©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Regulation of Lysyl Oxidase by Basic Fibroblast Growth Factor in Osteoblastic MC3T3-E1 Cells (*)

(Received for publication, November 14, 1995)

Eduardo J. Feres-Filho (1) Gabriel B. Menassa (1) Philip C. Trackman (1) (2)(§)

From the  (1)Department of Periodontology and Oral Biology, Boston University Goldman School of Graduate Dentistry, Boston, Massachusetts 02118 and the (2)Department of Biochemistry, Boston University School of Medicine, Boston, Massachusetts 02118

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Lysyl oxidase catalyzes the final known enzymatic step required for collagen and elastin cross-linking. A cross-linked collagenous extracellular matrix is required for bone formation. This study investigated whether lysyl oxidase, like its type I collagen substrate, is down-regulated by basic fibroblast growth factor (bFGF) in osteoblastic MC3T3-E1 cells and determined the degree of post-transcriptional control. Steady-state lysyl oxidase mRNA levels decreased to 30% of control after 24 h of treatment with 1 and 10 nM bFGF. This regulation was time-dependent. COL1A1 mRNA levels declined to less than 10% of control after 24 h of bFGF treatment. Media lysyl oxidase activity decreased consistent with steady-state mRNA changes in cultures that were refed after 24 h of growth factor treatment. Interestingly, treatment of MC3T3-E1 cells with 0.01-0.1 nM bFGF for 24 h and treatment with 1 nM bFGF for up to 12 h resulted in a modest stimulation of lysyl oxidase gene expression and enzyme activity. At least 50% of the down-regulation of lysyl oxidase was shown to be post-transcriptional. New protein synthesis was not required for the down-regulation by bFGF, but cycloheximide did increase constitutive lysyl oxidase mRNA levels 2.5-fold. We conclude that lysyl oxidase and COL1A1 are regulated similarly by bFGF in these osteoblastic cells, consistent with the in vivo effects of this growth factor on bone collagen metabolism.


INTRODUCTION

Lysyl oxidase catalyzes the oxidative deamination of peptidyl-lysine to peptidyl-alpha-aminoadipic--semialdehyde in collagen and elastin precursors. Extracellular lysyl oxidase activity is the final enzymatic step required for cross-linking and deposition of elastin and collagen in connective tissues(1, 2) . This enzyme is copper-dependent, and decreased dietary copper results in deficient lysyl oxidase activity. Nutritional studies utilizing animals fed either copper-deficient diets or diets containing the lysyl oxidase inhibitor BAPN, (^1)established correlations between lowered lysyl oxidase activity, reduced cross-linking of collagen and elastin, and impaired mechanical properties of bone (3, 4, 5, 6, 7, 8) . Interestingly, recent biochemical analysis of human osteoporotic bone collagen from the neck region of femoral heads demonstrated a decrease in the lysyl oxidase-dependent cross-link dehydro-hydroxylysino-keto-norleucine. This is consistent with the increased susceptibility of femoral neck region fracture in osteoporosis(9) .

Collagen accumulation and cross-linking were decreased in chick osteoblast cultures treated with BAPN(10) . In these studies, BAPN diminished collagen fibril diameter, cross-linking, and insoluble calcium accumulation. Collagen turnover was increased compared with control cultures. In contrast, cultures not treated with BAPN resembled normal embryonic bone with respect to cross-link levels and ultrastructure. These results are consistent with studies showing that a cross-linked collagenous matrix is required for the subsequent mineralization of bone in osteoblastic cell cultures(11) . Thus, due to its critical function in collagen accumulation, lysyl oxidase is likely important in bone development and pathology.

Basic fibroblast growth factor (bFGF) is a potent mitogen for a variety of cell types. It is produced by osteoblasts (12) and is found in high concentration in the bone extracellular matrix(13) . bFGF is stored in complexes with heparin/heparan sulfate proteoglycans. It is released by endothelial cell proteases or heparin-like molecules at the sites of injury(14, 15) . These findings suggest that bFGF could be important in bone remodeling and fracture repair. Studies in vivo have shown that bFGF stimulates osteogenic cell proliferation while inhibiting production of bone matrix collagen(16) . In vitro, bFGF causes reduced matrix synthesis by osteoblasts (17) and inhibits collagen synthesis, mostly by a transcriptional mechanism in MC3T3-E1 cells(18) .

Our working hypothesis is that lysyl oxidase and type I collagen may be similarly regulated by bFGF in osteoblastic cultures. cDNA cloning studies of lysyl oxidase from rat, mouse, chick, and human demonstrate that the lysyl oxidase transcript has long 5`- and 3`-untranslated regions whose functions are not known(19, 20, 21, 22, 23) . Untranslated regions have been shown to control mRNA turnover, translation, and subcellular location(24, 25, 26, 27) . Therefore, we investigated whether lysyl oxidase is down-regulated by bFGF in osteoblastic cells and established the degree of change in mRNA decay rates of lysyl oxidase and COL1A1.


EXPERIMENTAL PROCEDURES

Materials

Recombinant human bFGF was purchased from Pepro Tech Inc., Rocky Hill, NJ. TRI Reagent(TM) was obtained from Molecular Research Center, Inc., Cincinnati, OH. Dulbecco's modified Eagle's medium (DMEM), newborn bovine serum (NBS), trypsin-EDTA solution, penicillin-streptomycin solution, Dulbecco's phosphate buffered saline, nonessential amino acid solution, bovine albumin fraction V (BSA), ascorbic acid, beta-glycerophosphate, 5,6-dichloro-1beta-D-ribofuranosylbenzimidazole (DRB) and cycloheximide were purchased from Sigma. All other chemicals were of reagent grade.

Cell Culture

Murine osteoblast-like MC3T3-E1 cells were provided by Dr. Louis Gerstenfeld, Children's Hospital, Boston, MA, and Dr. Renny Franceschi, University of Michigan, Ann Arbor, MI. Cells were plated onto 100-mm tissue culture dishes in DMEM, containing 10% heat-treated (56 °C, 30 min) NBS plus 1% nonessential amino acid and 100 units/ml of penicillin and 100 µg/ml streptomycin. Cultures were maintained at 37 °C in a fully humidified atmosphere of 5% CO(2) in air. Medium was changed every 3 days. For experiments, cells in logarithmic growth phase were dissociated with trypsin/EDTA, counted in a hemocytometer, and inoculated at 200,000 cells/plate. At a density of 70%, the cells were fed with complete medium (+10% NBS) or serum-free medium (+0.1% BSA) containing 50 µg/ml of ascorbate and 10 mM beta-glycerophosphate for 24 h. Cells were then refed with the same medium plus or minus bFGF for the appropriate period of time. Experiments were performed after no more than three passages from one set of frozen cell stocks. When harvested, typical control cultures had about 1 times 10^6 cells/100-mm plate, whereas cultures treated with 1 nM bFGF for 24 h had 15-20% more cells.

Assay of Lysyl Oxidase Activity

Lysyl oxidase enzyme activity was measured in the conditioned media and cell layers, using recombinant human [^3H]tropoelastin substrate(28) . Briefly, cells were cultured as described above. Media samples (0.5 ml) were assayed in quadruplicate in a final volume of 1 ml, containing 0.1 M borate 0.15 M NaCl, pH 8.0, and 160,000 cpm of [^3H]tropoelastin in the presence and absence of 1 times 10M BAPN. Reactions were incubated for 90 min at 37 °C followed by distillation under vacuum. Radioactivity in 0.5-ml aliquots of distillate was determined by liquid scintillation spectrometry. Units of enzyme activity were defined as cpm released above the BAPN control. The scintillation counting efficiency was 50%. For normalizing the enzyme activity to cell number, media were collected and assayed for lysyl oxidase enzyme activity, and cells from the same plate were dissociated and counted in a hemocytometer.

Cell layer lysyl oxidase enzyme activity was measured as follows. The medium was first removed and cells were washed 3 times with phosphate-buffered saline. 1 ml of extraction buffer (0.02 M boric acid, 4 M urea, 0.15 M NaCl, pH 8.0) plus 0.001 M phenylmethylsulfonyl fluoride and 10 µl of aprotinin/10 ml of extraction buffer was added to the plates. The cells were scraped with a rubber policeman and suspended 5 times with a 21-gauge needle and 10 times with an 18-gauge needle. The suspension was transferred to microcentrifuge tubes and spun down at 4 °C for 10 min at full speed. The supernatant was dialyzed overnight against 0.02 M boric acid, pH 8.0, and 0.5-ml samples were assayed in quadruplicate as described above.

RNA Isolation and Northern Analysis

Total RNA was prepared using Tri-Reagent(TM)(29) . 10 µg of denatured RNA was applied per lane, separated by electrophoresis on 1% agarose/formaldehyde gels, and transferred to GeneScreen(TM) nylon membranes(30) . Membranes were prehybridized and then hybridized for 18 h at 42 °C in 50% formamide-containing solutions with a P-labeled COL1A1 cDNA (31) or P-labeled mouse lysyl oxidase cDNA probe (32) as described previously(33) . For normalization, blots were stripped and rehybridized with a radiolabeled glyceraldehyde 3-phosphate dehydrogenase cDNA (34) or an 18 S ribosomal probe (35) . Probes were labeled using the random primer method(36) . The membranes were washed and were subjected to autoradiography at -80 °C(33) . Signals were assessed and normalized by densitometric scanning. Values for standard error were derived from triplicate scans of films. Experiments were performed at least twice.

Analysis of mRNA Decay Rates

Cells were cultured and treated with or without 1 nM bFGF as described above. Cells were refed with the same medium containing 20 µg/ml of the RNA polymerase II inhibitor DRB(37) . Total RNA was isolated at intervals and was subjected to Northern blotting. Membranes were successively probed with lysyl oxidase, COL1A1 collagen, GAPDH, and 18 S ribosomal RNA probes (see above). Signals were quantitated using scanning laser densitometry, and normalized to the 18 S ribosomal RNA signal. The log of percent RNA remaining against time was plotted, and half-lives were calculated after linear regression analysis(37) .


RESULTS

Dose-dependent Regulation of Lysyl Oxidase by bFGF

Preconfluent MC3T3-E1 cells were cultured in DMEM supplemented with 10% NBS in the absence or presence of bFGF for 24 h. A dose-dependent down-regulation in the steady-state lysyl oxidase and COL1A1 mRNA levels was found (Fig. 1). Down-regulation of lysyl oxidase mRNA to about 40% of control occurred at 1 nM bFGF. COL1A1 was down-regulated to less than 5% of control at 1 nM bFGF. Interestingly, at lower concentrations, bFGF caused a modest up-regulation in steady-state lysyl oxidase mRNA levels but not in COL1A1 (Fig. 1). The same results were observed culturing the cells in serum-free media containing 0.1% BSA (data not shown). Experiments were performed at least 2 times, all with similar results.


Figure 1: Down-regulation of lysyl oxidase and COL1A1 steady-state mRNA levels by bFGF is dose-dependent. MC3T3-E1 cells were cultured in media containing 10% NBS in the absence (Control) or presence of indicated concentrations of bFGF. After 24 h, total RNA was isolated and subjected to Northern blotting as described under ``Experimental Procedures.'' Inset, autoradiogram of Northern blots probed with P-radiolabeled COL1A1 and lysyl oxidase cDNA probes, and with a DNA probe for 18 S ribosomal RNA (18S rRNA). Lane 1, control; lane 2, 0.01 nM bFGF; lane 3, 0.1 nM bFGF; lane 4, 1 nM bFGF; lane 5, 10 nM bFGF. Signals were quantitated by scanning laser densitometry and signals for lysyl oxidase and collagen were normalized to the signals for 18 S rRNA. Hatched bars, lysyl oxidase; black bars, COL1A1.



Down-regulation of Lysyl Oxidase by bFGF Is Time-dependent

The time-dependent regulation of steady-state lysyl oxidase mRNA levels and enzyme activity by 1 nM bFGF was tested. 6 h of bFGF treatment caused a 60% increase in the steady-state lysyl oxidase mRNA level, and a 20% increase in enzyme activity (Fig. 2A and Table 1).


Figure 2: Time-dependent effects of 1 nM bFGF on steady-state COL1A1 and lysyl oxidase mRNA levels (A) and effects of refeeding cultures (B). A, autoradiogram of Northern blot of total RNA from MC3T3-E1 cells cultured in the absence (odd numbered lanes) or presence (even numbered lanes) of 1 nM bFGF for 6 h (lanes 1 and 2); 24 h (lanes 3 and 4), and 48 h (lanes 5 and 6). B, media were changed (cells refed) after 24 h of treatment with 1 nM bFGF, and cells were cultured for an additional 24 or 48 h. Lanes 1-4, control cells with no refeeding were treated for 24 h (lanes 1 and 2) or 48 h (lanes 3 and 4). Lanes 5-8, refed after 24 h treatment and cultured for an additional 24 h (lanes 5 and 6) or 48 h (lanes 7 and 8). Odd numbered lanes, no bFGF; even numbered lanes, 1 nM bFGF. Experiments were performed twice with similar results.





This was followed by down-regulation of steady-state lysyl oxidase mRNA to about 25% of control (75% reduction), which occurred at 24 and 48 h of treatment. The decreased lysyl oxidase mRNA levels were not accompanied by a similar decrease in media enzyme activity (Fig. 2A and Table 1). No enzyme activity was detected in the cell layer (not shown).

We then tested the notion that accumulation of active enzyme in the cell culture medium coupled to slow down-regulation of lysyl oxidase mRNA could account for the relatively high lysyl oxidase activity found at 24 h of bFGF treatment. Cells were treated with or without growth factor, and media were changed after 24 h. Lysyl oxidase enzyme activity was then assayed after an additional 24 and 48 h of culturing. Thus, new enzyme activity after the full inhibitory effect of bFGF was measured. Changes in steady-state mRNA levels were determined from parallel cultures to establish that growth factor-dependent changes were maintained throughout the experiment. Lysyl oxidase enzyme activity was also determined in cultures without refeeding, to confirm the relatively high enzyme activity found under these conditions.

As shown in Table 2, lysyl oxidase enzyme activity in the new media decreased to 30 and 20% of controls after 24 and 48 h, respectively. These results agreed with the decrease in steady-state lysyl oxidase mRNA levels isolated from parallel cultures. As expected, cultures not refed exhibited high enzyme activity relative to changes in lysyl oxidase mRNA levels (Table 2). bFGF down-regulation of lysyl oxidase and COL1A1 mRNA levels was maintained throughout the experiment (Fig. 2B). Experiments performed under serum-free conditions yielded similar results (data not shown). Thus, bFGF-dependent changes in steady-state lysyl oxidase mRNA levels resulted in corresponding changes in lysyl oxidase enzyme activity.



Analysis of Changes in mRNA Decay Rates

In preparation for analyzing the degree of post-transcriptional down-regulation of lysyl oxidase mRNA by bFGF (see below), a detailed time study was performed. The time at which up-regulation of lysyl oxidase ceased, and down-regulation began was established. We reasoned that the mechanism of down-regulation of lysyl oxidase mRNA might be fully in effect when down-regulation began, given that the half-life of lysyl oxidase mRNA is long(19) .

Down-regulation of steady-state lysyl oxidase mRNA levels by 1 nM bFGF began after 12 h and reached maximum effect at 24 h (Fig. 3). Interestingly, down-regulation of steady-state COL1A1 mRNA occurred earlier, to a higher degree, and was maintained for at least 48 h. These results are consistent with the dose-response study (Fig. 1) where COL1A1 was down-regulated at lower concentrations of bFGF compared with lysyl oxidase.


Figure 3: Detailed time-dependent regulation of COL1A1 and lysyl oxidase steady-state mRNA levels by 1 nM bFGF. Hatched bars, lysyl oxidase; and black bars, COL1A1. Data are from two pooled experiments. Values are standard error means of triplicate densitometric scans normalized to the 18 S rRNA signals.



bFGF-dependent changes in lysyl oxidase, collagen, and GAPDH mRNA decay rates were then determined. In the first group of experiments MC3T3-E1 cells were treated without or with 1 nM bFGF for 12 h, and then 20 µg/ml DRB was added to inhibit new mRNA synthesis. Cultures were harvested at intervals over the next 12 h, and RNA was isolated. Parallel cultures not treated with DRB were grown in order to verify bFGF-dependent changes in steady-state mRNA levels. Total RNA was subjected to Northern blot analysis (Fig. 4). Lysyl oxidase mRNA decayed with a t of 10 h in DRB-treated cells. The t for DRB- plus bFGF-treated cells was 6.9 h, a decrease of 31%. Thus, post-transcriptional mechanisms account for about 50% of the lysyl oxidase regulation by 1 nM bFGF, as steady-state mRNA levels were decreased to 63% of controls. Similar figures were found for COL1A1 mRNA (Fig. 4). The control half-life for COL1A1 was 8.2 and 4.3 h for bFGF-treated cultures, accounting for 50% of down-regulation. This degree of post-transcriptional bFGF regulation of COL1A1 is similar to that estimated previously in MC3T3-E1 cells(18) . bFGF regulation of GAPDH mRNA was also analyzed. Whereas the bFGF-treated steady-state mRNA levels for GAPDH increased 170%, the stability of GAPDH mRNA decreased to 50% of control. Thus, in contrast to lysyl oxidase and COL1A1, regulation of GAPDH could not be accounted by bFGF-dependent changes in mRNA decay rates. Regulation of GAPDH by bFGF, therefore, likely occurs by a different mechanism (Fig. 4).


Figure 4: Determination of bFGF post-transcriptional mRNA decay rates of lysyl oxidase, COL1A1, and GAPDH mRNAs by Northern blotting after 12 h of bFGF pretreatment (A-C) and calculation of mRNA decay rates (D-F). A-C, subconfluent MC3T3-E1 cells were treated with 1 nM bFGF for 12 h, and then with 20 µg/ml DRB as described under ``Experimental Procedures.'' In addition, parallel cultures not treated with DRB were grown in order to establish bFGF-dependent changes in steady-state mRNA levels. All blots were probed with radiolabeled cDNAs for lysyl oxidase, COL1A1, and GAPDH and with a probe for 18 S ribosomal RNA. A, Northern blots from bFGF- and DRB-treated cells; B, Northern blots from DRB-treated cells; C, steady-state mRNA changes. For A and B, treatment times refer to hours after DRB addition. Lane 1, 0 h; lane 2, 2 h; lane 3, 4 h; lane 4, 6 h; lane 5, 8 h; lane 6, 10 h; lane 7, 12 h. In C, no DRB was added. Lanes 1 and 2, 0 h; lanes 3 and 4, 6 h; lanes 5 and 6, 12 h. D-F, the hybridization signals seen in blots A, B, and C were quantified and normalized to the 18 S ribosomal RNA signal after triplicate densitometric scanning. Data are from two experiments were pooled. Error bars are the range of log % mRNA remaining from triplicate densitometric scans. All scanning data from A and B were subjected to linear regression analysis of semi-log plots of the percentage of mRNA remaining versus time, yielding the following decay half-lives: D, lysyl oxidase mRNA decayed with a t of 10 and 6.9 h in DRB-treated (box) and in DRB plus bFGF-treated (bullet) cells, respectively; E, COL1A1 mRNA decayed with a t of 8.2 and 4.3 h in DRB-treated (box) and in DRB plus bFGF-treated (bullet) cells, respectively; F, GAPDH decayed with a t of 25.4 and 13.2 h in DRB-treated (box) and in bFGF plus DRB-treated (bullet) cells, respectively. Correlation coefficients for the regression lines for control and bFGF-treated cells, respectively, were 0.890 and 0.943 for lysyl oxidase, 0.854 and 0.923 for COL1A1, and 0.700 and 0.865 for GAPDH. The amount of regulation accounted for by post-transcriptional mechanisms was calculated dividing the bFGF-dependent change in decay half-life for each transcript by the change in steady-state mRNA isolated from parallel experiment: lysyl oxidase (31%/63% = 50%); COL1A1 (52%/95% = 54%).



We next analyzed the decay of lysyl oxidase mRNA after 21 h of 1 nM bFGF pretreatment of MC3T3-E1 cells. This was performed to evaluate whether the post-transcriptional down-regulation of lysyl oxidase was greater after 21 h compared with 12 h of growth factor pretreatment. It is noted that lysyl oxidase steady-state mRNA levels are more stably down-regulated after 21 h of pretreatment (Fig. 3). Interestingly in control cells, no measurable decay of lysyl oxidase mRNA in control cultures was detected (Fig. 5). In bFGF-treated cultures, the half-life was reduced to 10 h. Thus, clear evidence for post-transcriptional lysyl oxidase regulation by bFGF was obtained from cells pretreated for 12 and 21 h ( Fig. 4and Fig. 5). The degree of post-transcriptional control appears to be greater after 21 h of bFGF pretreatment and coincides with the maximum and stable down-regulation in lysyl oxidase steady-state mRNA levels.


Figure 5: Determination of mRNA decay rate of lysyl oxidase after 21 h of 1 nM bFGF pre-treatment of MC3T3-E1 cells. Subconfluent MC3T3-E1 cells were treated for 21 h with or without 1 nM bFGF, followed by 20 µg/ml DRB as described under ``Experimental Procedures.'' Parallel cultures not treated with DRB were grown to establish bFGF-dependent changes in steady-state mRNA levels. Blots were probed for lysyl oxidase and 18 S ribosomal RNA. Inset, Northern blots from DRB-treated cells (lanes 1-6), and DRB plus bFGF (lanes 7-12). Times of harvest after DRB-treatment were 2 h (lanes 1 and 7), 4 h (lanes 2 and 8), 6 h (lanes 3 and 9), 8 h (lanes 4 and 10), 10 h (lanes 5 and 11), and 12 h (lanes 6 and 12). Steady-state mRNA levels were determined from parallel cultures not treated with DRB corresponding to zero (lanes 13 and 14) and 12 h of DRB treatment (lanes 15 and 16). The plot of %RNA remaining against time of DRB treatment shows data are from two pooled experiments. Error bars represent the range of two experiments, each assessed twice by laser scanning densitometry. All data were subjected to linear regression analysis. Data from zero hours of DRB treatment were not included in the analysis because RNA for this time point from one of the two experiments was degraded. DRB plus 1 nM bFGF-treated (bullet) cells resulted in a calculated half-life of 10 h for lysyl oxidase mRNA and a correlation coeffient of 0.852. Data from cells not treated with bFGF (box) resulted in a slope of near zero, and thus had no detectable decay of lysyl oxidase mRNA.



Effects of Cycloheximide

Inhibition of protein synthesis can influence growth factor-dependent effects on gene expression by different mechanisms. When regulation is predominantly post-transcriptional, inhibition of protein synthesis by cycloheximide sometimes causes large increases in mRNA levels known as super-induction. This may be due to cycloheximide-dependent loss of labile proteins that function to destabilize the mRNA (38) or protection of the mRNA by bound ribosomes(39) . We therefore wished to establish whether bFGF down-regulation of lysyl oxidase was influenced by cycloheximide.

Treatment of MC3T3-E1 cells with cycloheximide for the final 8 h of 20-h exposures to 1 nM bFGF resulted in little change in the down-regulation of lysyl oxidase, compared with controls without bFGF. In two experiments, bFGF-treated cultures had steady-state lysyl oxidase mRNA levels of 37.5% ± 6.5 and 50% ± 5% of no growth factor controls, in the presence and absence of cycloheximide, respectively. COL1A1 down-regulation by bFGF was also maintained under these conditions (Fig. 6). Interestingly, the steady-state lysyl oxidase mRNA levels in both the control and growth factor-treated cells were increased by about 2.5-fold by cycloheximide (Fig. 6). There was little effect of cycloheximide on GAPDH or COL1A1 mRNA levels in either bFGF- or no bFGF-treated cells (Fig. 6). These results suggest that cycloheximide influences the level of constitutive expression of lysyl oxidase mRNA in MC3T3-E1 cells but not the level in COL1A1 and GAPDH mRNA. Moreover, new protein synthesis is not required for bFGF-mediated down-regulation of steady-state lysyl oxidase mRNA levels.


Figure 6: Effect of cycloheximide on lysyl oxidase, COL1A1, and GAPDH mRNA levels. MC3T3-E1 cells were preincubated without (control) or with 1 nM bFGF for 12 h, and then treated with or without 5 µg/ml cycloheximide. After 8 h, total RNA was isolated and Northern blot analysis was performed. A, lane 1, control; lane 2, bFGF; lane 3, control plus cycloheximide; lane 4, bFGF plus cycloheximide. This experiment was performed twice with similar results.




DISCUSSION

The results presented show that lysyl oxidase expression is regulated by bFGF in osteoblastic MC3T3-E1 cells. Steady-state lysyl oxidase mRNA levels decreased after 24 h of 1 and 10 nM bFGF treatment, similar to changes found in COL1A1 mRNA. Lowered lysyl oxidase mRNA levels resulted in diminished production of new lysyl oxidase enzyme activity.

In contrast, 0.01-0.1 nM bFGF caused an increase in lysyl oxidase mRNA levels but not in COL1A1 mRNA. Short-term treatment of MC3T3-E1 cells for 6 h with 1 nM bFGF caused increased steady state levels of both COL1A1 and lysyl oxidase mRNAs. This short-term treatment caused a corresponding increase in the culture medium lysyl oxidase enzyme activity.

These time- and dose-dependent effects of bFGF on lysyl oxidase and COL1A1 gene expression may be related to time-dependent effects of bFGF on collagen synthesis observed in fetal rat calvaria organ cultures(17, 40, 41) . In these studies, treatment of organ cultures with bFGF for 24 h resulted in lowered collagen synthesis. In contrast, treatment with bFGF for 24 h followed by culturing in the absence of growth factor for an additional 24 or 48 h resulted in increased collagen synthesis. The stimulatory effects on collagen synthesis were principally due to the mitogenic effect of bFGF on osteoblasts in the organ cultures(17) , although direct effects on collagen gene expression were not excluded. Similarly, in vivo studies of chick embryos treated with bFGF resulted in decreased osteogenesis in the short term but stimulated bone formation in the long term, after bFGF application was discontinued. It was suggested that in addition to increasing the numbers of osteogenic cells, bFGF treatment might also ultimately increase the osteogenic potential of osteoblastic cells compared with embryos not treated with bFGF(42) . Time-dependent effects on lysyl oxidase and collagen gene expression could be physiologically important, since exposure of osteoblasts to bFGF in vivo resulting from injury is likely to be acute. A more complete understanding of the effects of bFGF on bone formation will require varying the duration of bFGF exposure of osteoblastic cells and determining the subsequent changes in cell number, lysyl oxidase activity, collagen accumulation, and ultimately mineralization in vitro.

The observed bFGF-dependent increase in steady-state GAPDH mRNA levels is probably related to changes in the proliferative state of MC3T3-E1 cells. Meyer-Siegler and co-workers (43) found that the expression of the GAPDH gene was dependent on the proliferative state of several human cell lines. Mitogenic effects of bFGF on MC3T3-E1 cells are well established(40) . bFGF influences differentiation of osteoblasts by inhibiting the expression of osteoblastic markers, including alkaline phosphatase and type I collagen(41) . bFGF also induces the expression of collagenase and plasminogen activator, leading to matrix degradation(44, 45) . Thus, the down-regulation of lysyl oxidase expression by bFGF is consistent with induction of a proliferative matrix-resorbing phenotype.

Post-transcriptional control of gene expression has been demonstrated for several extracellular matrix genes including elastin (46) and COL1A1(47) . Transcript stability is believed to be regulated principally by sequences located in the 5`- and 3`-untranslated regions and the length of the polyadenyl tail(39) . Due to the presence of long 5`- and 3`-untranslated regions in lysyl oxidase, we wished to establish the degree of post-transcriptional mechanisms in the bFGF-mediated effects. Our analyses indicate that changes in mRNA decay rates were responsible for at least 50% of lysyl oxidase mRNA regulation by bFGF. The remaining bFGF down-regulation of lysyl oxidase is likely to be transcriptional, as has been shown for COL1A1(18) . Comparison of the complete 3.5 kilobase pairs of rat 3`-untranslated region of rat lysyl oxidase (19) to that of human (48) reveals sequence conservation with an identity of 72.6% (not shown). It will be of interest to establish whether conserved regions of the 3`-untranslated region of lysyl oxidase mRNA regulate its stability in response to growth factors and cytokines, as may be true for COL1A1 (49, 50) .

We tested whether labile protein factors might be necessary for the bFGF-mediated effect on lysyl oxidase and COL1A1 expression. Cycloheximide caused increased levels of lysyl oxidase messages, but no changes were found in COL1A1 and GAPDH mRNAs. Furthermore, labile bFGF-induced protein factors appear not to mediate down-regulation of COL1A1 and lysyl oxidase mRNA levels. This effect indicates that the constitutive expression of lysyl oxidase mRNA is influenced by labile factors in MC3T3-E1 cells. As unstable proteins appear not to directly mediate bFGF-dependent regulation of lysyl oxidase, we speculate that activation of stable protein factors by post-translational modification such as phosphorylation/dephosphorylation pathways may result in bFGF-dependent down-regulation of lysyl oxidase steady-state mRNA levels.

The essential role of lysyl oxidase in collagen cross-linking and accumulation suggests that its regulation by growth factors may have biological importance in osteogenesis. Interestingly, type I collagen synthesis and accumulation have been shown to be uncoupled in mineralizing MC3T3-E1 cells(11, 51) . In these studies, it was shown that the peak of collagen synthesis did not correspond to the peak of collagen accumulation, as these cells formed a mineralized extracellular matrix. Although lysyl oxidase steady-state mRNA levels were reported not to increase during the period of increased collagen accumulation(51) , measurements of lysyl oxidase enzyme activity were not presented. It is notable that lysyl oxidase has a complex biosynthetic pathway(52) . The proenzyme is secreted as a 50-kDa glycoprotein and undergoes extracellular processing to form the 32-kDa product known to be active. As the studies reported here now demonstrate, changes in lysyl oxidase activity may not correspond to changes in steady-state mRNA levels at a given time due to residual pools of active enzyme. Similarly, we have recently shown that intracellular or extracellular pools of potentially activable proenzyme may accumulate under specific conditions(53) . These precursor molecules may become activated as osteoblastic cells undergo phenotypic changes in the absence of increased lysyl oxidase steady-state mRNA levels. We believe that critical analysis of the possible role of lysyl oxidase activity in controlling collagen accumulation, and ultimately bone mineralization, are now required.


FOOTNOTES

*
This research was supported by National Institutes of Health Grant DE 11004 (to P. C. T.) and by a Fellowship awarded by the Federal Agency for Post-graduate Education, Brasilia, Brazil (to E. J. F.-F.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
To whom correspondence should be addressed. Boston University Goldman School of Graduate Dentistry, Boston University Medical Center, 700 Albany St., W-201E, Boston, MA 02118.

(^1)
The abbreviations used are: BAPN, beta-aminopropionitrile; bFGF, basic fibroblast growth factor; COL1A1, alpha1 type I collagen; DMEM, Dulbecco's modified Eagle's medium; BSA, bovine serum albumin fraction V; DRB, 5,6-dichloro-1beta-D-ribofuranosylbenzimidazole; NBS, newborn bovine serum; GAPDH, glyceraldehyde 3-phosphate dehydrogenase.


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