binding of Ku induced by LOX overexpression, we tested whether it was the result of a change in Ku expression level itself. That was not the case, because the Western blot shows that neither Ku80 nor Ku70 protein levels were affected by LOX expression (Fig. 7B). Also, there was no change in their intracellular distribution (data not shown).
Although our data strongly suggest a regulation of Col3A1 expression by
LOX in COS-7, it is also true that these cells are not the best model
for collagen production. Therefore, to test our hypothesis in
vivo and on a more appropriate model, we decided to perform the
same EMSA experiments using a primary culture of human skin
fibroblasts. Although these cells expressed a significant amount of our
recombinant LOX upon transfection of pSG5-LOX, the level of expression
was much less than the one obtained in COS-7 cells (Fig.
9B). Nevertheless, as shown in
Fig. 9A, we were able to reproduce the same results as with
COS-7 cells, because even a milder expression of LOX was accompanied by
a significant increase of binding of Ku antigen to the oligonucleotide
31. The supershift of the retarded DNA-protein complex induced by the
anti-Ku80 antibody confirmed that we were dealing exactly with the same
phenomenon (Fig. 9A, third lane). Next, we tested
whether the presence of our recombinant LOX would really increased the
level of Col3a1 messenger. In Fig. 9 (C and D)
the results of a RT-PCR analysis show a significant 1.7-fold average
increase of endogenous Col3A1 messenger in the fibroblasts expressing
our recombinant LOX. Considering that the best transfection does not
reach more than 20% of the target cells and that the conditions
in vivo are rather different from those in the luciferase
assay, these in vivo results seem to support our previous
data. Moreover, as shown in Fig. 9B, we know that the
transfection yield obtained with these human fibroblasts was quite
lower than with COS-7, which should further reinforce the meaning
of that quasi 2-fold increase in Col3A1.
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ABSTRACT
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DISCUSSION
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LOX plays a critical role in the organization of extracellular
matrix, stabilizing the molecules of collagen and elastin (1, 55-57).
Because of that, LOX is considered one of the main actors in the
development of many pathological fibrotic processes (5-8). Also, LOX
has been proposed as the tumor suppressor gene, because of its
down-regulation in many experimental and naturally occurring tumors and
its anti-ras activity (14, 15, 17, 18, 30, 58). It has even
been proved that LOX is up-regulated by the tumor suppressor interferon
responsive factor-1 at the promoter level (26). This evidence suggests
an additional role for LOX apparently not directly related to its
collagen cross-linking activity. In support of this hypothesis there
are observations that show a possible intracellular role for LOX (29,
30). Collagen III is one of the substrates of LOX and is also
characteristic of specific organ fibrosis (31, 32, 34, 59-61). In many
cases it has been shown that the level of LOX expression changes in parallel with collagen III (9, 17, 35, 62). Also LOX-like protein, a
member of the LOX family, has been shown to be up-regulated together
with collagen III in an experimental liver fibrosis (36) and is found
expressed in the intracellular
compartment.2 In the
present paper we present evidence that the mature 32-kDa form of LOX
intracellularly expressed (37, 38) can regulate the transcription
activity of COL3A1 promoter. We showed that the region from 117 to + 61 of COL3A1 promoter is responsible for a positive transcriptional
response to the overexpression of our recombinant mature LOX. The
effect is specific for COL3A1 promoter, and it is dependent on LOX
catalytic activity, which suggests some intracellular cross-linking
process that mediates the observed effects. EMSA experiments and
homology analysis of the indicated promoter region showed three highly
conserved sequences that are able to bind the same proteic factor(s).
By homology of our consensus sequences with NRE1, we inferred that the
protein(s) complexing to our oligonucleotide probe could be Ku antigen,
which, in fact, has been previously proved to bind to NRE1 in a
specific manner (44, 48-50). Indeed, using specific antibodies for Ku antigen, we were able to compete and supershift the retarded band appearing in our EMSA analysis. Ku is a heterodimer (80-86 and 70 kDa)
that forms a complex with the DNA-PK and brings it to the target DNA
(63-65). A well described role for Ku/DNA-PK is to direct and control
some DNA repair processes and V(D)J recombination (52-54, 66, 67). One
of the consequences of such Ku activity is its role in controlling the
general cell radiosensitivity (68-72). However, many different
activities have been proposed for Ku antigen, from the physical
interaction with EGF and glucocorticoid receptors (73, 74) or even
somatostatin (75, 76) to the regulation of promoters activities (44,
48, 49, 77, 78). So far, the best documented alternative activity of Ku
antigen is the regulation of NRE1, a sequence in the long terminal
repeat promoter of MMTV, which is necessary to repress MMTV
transcription induced by glucocorticoids (44, 48, 51). Furthermore,
more recent evidence support Ku role in promoter regulation. DAS, a
sequence similar to NRE1, which is downstream of the TATA box of the
strict late () UL38 promoter of herpes simplex virus type 1, has been reported to be able to bind Ku/DNA-PK and activate the
promoter (49).
Our findings suggest that LOX can be responsible of alternative
intracellular activities and that the activation of COL3A1 promoter can
be one of those. In the specific case it is not surprising that an
enzyme would up-regulate its own substrate, in a type of positive
feedback fashion. Moreover, our data are supported by a previous
observation suggesting a co-regulation of LOX and COL3A1. The finding
that Ku antigen might be involved in such a regulation is completely
novel. Presently it is difficult to define the possible mechanism by
which LOX would increase Ku binding to its target sequence on COL3A1
promoter. We think that some LOX-dependent activation of Ku
might occur, probably in terms of post-translational modification. It
has already been described that Ku can be substrate of the
DNA-dependent PK (79), and its phosphorylation seems
related to its binding to an Epstein-Barr virus-responsive
enhancer (78). Obviously, further studies are needed to completely
understand the regulatory mechanism that links LOX to Ku. A very recent
paper has pointed out that Ku can be placed in the class of the
caretaker genes and, therefore, suppresses malignant transformation in
certain conditions (80). It is intriguing to think that at the least
some of LOX tumor suppressor activities might be explained by an
improved Ku-dependent DNA repair activity and, therefore, a
more stable genomic status of the cells.
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FOOTNOTES |
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* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed: Laboratory of
Nephrology, Istituto G. Gaslini, Largo G. Gaslini, 5, 16147 Genova, Italy. Tel.: 39-010-380742; Fax: 39-010-395214; E-mail:
a-dido@usa.net.
Published, JBC Papers in Press, August 14, 2000, DOI 10.1074/jbc.M003362200
2 K. Csiszar, personal communication.
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ABBREVIATIONS |
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The abbreviations used are: LOX, lysyl oxidase; ECM, extracellular matrix; PCR, polymerase chain reaction; RT, reverse transcriptase; EMSA, electrophoresis mobility shift assay; bp, base pair(s); PAGE, polyacrylamide gel electrophoresis; MMTV, mammary mouse tumor virus; DNA-PK, DNA-dependent protein kinase.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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