Processing of procollagen types III and I in cultured bovine smooth muscle cells

The processing of type III and type I procollagen molecules in cultured bovine aortic smooth muscle cells was investigated. The molecular identities of the processing intermediates of type III and type I procollagen were characterized by analysis of the radioactive collagenous components using mammalian collagenase and pepsin digestions and cyanogen bromide peptide mapping. The results indicate that the processed intermediates for procollagen type III and type I are their respective pC components. Although the processing pathways for both collagen types are the same, data from pulse-chase experiments suggest that the rates at which the processing occurs are different. Type I procollagen is processed more rapidly to its intermediate than is type III procollagen. The type I pC intermediate is almost completely processed to alpha-chains and a significant portion of these fully processed molecules remains in a soluble form even after 11 h. In the same time period, the type III pC intermediate is slowly converted to alpha-chains. Since beta-aminopropionitrile was not employed in these studies, significant accumulation of collagen chains into the insoluble extracellular matrix was observed during the chase period.     

Modulation of types I and III procollagen synthesis at various stages of arterial smooth muscle cell growth in vitro

Collagen synthesis was monitored in cultures of rabbit arterial smooth muscle cells (SMC). Both the rate of collagen synthesis per cell and collagen synthesis as a percent of total protein synthesis were measured at specific intervals from 1 to 14 days after inoculation of smooth muscle cells. The proportions of types I and III collagen present in the conditioned incubation medium and in the cell layer were also examined. After inoculation the cells displayed population expansion typical of SMC in which growth slowed but did not cease after the cells attained confluence. Collagen synthesis rates, expressed as [14C]hydroxyproline per cell, were eight-fold higher in preconfluent cells. In these cultures collagen accounted for more than 20% of the newly synthesized, 14C-labeled protein present as trichloroacetic acid (TCA)-insoluble material in 24 h culture media. In post-confluent cultures, this percentage was reduced to about 7% of the total protein synthesized. Synthesis rates of both collagen and non-collagen protein decreased with increasing time after inoculation. However, the rate of decline of collagen synthesis was three times greater than that seen for non-collagen protein. Early cultures synthesized relatively more type I than type III procollagen. The type I to type III ratio was highest at day 3 and declined after that time to day 14. While the synthesis of both types decreased with increasing age, type I declined at a greater rate resulting in a predominance of type III procollagen secretion by older cultures. We conclude that protein synthesis in general and collagen synthesis in particular are quantitatively and qualitatively dependent upon the growth stage of SMC in vitro.     

Cell density and proliferation modulate collagen synthesis and procollagen mRNA levels in arterial smooth muscle cells.

Collagen synthesis and procollagen mRNA levels were determined and compared in (1) sparse, rapidly proliferating smooth muscle cells (SMC); (2) postconfluent, density-arrested SMC; and (3) sparse, nonproliferating (mitogen-deprived) rabbit arterial SMC. Collagen synthesis per SMC was decreased by 70% in postconfluent versus proliferating cells. However, relative collagen synthesis, expressed as the percentage of total protein synthesis, increased from 3.7% in sparse cultures to approximately 7% in postconfluent cultures. Slot blot analyses demonstrated that the relative steady state alpha 1(I) and alpha 1(III) procollagen mRNA levels were also increased in postconfluent cultures when compared to sparse cultures. As with collagen synthesis per cell, the mRNA levels per cell for types I and III procollagen in postconfluent cells, determined by densitometry of blots, were likewise approximately half that found in sparse, proliferating cells. In a separate study to determine if cell-cell contact was necessary for eliciting these changes in collagen synthesis, we determined collagen synthesis in mitogen-deprived and proliferating SMC cultures at low density. Mitogen-deprived cultures synthesized only 10% the amount of collagen produced (per cell) by proliferating cultures in 10% fetal bovine serum. Relative collagen synthesis in proliferating and nonproliferating cultures was 5.0 and 8.3%, respectively. These results demonstrate elevated collagen synthesis, per cell, by proliferating cultures compared with nonproliferating cultures, regardless of whether cells were rendered quiescent by density arrest or by mitogen deprivation. Results also suggest a pretranslational mechanism for the regulation of collagen synthesis in rabbit aortic smooth muscle cells.     

Processing of types I and III procollagen in Ehlers-Danlos syndrome type VII.

The processing of types I and III procollagen was studied in skin fibroblast cultures from type VII A and B of the Ehlers-Danlos syndrome [EDS] and age-matched controls. Synthesis of collagenous proteins was significantly increased in EDS type VII B, and the activities of prolyl-4-hydroxylase and galactosylhydroxylysyl glucosyltransferase were slightly increased in these cell lines, reflecting increased biosynthesis of collagen. The synthesis of collagenous proteins was close to normal in EDS type VII A cells. The synthesis of type III procollagen per cell was increased, as also was the ratio of immunoreactive type III procollagen to total collagen production. The activity of type I procollagen amino-terminal proteinase was decreased in skin fibroblasts of type VII A and normal in those of type VII B relative to cell protein or DNA. Type III amino-terminal proteinase activity was of a level found in normal cells when expressed relative to the protein or DNA, and the release of type III amino-terminal propeptides was nevertheless not disturbed in these EDS type VII cell cultures. The results show that only the conversion of type I procollagen is defective in EDS type VII, and no general defect in procollagen processing can be found in EDS type VII as has been suggested in the case of dermatosparaxis, a connective tissue disorder in animals caused by disturbed procollagen conversion.     

Substratum influence on collagen and fibronectin biosynthesis by arterial smooth muscle cells in vitro

Collagen, fibronectin, and nonfibrous protein biosynthesis were examined in cultures of rabbit arterial smooth muscle cells grown on tissue culture plastic precoated either with rabbit plasma fibronectin or bovine serum albumin. Cells seeded into fibronectin-coated wells appeared to reach confluence more quickly than counterparts grown on albumin-coated surfaces. Measurement 3H-thymidine incorporation into DNA by these cultures suggested that this was probably a consequence of more rapid and efficient cell attachment rather than an increased rate of proliferation of smooth muscle cells grown on fibronectin. In preconfluent cultures, the rates of collagen and fibronectin biosynthesis were reduced to 34 and 57%, respectively, on a per-cell basis in cultures grown on fibronectin-coated surfaces compared with cells grown on albumin-coated plasticware. In preconfluent cultures grown on fibronectin-coated surfaces, a greater percentage of the total fibronectin synthesized was incorporated into the cell layer. The distribution of newly synthesized collagen between culture medium and cell layer, however, was not affected by alteration of substratum composition. There was no difference in the rate of synthesis of noncollagen proteins between the two groups of preconfluent cells. In postconfluent cultures the rates of collagen and fibronectin biosynthesis were equivalent in both albumin- and fibronectin-treated cultureware. In preconfluent cultures, analyses of procollagens showed that the overall amounts of both types I and III procollagens were reduced in fibronectin-treated wells, indicating the reduction in collagen synthesis to be general and not type-specific. Although type V procollagen biosynthesis was not detected in either preconfluent group, it was found in postconfluent cultures. The reduction of fibronectin synthesis in cells grown in fibronectin-coated wells was significant as early as 4 hours after plating. Together, these findings suggest that cultured arterial smooth muscle cells are capable of deriving information from their substratum and regulating the biosynthetic rates of extracellular matrix components in response to the immediate needs of the cell.     

Characterization of the collagen chains synthesized by cultured smooth muscle cells derived from rhesus monkey thoracic aorta.

Five different collagen chains and one smaller collagenous fragment have been isolated from the collagens found in the combined cell layer and medium of rhesus monkey aortic smooth muscle cell cultures. The collagen chains which can be identified are alpha1 (III), alpha1(I), alpha2, A and B. The smaller collagenous peptide exhibits an apparent molecular weight of 45 000 and has been designated CP45 (Mayne, R., et al. (1977), Arch. Biochem. Biophys. 181, 462). Smooth muscle cells continue to synthesize the collagens from which these components are derived for at least eight passages in culture. At each passage the alpha1 (III) chain consistently represents about one-half of the total collagen which is recovered after initial fractionation by agarose gel chromatography. The results show that smooth muscle cells derived from rhesus monkey thoracic aorta are phenotypically stable for many generations in vitro.     

Complex regulation of collagen gene expression in cultured bovine aortic smooth muscle cells

Cultured bovine aortic smooth muscle cells display an increase in production of type I and type III collagen as a function of the number of days in second passage (Beldekas, J. C., Gerstenfeld, L. C., Sonenshein, G. E., and Franzblau, C. (1982) J. Biol. Chem. 257, 12552-12556). In this study, we report that the regulation of these events is highly complex and relates to the growth state of the cells. Cultures, seeded at 1.5 X 10(6) cells/75-cm2 flask, produced very little collagenous protein early when the cells were proliferating rapidly. As they approached confluence at day 6, collagen synthesis began to increase. Maximal collagen synthesis was observed at day 14. In contrast, the levels of the mRNAs for type I and type III collagen increased only up to the 10th day and thereafter decreased. Cell-free translation analyses indicated that the translational activity of the collagen mRNAs was increasing over the time course. These results suggest that both translational and pretranslational sites are involved in the control of collagen production by aortic smooth muscle cells, and that collagen synthesis is inversely related to the proliferative state of the cells in culture.     

Synthesis of procollagen by dental pulp cells from incisor in vitro.

Fibroblast-like cells were isolated from dental pulp of rabbit incisor, and were shown to synthesize and secrete procollagen. Analysis of the secreted procollagen and their CNBr peptides indicated that the prominent form was type I procollagen. Our results also suggested the presence of type III procollagen as a minor component synthesized by pulp cells in vitro.     

Synthesis of collagen by smooth muscle in the hyertrophic intestine

During hypertrophy of the small intestine of the guinea-pig at the oral side of an experimental stenosis, the individual intestinal segments do not increase in length but undergo a remarkable increase in weight (up to 7 times that of control segments). Concomitantly an increase in collagen content is found; this is usually larger than the increase in weight, and the concentration of collagen is therefore also increased. This effect is more noticeable in the muscle coat than in the wall as a whole. It is suggested, on the basis of histological observations, that some of this collagen is synthesized by smooth muscle cells.     

Phenotypic heterogeneity influences the behavior of rat aortic smooth muscle cells in collagen lattice

Phenotypic modulation of vascular smooth muscle cells (SMCs) in atherosclerosis and restenosis involves responses to the surrounding microenvironment. SMCs obtained by enzymatic digestion from tunica media of newborn, young adult (YA) and old rats and from the thickened intima (TI) and underlying media of young adult rat aortas 15 days after ballooning were entrapped in floating populated collagen lattice (PCL). TI-SMCs elongated but were poor at PCL contraction and remodeling and expressed less alpha2 integrin compared to other SMCs that appeared more dendritic. During early phases of PCL contraction, SMCs showed a marked decrease in the expression of alpha-smooth muscle actin and myosin. SMCs other than TI-SMCs required 7 days to re-express alpha-smooth muscle actin and myosin. Only TI-SMCs in PCL were able to divide in 48 h, with a greater proportion in S and G2-M cell cycle phases compared to other SMCs. Anti-alpha2 integrin antibody markedly inhibited contraction but not proliferation in YA-SMC-PLCs; anti-alpha1 and anti-alpha2 integrin antibodies induced a similar slight inhibition in TI-SMC-PCLs. Finally, TI-SMCs rapidly migrated from PCL on plastic reacquiring their epithelioid phenotype. Heterogeneity in proliferation and cytoskeleton as well the capacity to remodel the extracellular matrix are maintained, when SMCs are suspended in PCLs.     

Cell shape and arrangement of cultured aortic smooth muscle cells grown on collagen gels

Aortic smooth muscle cells (SMC) grown on conventional plastic culture dishes have morphological and functional properties of dedifferentiated cells in sub-culture. We examined the influence of collagen gels on the cell shape and arrangement. The cells grown on collagen gels showed a multilayered growth with formation of nodules. When the edge of the collagen gels was detached from the culture dish, the shape and arrangement of cells on the edge differed from that of the central, still attached region. The cells grown on floating collagen gels exhibited a spindle-like shape and were arranged in concentric circles. These findings suggest that the physical property of the substrate influences the cell shape and arrangement.     

Visualization of the uptake of high-density lipoprotein by rat aortic endothelial cells and smooth muscle cells in vitro

High-density lipoproteins (HDL) were conjugated to Fluorescein 1,1-dioctadecyl 3,3,3,3-tetramethylindocarbocyanine perchlorate (DiI) or colloidal gold for the investigation of ultrastructural aspects of binding and uptake of HDL by cholesterol-loaded cultured endothelial and smooth muscle cells from rat aorta. When cells were incubated for 2h at 4°C, HDL–DiI and HDL–gold conjugates were seen only on the cell surface. When cells were returned to incubation at 37°C for 5min, HDL–DiI appeared in the cytoplasm and colocalized with the fluorescent cholesteryl ester tag BODIPY-FL-C₁₂. HDL–gold conjugates appeared in the plasmalemmal invaginations and plasmalemmal vesicles. After incubation for 15min, most of the HDL–gold conjugates reappeared on the cell surface. After incubation for 30min, only a few conjugates were observed and they localized in lysosomal-like bodies. Quantitative data indicated that when the cholesterol-loaded cells were incubated at 4°C for 2h, the numbers of HDL–gold associated in clusters on the endothelial cell surface was 1.18 clusters/m. When cells were returned to incubation at 37°C for 5min, this value decreased to 0.7, increased again to 1.13 at 15min, and decreased to 0.29 at 30min. The numbers of clusters in the plasmalemmal invaginations were 0.06 clusters/m at 4°C for 2h, increased to 0.34 at 37°C for 5min and decreased gradually to 0.19 and 0.04 at 15 and 30min, respectively. The incidence of clusters in the plasmalemmal vesicles per non-nuclear cytoplasm was 0.01 clusters/m² at 4°C for 2h, increased significantly to 1.08 at 37°C for 5min, and decreased to 0.43 and 0.14 at 15 and 30min, respectively. This work supports that the plasmalemmal invaginations and plasmalemmal vesicles are linked to the HDL uptake in cholesterol-loaded aortic endothelial cells and smooth muscle cells.     

Treatment of porcine aortic smooth muscle cells with phorbol esters prevents nodulation in vitro.

Vascular smooth muscle cells exhibit a unique pattern of growth in culture. They have the capacity for multilayer growth and form large macroscopic nodules. We find that nodulation is inhibited in the presence of phorbol esters and that there is a concomitant decrease in the production of a 38 kd secreted protein associated with nodulation in porcine smooth muscle. Examination of the organization of actin filaments within the cells using a rhodamine phalloidin stain indicates that there is a rearrangement of actin filaments in response to phorbol esters. This rearrangement increases the number of attachment sites to the culture surface and may contribute to the inhibition of nodulation in smooth muscle cells by phorbol esters.     

Formation of collagen fibrils in vitro by cleavage of procollagen with procollagen proteinases

A new system was developed for studying the assembly of collagen fibrils in vitro. A partially purified enzyme preparation containing both procollagen N-proteinase and c-proteinase (EC 3.4.24.00) activities was used to initiate fibril formation by removal of the N- and C-propeptides from type I procollagen in a physiological buffer at 35-37 degrees C. The kinetics of fibril formation were similar to those observed for fibril formation with tissue-extracted collagen in the same buffer system, except that the lag phase was longer. The longer lag phase was in part accounted for by the time required to convert procollagen to collagen. Similar results were obtained when an intermediate containing the C-propeptide but not the N-propeptide was used as a substrate. Therefore, removal of the c-propeptide appeared to be the critical step for fibril formation under the conditions used here. The fibrils formed by enzymic cleavage of procollagen or pCcollagen appeared microscopically to be more tightly packed than fibrils formed directly from collagen under the same conditions. This impression was confirmed by the observation that the fibrils formed by cleavage of procollagen were stable to temperatures 1.5-2 degrees C higher than fibers formed from extracted collagen under the same conditions. When smaller amounts of procollagen proteinase were used, the rate of cleavage of procollagen to collagen was markedly reduced. The fibrils which formed under these conditions were up to 3 micrometers in diameter. Some appeared to contain branch points.     

In vitro study of smooth muscle cells on polycaprolactone and collagen nanofibrous matrices

Biodegradable polycaprolactone and collagen nanofibers were produced by electrospinning, with fiber diameters of around 300-700nm and features similar to the extracellular matrix of natural tissue. Human coronary artery smooth muscle cells (SMCs) seeded on nanofibrous matrices tend to maintain normal phenotypic shape and growth tends to be guided by the nanofiber orientation. The SMC and nanofibrous matrix interaction was observed by SEM, MTS assay, trypan blue exclusion method and laser scanning confocal microscopy. The results showed that the proliferation and growth rate of SMCs were not different on polycaprolactone (PCL) nanofibrous matrices coated with collagen or tissue culture plates. PCL nanofibrous matrices coated with collagen showed that the SMCs migrated towards inside the nanofibrous matrices and formed smooth muscle tissue. This approach may be useful for engineering a variety of tissues in various structures and shapes, and also to demonstrate the importance of matching both the initial mechanical properties and degradation rate of nanofibrous matrices to the specific tissue engineering.     

Quantitative assay of types I and III collagen synthesized by keloid biopsyes and fibroblasts.

Molecular sieve column chromatography was used to determine the amount of type I and III collagen synthesized by normal dermis and keloid biopsies and fibroblasts derived from these tissues. After incubation with radioactive proline, the collagen was extracted and separated into types I and III and then quantitated. There was no significant difference in the percent type III collagen synthesized by fresh keloid biopsies compared to normal dermis. Likewise, there was no significant difference in the percent type III collagen synthesized by keloid fibroblasts compared to normal dermal fibroblasts. However, fibroblasts from both keloid and normal dermis synthesized a lower percentage of type III collagen in cell culture compared to the original biopsies. These findings demonstrate that keloid collagen has the same type distribution as normal dermis and suggest that increased collagen synthesis in these lesions is not related to altered collagen types.     

Changes in inositol polyphosphate-sensitive calcium exchange in aortic smooth muscle cells in vitro

Cells that expressed the muscle-specific intermediate filament protein desmin were cultured from the aorta of Fischer 344 rats. When the cultured cells were extracted with digitonin, they accumulated 45Ca2+ from the incubation medium in a manner that was stimulated by ATP and released subsequently by exposure to the Ca2+ ionophore A23187. Ca2+ bound in the presence of ATP was also released by exposure to inositol 1,4,5-trisphosphate (IP3). Like contraction in some kinds of smooth muscle, IP3 released Ca2+ in either the absence or the presence of the ATPase-inhibitor ruthenium red. When the responsiveness of digitonin-extracted cells cultured from 3-, 12-, and 24-month-old rats was compared, cells from the youngest group released only about one-half as much Ca2+ as cells from the 12- or 24-month-old rats. The results suggest that in the rat there are changes during maturation in the responsiveness to inositol polyphosphates of intracellular compartments that sequester Ca2+ for stimulus-contraction coupling in the aortic smooth muscle cell. These changes, characterized in smooth muscle cells in vitro, might contribute to the way vascular responsiveness is regulated in vivo.     

Renin synthesis by canine aortic smooth muscle cells in culture

Angiotensin-I generating activity has been detected in homogenates of arterial tissue but it remains unclear whether this enzymatic activity results from the presence of renin itself or from the action of other proteases such as cathepsin D. In an assay system employing anephric dog plasma as substrate and buffered to pH 7.4, we detected angiotensin-I generating activity in homogenates of canine aortic smooth muscle cells. This enzymatic activity was in large part inhibitable by renin-specific antisera raised to pure canine renal renin. Immunofluorescent study of cultured arterial smooth muscle cells was also performed using renin specific antiserum. Granular cytoplasmic immunofluorescence was detected when specific antirenin serum was used but not when preimmune serum was employed. The addition of pure canine renin to the renin antiserum during staining suppressed the granular immunofluorescence confirming the specificity of staining. Finally, biosynthetic radiolabelling studies were performed. Immunoprecipitation of newly synthesized proteins with antirenin serum and staphylococcal protein A followed by gel electrophoresis and autoradiography demonstrated the synthesis of an immunoreactive protein with the molecular weight of renin. Pretreatment of the antirenin serum with pure canine renin resulted in the disappearance of this immunoreactive protein band. Thus these studies provide multiple lines of evidence to indicate the $\text{in}$$\text{situ}$ synthesis of renin by vascular smooth muscle cells.