Kumara-Siri M H, Surks M I
J Biol Chem. 1985 Nov 25;260(27):14529-37.
3,5,3'-Triiodo-L-thyronine (T3) regulates the growth rate and GH production of cultured GC cells, a rat pituitary tumor cell line. We have previously demonstrated a parallel increase in cellular content of DNA and nuclear T3 and glucocorticoid receptors during the DNA synthesis (S) phase of the GC cell growth cycle. To determine the relationship between the increase in nuclear hormone receptors and GH production in S-phase cultures, we measured the synthesis rate of GH by pulse-labeling with [3H]leucine and immunoprecipitation as well as the relative concentration of GH mRNA by dot hybridization employing formaldehyde-treated cytoplasm and GH cDNA. Total protein synthesis was similar in S-phase and asynchronous cultures. However, in comparison to asynchronous cultures, S-phase cells had an increased GH synthesis rate, p less than 0.005 (from 13,430 +/- 609 to 19,150 +/- 1160 cpm/10(6) cells/2 h) and increased GH mRNA, p less than 0.001 (from 7.2 +/- 1.2 to 14.5 +/- 1.5 relative A units). The S-phase-associated augmentation in GH production did not appear to result from a decrease in ADP-ribosylation induced by 2 mM thymidine treatment which was utilized for the S-phase synchronization. To determine whether increased GH mRNA and GH synthesis in S-phase was associated with an increase in synthesis of GH mRNA, we measured the incorporation of [3H]uridine into GH mRNA by incubating partially synchronized S-phase cells with [3H]uridine and isolating 3H-labeled GH mRNA by hybridization to GH cDNA immobilized on nitrocellulose filters. Total RNA synthesis was similar in asynchronous, S-phase and G1 cell populations. However, the mean incorporation of [3H]uridine into GH mRNA of S-phase cultures was decreased to 52, 59, and 61% (counts/min of GH mRNA/10(6) cells), 49, 59, and 65% (ppm of total RNA), and 64 and 69% (ppm of poly(A)+ RNA) of asynchronous cultures. Our studies show further that the decrease in [3H]uridine incorporation into GH mRNA did not result from a cell cycle specific change in efficiency of hybridization or exclusively to an S-phase associated increased rate of degradation of GH mRNA. Thus, despite increased nuclear T3 and glucocorticoid receptors and, increased GH mRNA and GH synthesis, the synthesis rate of GH mRNA appears decreased in S-phase GC cells.(ABSTRACT TRUNCATED AT 400 WORDS)
3,5,3'-三碘-L-甲状腺原氨酸(T3)可调节培养的GC细胞(一种大鼠垂体肿瘤细胞系)的生长速率和生长激素(GH)分泌。我们之前已经证明,在GC细胞生长周期的DNA合成(S)期,细胞内DNA以及细胞核内T3和糖皮质激素受体的含量会同时增加。为了确定细胞核激素受体增加与S期培养物中GH分泌之间的关系,我们通过用[3H]亮氨酸脉冲标记和免疫沉淀法测量了GH的合成速率,并通过使用经甲醛处理的细胞质和GH cDNA进行点杂交来测量GH mRNA的相对浓度。S期和非同步培养物中的总蛋白质合成相似。然而,与非同步培养物相比,S期细胞的GH合成速率增加,p<0.005(从13,430±609增至19,150±1160 cpm/10(6)细胞/2小时),且GH mRNA增加,p<0.001(从7.2±1.2增至14.5±1.5相对A单位)。S期相关的GH分泌增加似乎并非由用于S期同步化的2 mM胸苷处理诱导的ADP-核糖基化减少所致。为了确定S期GH mRNA和GH合成增加是否与GH mRNA合成增加有关,我们通过将部分同步化的S期细胞与[3H]尿苷一起孵育,并通过与固定在硝酸纤维素滤膜上的GH cDNA杂交来分离3H标记的GH mRNA,从而测量了[3H]尿苷掺入GH mRNA的情况。非同步、S期和G1期细胞群体中的总RNA合成相似。然而,S期培养物中[3H]尿苷掺入GH mRNA的平均量分别降至非同步培养物的52%、59%和61%(GH mRNA计数/分钟/10(6)细胞)、49%、59%和65%(总RNA的百万分率)以及64%和69%(聚腺苷酸+RNA的百万分率)。我们的研究进一步表明,[3H]尿苷掺入GH mRNA的减少并非由杂交效率的细胞周期特异性变化或仅由S期相关的GH mRNA降解速率增加所致。因此,尽管细胞核内T3和糖皮质激素受体增加,且GH mRNA和GH合成增加,但S期GC细胞中GH mRNA的合成速率似乎下降了。(摘要截短于400字)
