In vitro characteristics of the lipid-filled interstitial cell associated with postnatal lung growth: evidence for fibroblast heterogeneity.

This study explores the in vitro modulation of the lipid-filled phenotype of the lipid interstitial cell (LIC) isolated from the developing rat lung. Isolated LIC lose their cytoplasmic lipid droplets when cultured in fetal bovine serum (FBS) but retain their potential for lipid storage, since they rapidly reaccumulate lipid when subcultured in neonatal rat serum (NRS) and to a lesser extent in adult rat serum (ARS). The return of LIC to a lipid-filled state may not represent cell differentiation, since it occurs in the presence of bromodeoxyuridine. NRS contains twice the free fatty acids (FFA) of FBS and ARS, and doubling the FFA concentration of FBS and ARS increases LIC storage lipids. Serum triglyceride (TG) is 10 times higher in ARS and 23 times higher in NRS than in FBS. Since LIC lipoprotein lipase (LPL) activity is in the range of 3T3-L1 adipocytes (0.56 vs. 1.72 units/mg DNA), the LIC has the potential of incorporating serum lipoprotein-triglyceride. The LPL activity of LIC is 9-12 times that of fetal and adult rat lung fibroblasts and 50 times that of human lung, trachea, or skin fibroblasts; LIC are probably a source of endothelial LPL in the developing lung. The response of LIC and ARLF cyclic-AMP to hormones known to influence lipid synthesis or degradation showed that: only LIC responded to glucagon; prostaglandin E1 was a more potent stimulus to LIC; isoproterenol was a more potent stimulus to ARLF; and neither cell responded to ACTH. The unique nature of LIC tends to support further the concept of fibroblast heterogeneity within tissues.

Protein turnover and proliferation. Turnover kinetics associated with the elevation of 3T3-cell acid-proteinase activity and cessation of net protein gain.

1. At least 95% of the total protein of A31-3T3 cell cultures undergoes turnover. 2. First-order exponential kinetics were used to provide a crude approximation of averaged protein synthesis, Ks, degradation, Kd, and net accumulation, Ka, as cells ceased growth at near-confluent density in unchanged Dulbecco's medium containing 10% serum. The values of the relationship Ka = Ks - Kd were : 5%/h = 6%/h - 1%/h in growing cells, and 0%/h = 3%/h - 3%/h in steady-state resting cells. 3. As determined by comparison of the progress of protein synthesis and net protein accumulation, the time course of increase in protein degradation coincided with the onset of an increase in lysosomal proteinase activity and decrease in thymidine incorporation after approx. 2 days of exponential growth. 4. After acute serum deprivation, rapid increases in protein degradation of less than 1%/h could be superimposed on the prevailing degradation rate in either growing or resting cells. The results indicate that two proteolytic mechanisms can be distinguished on the basis of the kinetics of their alterations. A slow mechanism changes in relation to proliferative status and lysosomal enzyme elevation. A prompt mechanism, previously described by others, changes before changes in cell-cycle distribution or lysosomal proteinase activity. 5. When the serum concentration of growing cultures was decreased to 1% or 0.25%, then cessation of growth was accompanied by a lower steady-state protein turnover rate of 2.0%/h or 1.5%/h respectively. When growth ceased under conditions of overcrowded cultures, or severe nutrient insufficiency, protein turnover did not attain a final steady state, but declined continually into the death of the culture.

Protein turnover and proliferation. Failure of SV-3T3 cells to increase lysosomal proteinases, increase protein degradation and cease net protein accumulation.

The contrasting control of lysosomal proteinases, protein turnover and proliferation was studied in 3T3 and SV-3T3 (SV-40-virus-transformed 3T3) cells. 1. In 3T3 cells, net protein accumulation proceeded from 5%/h (doubling time, T(d)=14h) in growing cells to 0%/h as cells became quiescent. SV-3T3 cells never ceased to gain protein, but rather decreased their protein accumulation rate from 6-7%/h (T(d)=10-12h) to 2%/h (T(d)=35-40h) just before culture death in unchanged medium. 2. In both cell types the rates of protein synthesis per unit of protein (a) were proportional to the initial serum concentration from 0 to 6%, and (b) declined under progressive depletion of undefined serum growth factors. In depleted growth medium, leucine incorporation per unit of protein in 3T3 and SV-3T3 cells declined to almost equal synthetic rates while the 3T3 cell existed in a steady state of zero net gain, and the SV-3T3 cell continued to gain protein at a rate of 2%/h. 3. Whereas a large fraction of the control of 3T3-cell net protein accumulation can be accounted for by an increase in degradation from 1%/h to 3%/h, the SV-3T3 cell did not exhibit a growth-related increase in degradation appreciably above 1%/h. 4. Thus, by using first-order kinetics, the continued net protein accumulation of the transformed cell can be accounted for by a failure to increase protein degradation, whereas fractional synthesis can be made to decline to a rate similar to that in the quiescent non-transformed cell. 5. Upon acute serum deprivation, both cell types similarly exhibited small rapid increases in proteolysis independent of cell growth state or lysosomal enzyme status. 6. The 3T3 cell increased its lysosomal proteinase activity in conjunction with increase in the growth-state-dependent proteolytic mechanism; however, the SV-3T3 cell failed to increase lysosomal proteinases or the growth-state-dependent proteolytic mechanism.