Adipogenic activity produced by hepatocyte-derived cell lines and by normal hepatocytes in primary culture.

Culture media conditioned by several hepatocyte derived cell lines were analyzed for their ability to stimulate adipose differentiation of the adipogenic cell line 1246. The results presented here show that culture media from HepG2 and Hep3B cell lines contain a high level of the activity, whereas media from hepatoma and hepato adenocarcinoma cell lines Huh-7, PLC/PRF/5, and SK-Hep-1 do not contain adipogenic activity. Conditioned medium from HepG2 cells also stimulated differentiation of 3T3-L1 cells and of rat epididymal adipocyte precursors in primary culture. Partial biochemical characterization of the adipogenic activity carried out using HepG2 conditioned medium indicates that the hepatocyte derived adipogenic factor has an apparent molecular weight between 445 and 232 kDa, is destroyed by treatment at 100 degrees C, with protease, with 2-mercaptoethanol and in acidic conditions. The activity is stable at alkaline pH. Culture media conditioned by normal rat hepatocytes in primary culture also contained adipogenic activity. In contrast, medium conditioned by primary culture of nonhepatocyte cell also isolated from liver was deprived of this activity. The data presented in this paper suggest that hepatocytes could be a physiological site of production of adipogenic activity.

Pedersen fetuin contains three adipogenic factors with distinct biochemical characteristics.

Crude Pedersen fetuin, derived from fetal bovine serum, contains adipogenic activity. Biochemical characterization was undertaken by following the differentiation of the 1246 adipogenic cell line. The present paper provides evidence that crude fetuin contains distinct proteins with adipogenic activity. By molecular sieve fractionation using Sephacryl S-300, the majority of adipogenic activity eluted in two distinct peaks, FI (molecular weight greater than 669 kDa) and FII (molecular weight ranging from 445 and 232 kDa). In addition a minor activity was found in a third peak, FIII (molecular weight around 69 kDa). Partial purification and biochemical characterization indicate that FI and FII are two distinct factors. FI has a PI higher than 9.4, is destroyed by alkaline treatment, and is stable when treated with acid. FII has a PI lower than 4.0, is alkali stable, but is destroyed completely by treatment with acid. Moreover, our data show that adipogenic factors are distinct from another protein alpha 2 macroglobulin known to be found in crude Pedersen fetuin. These results suggest that serum contains two large molecular weight proteins bearing adipogenic activity which could play an important role in the control of the adipose differentiation process.

Deeper 'Go' phase in rat fibroblasts affects the lag time required for T antigen induced DNA synthesis, but not the lag time required for SV40 T antigen expression.

In density-arrested rat 3YltsG125 cells, the time required for entry into S phase after serum stimulation is prolonged with increase in duration of the arrest. When these cells were infected with simian virus 40, the time required for expression of T antigen did not change, but the time required for entry into S phase was prolonged with increase in duration of the arrest. The extent of prolongation of the interval between T antigen expression and entry into S phase correlated well with the extent of the prolongation detected with serum stimulation. These observations suggest that: (1) expression of T antigen was not affected by the level of cellular preparedness for entry into S phase, i.e., it did not depend on cellular functions directly involved in the preparedness, and (2) T antigen induced cellular DNA synthesis, at least in part, by a mechanism similar to that of serum-induced DNA synthesis.

Influence of the deprivation of a single amino acid on cellular proliferation and survival in rat 3Y1 fibroblasts and their derivatives transformed by a wide variety of agents.

We compared proliferation and survival of various syngeneic transformed cell lines under conditions of depletion of 15 amino acids in Dulbecco-Eagle's medium. We used a normal fibroblast line 3Y1 and 22 transformed sublines of 3Y1 which had been induced by one of seven transforming agents--simian virus 40, mouse polyomavirus, adenovirus type 12, E1A gene of adenovirus type 12, cDNA of Harvey murine sarcoma virus, Rous sarcoma virus, or N-methyl-N'-nitro-N-nitrosoguanidine. Unlike other untransformed cells examined (mouse BALB/c-3T3 line, mouse NIH-3T3 line, and primary Fischer rat embryo fibroblasts), 3Y1 ceased to proliferate and accumulated in a viable state with a G1-phase DNA content under 14 singular deprivations of amino acid. None of the transformed 3Y1 lines completely arrested in the G1 phase of the cell cycle and each showed different levels of survival, depending on each transforming agent. As for transformed 3Y1 cells induced by a given virus or a given transforming gene, any one of the three sublines shared the same trend with respect to proliferation and survival. Transformed derivatives induced by N-methyl-N'-nitro-N-nitrosoguanidine showed almost the same trend in proliferation, but the patterns of survival were not uniform. Our observations suggest that the unique responses of 3Y1 to amino acid depletion are differently modified by different transforming agents.

Simian virus 40 compensates a cellular mutational defect of a serum-dependent function controlling cell cycle progression in the G2 phase.

Rat 3Y1tsF121 fibroblasts are arrested in the G2 phase at the nonpermissive temperature due to a temperature-sensitive (ts) defect, and the G2 arrest is overcome at the nonpermissive temperature by the addition of a large dose of fresh serum. When the G2-arrested cells which had been exposed to the nonpermissive temperature for 12 hr were shifted down to the permissive temperature, most divided within 12 hr. When the cultures prepared in parallel were infected with simian virus 40 (SV40) at the nonpermissive temperature, the G2-arrested cells divided as early as 6 hr after the expression of T antigen. The G2-arrested cells, which had been exposed to the nonpermissive temperature for 36 hr, lost both the ability to restore the G2 and M traverse at the nonpermissive temperature after the addition of fresh serum and the reversibility of the arrest upon shift down to the permissive temperature. However, SV40 induced these cells to divide at the nonpermissive temperature, as in the case of the reversibly arrested cells. A small t-antigen-deletion mutant (dl-884) also induced both types of the G2-arrested cells to divide at the nonpermissive temperature. These results suggest that (1) SV40 compensates or activates, in the G2 phase, the function regulating G2 and M transition by serum; (2) SV40 induces restoration of the irreversible G2 arrest; and (3) small t antigen is not responsible for these activities of SV40.

Serum-dependent regulation of proliferation of cultured rat fibroblasts in G1 and G2 phases.

We reported that: (i) 3Y1tsF121 cells, a temperature-sensitive (ts) mutant of rat 3Y1 fibroblasts, are reversibly arrested either in the G1 or in the G2 phase, at the nonpermissive temperature. (ii) Cells retain the ability to resume proliferation at the permissive temperature after prolonged arrest in the G1 phase (for 5 days), whereas they lose it after prolonged arrest in the G2 phase (over 24 h). (iii) The G1 arrest is overcome at the nonpermissive temperature by the addition of fresh serum (H. Zaitsu and G. Kimura (1984) J. Cell. Physiol. 119, 82; (1985) J. Cell. Physiol. 124, 177). In the present study, the G2 arrest was overcome by exposing the cells to fresh serum, at the nonpermissive temperature. The G2 arrest occurred only at a higher cell density than that of the G1 arrest. The efficiency of the overcome was higher in the case of the G2 arrest than in case of the G1 arrest. When cells synchronized at the G1/S border by aphidicolin at the permissive temperature were released from the block, they divided in the absence of serum, at the permissive temperature. Even if they had passed through the previous G2 phase in a very high concentration of fresh serum at the permissive temperature, mitotic cells did not enter the S phase in the absence of serum, even at the permissive temperature. When the cells arrested in the G1 phase (not in G0) due to the ts defect were incubated in the absence of serum at the permissive temperature, only 34% entered the S phase and only 15% divided. These results suggest that (i) the ts defect in 3Y1tsF121 limiting cellular proliferation in both the G1 and the G2 phases is probably due to a single mutational event, and is a serum-requiring event. (ii) Preparation of the serum-requiring event which is required for the G2 traverse is completed in the G1 phase, under ordinary conditions. (iii) However, cells are able to fulfill the serum-requiring event in the G2 phase as well as in the G1 phase when the preparation is below the required level. (iv) The commitment to DNA synthesis is not necessarily a commitment to cell division. (v) Cells are arrested in the G1 phase more safely and more effectively than in the G2 phase, by the serum-related mechanism.

Elongation and shortening of time required for entry into S phase after release from G1 and G0 arrests in temperature-sensitive mutants of rat 3Y1 cells.

Temperature-sensitive (ts) mutants of rat 3Y1 fibroblasts representing four separate complementation groups (3Y1tsD123, 3Y1tsF121, 3Y1tsG125, and 3Y1tsH203) are arrested mainly in the G1 phase when cells of randomly proliferating population at 33.8 degrees C are shifted to 39.8 degrees C (temperature arrest). We examined the time lag of the cellular entry into the S phase after release at 33.8 degrees C, both from the temperature arrest and from the arrest at 33.8 degrees C at a confluent cell density (density arrest). In the temperature-arrested cells, as the duration of temperature arrest increased, the time lag of entry into S phase after shift down to 33.8 degrees C was prolonged, in all four mutants. These observations suggest that the four different functional lesions, each causing arrest in the G1 phase, are also responsible for prolongation of the time lag of entry into the S phase in cells arrested in the G1 phase. The prolongation of the time lag in the temperature-arrested cultures was accelerated at a higher cell density, in medium supplemented with a lower concentration of serum, and at a higher restrictive temperature. In the density-arrested cells, as the duration of pre-exposure to 39.8 degrees C was increased, the time lag of entry into S phase at 33.8 degrees C after release from the arrest was drastically prolonged, in all four mutants. In 3Y1tsF121, 3Y1tsG125, and 3Y1tsH203, when the density-arrested cells were prestimulated by serum at 39.8 degrees C for various periods of time, the time lag of entry into S phase after release from the density arrest at 33.8 degrees C was initially shortened, and then, prolonged progressively as the period of prestimulation increased. These findings, taken together with other data, show that all four ts defects affect cells in states ranging from the deeper resting to mid- or late-G1 phase. It is suggested that events represented by these four mutants are required for entry into the S phase and normally operate in parallel but not in sequence in cells in states ranging from the deeper resting to the mid- or late-G1 phases, though they may affect each other.

Prolongation of duration of G2 arrest delays and finally blocks entry into M phase in contrast to stable and reversible G1 arrest: study of a G1/G2 temperature-sensitive mutant of rat 3Y1 fibroblasts.

Proliferation of 3Y1tsF121 cells was arrested in G1 and G2 phases after a shift up to 39.8 degrees C (restrictive temperature). Both arrests were reversible: after a shift down to 33.8 degrees C (permissive temperature), these cells effectively entered the next phases. However, the entry into M phase of the G2-arrested cells was delayed depending on the time in arrest. The G2-arrested cells finally became incapable of entering M phase with a prolonged incubation at 39.8 degrees C. Under the same condition, G1-arrested cells did not lose their ability to proliferate, and their delay of entry into S phase was slight. Therefore, cells in G2 phase are, in a sense, more unstable than the cells in G1 phase. These results also suggest that the time required for entry into M phase may depend on the preparedness for the initiation of M phase and, that it may be prolonged under the condition where the preparedness for entry into M phase is diminished.

Serum-independent regulation of initiation of DNA synthesis relating to temperature-sensitive defect in rat 3Y1tsD123 fibroblasts and its compensation by simian virus 40.

Randomly proliferating 3Y1tsD123 cells are arrested in G1 phase within 24 h after a shift up to 39.8 degrees C (temperature arrest), yet the density-arrested cells (prepared at 33.8 degrees C) enter S phase at 39.8 degrees C with serum stimulation, with or without preexposure to 39.8 degrees C for 24 h (Zaitsu and Kimura 1984a). When the density-arrested 3Y1tsD123 cells were preexposed to 39.8 degrees C for 96 h, they lost the ability to enter S phase at 39.8 degrees C by serum stimulation and required a longer lag time to enter S phase at 33.8 degrees C by serum stimulation than did the cells not preexposed to 39.8 degrees C. Simian virus 40 induced cellular DNA synthesis at 39.8 degrees C in the density-arrested 3Y1tsD123 preexposed to 39.8 degrees C for 96 h. In the absence of serum after a shift down to 33.8 degrees C, the temperature-arrested 3Y1tsD123 cells entered S phase and then divided once. We postulate from these results that (1) the ts defect in 3Y1tsD123 is involved in a serum-independent process. Once this process is accomplished, its accomplishment is invalidated slowly with preexposure to 39.8 degrees C. This and the serum-dependent processes occur in parallel but not necessarily simultaneously. The accomplishment of both (all) processes is required for the initiation of S phase. The density-arrested 3Y1tsD123 cells have accomplished the serum-independent process related to the ts defect, but have not accomplished serum-dependent processes. In case of the temperature-arrested 3Y1tsD123 cells, the reverse holds true. The lag time for entry into S phase depends on the preparedness for the initiation of DNA synthesis (on the extent of accomplishment of each of all processes required for entry into S phase). (2) To induce cellular DNA synthesis, simian virus 40 stimulates directly the serum-independent process. However, we do not rule out the possibility that simian virus 40 stimulates serum-dependent processes simultaneously.

Advance toward S phase and retreat toward deeper "G0" states in resting 3Y1 cells with environmental changes.

To elucidate conditions which affect the lag time for resting cells to enter S phase after serum stimulation, we used a wild-type 3Y1 rat fibroblast line and four temperature-sensitive mutants of 3Y1 (3Y1tsD123, 3Y1tsF121, 3Y1tsG125, and 3Y1tsH203). Among these five lines, in only tsG125 cells was there an obviously prolonged lag time with increase in time in resting state at 33.8 degrees C. The resting wild-type 3Y1 cells, preexposed to 39.8 degrees C, also showed a prolongation of lag time. The prolongation in tsG125 had a certain limit. Preexposure to 39.8 degrees C before serum stimulation accelerated such prolongation in tsG125 to its limit, but did not change the limit, per se. Resting tsG125 cells stimulated by serum at 39.8 degrees C, did not enter S phase, yet they did advance toward S phase. When they were kept at 39.8 degrees C, they retreated toward a deeper resting state ("G0") with time. These retreats correlated with the decrease in stimulating activity in the culture media. About 20% of the resting tsG125 cells stimulated by serum at 39.8 degrees C were committed to enter S phase, when the extent of commitment was examined at 33.8 degrees C. Most of the tsG125 cells committed at 33.8 degrees C did not enter S phase, when the extent of commitment was examined at 39.8 degrees C. More cells were committed after stimulation at 33.8 degrees C than at 39.8 degrees C, when the test was done at 33.8 degrees C. We suggest that resting cells may be reversibly changed within range of resting states, in either direction, that is, advance toward S phase or retreat toward deeper "G0." These changes may be determined by alterations in the balance between synthesis and decay of the preparedness for the initiation of DNA synthesis caused by cellular response to environmental changes (e.g., medium activity, temperature, etc.). The ts defect in tsG125 may affect the cell cycle progression, both before and after commitment by serum.

Arrest states in a set of mutants of rat 3Y1 cells temperature-sensitive for entering S phase.

Four temperature-sensitive (ts) mutants of rat 3Y1 cells (3Y1tsD123, 3Y1tsF121, 3Y1tsG125, and 3Y1tsH203) are arrested at 39.8 degrees C mainly with a 2N DNA content (temperature-arrested cells). The states of these cells were compared with findings in case of cells arrested at 33.8 degrees C at saturation density (density-arrested cells), with regard to the ability to enter S phase after release from arrest or after serum stimulation at 39.8 degrees C. With the 3Y1tsD123, the ts defect is an event which seems essential for the initiation of S phase and occurs after mitosis but not after release from the density arrest. The defect in 3Y1tsF121 related to the efficiency of utilization of serum component(s). In case of 3Y1tsG125, the state of temperature arrest appeared to locate between the state of density arrest and the beginning of S phase. There was no significant difference between the density- and the temperature-arrested cells, in case of 3Y1tsH203.