The possible cyclic AMP-dependence of an early prereplicative event that determines mitosis in regenerating rat liver

The beta-adrenergic blocker dl-propranolol prevented a large proportion of regenerating rat liver cells from entering the mitotic phase of their first cell division cycle without affecting their ability to initiate or complete DNA replication. The drug, at a dose of 20 or 50 mg/kg of body weight, was most effective in reducing mitosis when injected between 1 and 2 hours after the proliferatively activating partial hepatectomy, which was 22 to 23 hours before the peak of DNA-synthetic activity. Propranolol also inhibited the early prereplicative surge of total liver cyclic AMP, which occurs shortly after partial hepatectomy, but this effect was not correlated to the mitosis-inhibiting activity. However, cyclic AMP or dibutyryl cyclic AMP completely reversed propranolol's mitosis-inhibiting action when injected between 1.5 and 2 hours (but not sooner or later) after partial hepatectomy, which was just before the total liver cyclic AMP content began to rise. Thus, there appears to be a transient, propranolol-inhibitable, probably cyclic AMP-initiated event in the early prereplicative development of rat hepatocytes that determines entry into mitosis rather than the initiation of DNA replication.     

The effects of thyroparathyroidectomy and 1,25 dihydroxyvitamin D3 on changes in the activities of some cytoplasmic and nuclear protein kinases during liver regeneration

Partial hepatectomy (HPX), which proliferatively activates the remaining liver cells, triggered two transient prereplicative surges in the total activities of cytoplasmic types I and II cyclic AMP-dependent protein kinase holoenzymes, and of nuclear catalytic subunits from cyclic AMP-dependent protein kinases. It also induced a transient prereplicative increase in the activities of a nuclear Ca2+-calmodulin-stimulable, protamine-phosphorylating protein kinase, and a nuclear poly(L-lysine)-phosphorylating, 105 kDa protein kinase. Thyroparathyroidectomy (TPTX) delayed and reduced the first surge and completely eliminated the second surge of both of the cytoplasmic cyclic AMP-dependent protein kinases, reduced the rises in the activity of nuclear catalytic subunits, and completely eliminated the surge of the Ca2+-calmodulin-stimulable protein kinase, but did not affect the surge of the nuclear 105 kDa protein kinase. The impairment of the responses of the two cyclic AMP-dependent protein kinases to HPX in TPTX rats was not accompanied by a rise in the level of heat-stable inhibitor of cyclic AMP-dependent protein kinase activity. One intraperitoneal injection of 1,25-dihydroxyvitamin D1 into TPTX rats immediately after HPX completely restored the post-HPX surges in the activity of type I cyclic AMP-dependent protein kinase, but the hormone, even in high doses, had little or not effect on the type II isoenzyme or the nuclear Ca2+-calmodulin-stimulable, protamine-phosphorylating enzyme.     

An examination of the roles of cyclic nucleotides in the initiation of cell proliferation.

The initiation of proliferative activity in proliferatively quiescent confluent monolayers of BALB/3T3 cell cultures by a fresh medium-serum replacement is independent of early (within minutes) fluctuations in total cellular cyclic AMP or cyclic GMP levels. However, the possibility of a later prereplicative cyclic AMP surge being involved in the initiation of DNA synthesis will be discussed.     

Effect of Trifluoperazine On Dna Synthesis During Liver Regeneration

Abstract. An intraperitoneal injection of the calcium-calmodulin blocker trifluoperazine into rats at 4 hr after a partial hepatectomy produced a strong inhibition of DNA synthesis observed at 24 hr after surgery; but when injection was administered at 20 hr after hepatectomy, it did not produce any effect on DNA replication. These observations indicate that trifluoperazine acted by blocking one or more events involved in triggering DNA replication but it did not affect on-going DNA synthesis. A more detailed study indicated that when trifluoperazine was injected at 4 hr after surgery, a 12 hr delay in the cytosolic calmodulin surge observed between 6 and 12 hr after partial hepatectomy (previous to initiation of DNA replication) and also in the starting of DNA synthesis was produced. These findings suggest that the pre-replicative surge of cytosolic calmodulin could be involved in triggering DNA synthesis observed after partial hepatectomy.     

Effect of trifluoperazine on DNA synthesis during liver regeneration

An intraperitoneal injection of the calcium-calmodulin blocker trifluoperazine into rats at 4 hr after a partial hepatectomy produced a strong inhibition of DNA synthesis observed at 24 hr after surgery; but when injection was administered at 20 hr after hepatectomy, it did not produce any effect on DNA replication. These observations indicate that trifluoperazine acted by blocking one or more events involved in triggering DNA replication but it did not affect on-going DNA synthesis. A more detailed study indicated that when trifluoperazine was injected at 4 hr after surgery, a 12 hr delay in the cytosolic calmodulin surge observed between 6 and 12 hr after partial hepatectomy (previous to initiation of DNA replication) and also in the starting of DNA synthesis was produced. These findings suggest that the pre-replicative surge of cytosolic calmodulin could be involved in triggering DNA synthesis observed after partial hepatectomy.     

Involvement of cyclic GMP in the initial stage of hepatocytes proliferation.

A transient rise in cyclic guanosine 3' : 5' monophosphate (c-GMP) in the liver was observed in rats in vivo 10--20 min after partial hepatectomy. A similar increase in c-GMP in the liver was also found in rats in vivo 15 min after infusion of TGH solution (a mixture of triiodothyronine, glucagon, and heparin). In both cases, inductions of ornithine decarboxylase [EC 4.1.1.17] and tyrosine aminotransferase [EC 2.6.1.5] were found 4 hr after the beginning of the experiments. Later, 22 hr after the surgical intervention or hormone infusion, thymidine kinase [EC 2.7.1.21] was activated and liver slices were able to incorporate [3H]thymidine into DNA. These biochemical phenomena were observed commonly in regenerating liver as well as in the liver of rats infused with TGH solution. c-GMP, but not c-AMP, could induce ornithine decarboxylase and tyrosine aminotransferase in isolated, perfused liver.     

Prereplicative changes in the soluble calmodulin of isoproterenol-activated rat parotid glands

Cells of rat parotid glands were maximally stimulated to initiate DNA synthesis by injecting into the animal a single dose of 25 to 150 mg of isoproterenol/ kg of body weight. During the 18- to 21-hr prereplicative period following injection of the highest dose of the drug, there were two predominant and transient redistributions of calmodulin from the bound to the soluble form, which tripled the level of soluble calmodulin at 3 hr and again at 18 hr just before the initiation of DNA synthesis. A small (50%) increase in total calmodulin was observed only during the early (3-h) prereplicative surge of soluble calmodulin. The late, pre-DNA-synthetic surge of soluble camodulin and the initiation of DNA synthesis were both prevented in rats that lacked their parathyroid-thyroid gland complex and had been hypocalcemic for 48 or 72 hr. Unlike the effect of high doses of isoproterenol, low doses (e.g., 25 mg/kg body weight) of the β-adrenergic drug could maximally stimulate DNA synthetic activity without the later pre-DNA-synthetic surge of soluble calmodulin, suggesting that any apparent correlation between the level of calmodulin and DNA synthesis may be spurious and that an actual increase in the level of soluble calmodulin just before the onset of DNA synthesis was not a prerequisite for DNA synthetic activity in parotid cells.     

The cyclic AMP-dependent initiation of DNA synthesis by T51B rat liver epithelioid cells.

The brief rise in the cellular cyclic AMP content which occurs late in the prereplicative phases of rat hepatocytes in vivo and T51B rat liver epitheloid cells in vitro seems to be necessary for the initiation of DNA synthesis. Thus, the extracellular calcium-deprivation in T51B rat liver cells in culture which induces a late G-1 block is rapidly reversible (cells surge into S phase within one hour) either by creating a cyclic AMP surge by the addition of calcium or 3-isobutyl-1-methyl xanthine (a cyclic 3',5'-nucleotide phosphodiesterase inhibitor) or by the exogenous addition of low concentrations of cyclic AMP itself (i.e., 10(-8)-10(-5) M). On the other hand, prevention of the calcium-induced cyclic AMP surge by imidazole (a cyclic 3',5'-nucleotide phosphodiesterase activator) blocked the initiation of DNA synthesis by the calcium-deprived T51B cells.     

The regulation of cell proliferation by calcium and cyclic AMP

Calcium, in partnership with cyclic AMP, controls the proliferation of non-tumorigenic cells in vitro and in vivo. While it does not seem to be involved in the proliferative activation of cells such as hepatocytes (in vivo) or small lymphocytes (in vitro), it does control two later stages of prereplicative (G1) development. It must be one of the very many regulatory and permissive factors affecting early prereplicative development, because severe calcium deprivation reversibly arrests some types of cell early in the G1 phase of their growth-division cycle in vitro. However, calcium more specifically and much more often regulates a later (mid or late G1) stage of prereplicative development. Thus, regardless of its severity or the type of cell, calcium deprivation in vitro or in vivo reversibly stops proliferative development at that part of the G1 phase in which the cellular cyclic AMP content transiently rises and the synthesis of the four deoxyribonucleotides begins. The evidence points to calcium and the cyclic AMP surge being co-generators of the signal committing the cell to DNA synthesis. The evidence is best explained so far by the cyclic AMP surge causing a surge of calcium ions which combine with molecules of the multi-purpose, calcium-dependent, regulator protein calmodulin (CDR) somewhere between the cell surface and the cytosol. The resulting Ca-calmodulin complexes then stimulate many different (and possibly membrane-associated) enzymes such as protein kinases, one of which produces the DNA-synthetic initiator. Calcium has little or no influence on the proliferation of tumor cells. Some possible explanations of this very important loss of control are considered.     

Prereplicative enzymic changes in regenerating rat liver.

After partial hepatectomy in rats, the following changes in enzymic activities were observed in the remnant liver during the prereplicative period. In the initial period of the prereplicative process, soon after removal of part of the liver, ornithine decarboxylase [EC 4.1.1.17] and IMP dehydrogenase [EC 1.2.1.14] increase. Subsequently, for entry into the S period, thymidine kinase [EC 2.7.1.75] increases simultaneously with increase in the intracellular cyclic AMP level and decrease in its phosphodiesterase [EC 3.1.4.17].     

A role for amino acids in the induction of deoxyribonucleic acid synthesis in liver

Nuclear DNA synthesis and mitosis are induced in the parenchymal liver cells of unoperated rats after a shift from a protein-free to a protein- or amino acid-containing diet. Protein or amino acids in the preparatory mash block the responses of the liver to the second diet. The formation of liver DNA after the nutritional shift begins several hours earlier than after partial hepatectomy. A small number of changes in the hepatic levels of amino acids and other ninhydrin-positive compounds result from the nutritional shift and some of these changes occur as well after 70% hepatectomy and the infusion of intact rats with the TAGH solution.     

Stimulation of autophosphorylation of liver cell membrane proteins by calcium and partial hepatectomy

Partial hepatectomy in the rat stimulated the phosphorylation of three proteins (Mr 100,000, 48,000, and 35,000) in the plasma membranes of the proliferatively activated cells of the liver remnant. The autophosphorylation of these plasma membrane proteins began to rise about 8 hours after surgery, peaked at 14 hours, and then returned to the original low level by 24 hours. This increase in autophosphorylation was not evident in isolated plasma membranes from other proliferatively activated liver cells, such as those in fetal liver or hepatomas. The protein kinase responsible for the phosphorylation of the three membrane proteins was activated by calcium but appeared both cyclic-AMP- and calmodulinindependent.     

Effect of alpha-adrenergic blockers on calmodulin association with the nuclear matrix of rat liver cells during proliferative activation

A transient peak of cytosolic calmodulin (CaM) was produced during the prereplicative phase of rat liver cell proliferation following partial hepatectomy. After accumulating in the cytosol, CaM apparently translocated into the nuclei, associating with the nuclear matrix. The administration of alpha 1-adrenergic blockers to hepatectomized rats prevented the association of CaM with the nuclear matrix without affecting the increase in the total nuclear CaM. The inhibitory effect of the alpha 1-antagonists was reversed by the simultaneous injection of the alpha-agonist noradrenaline. Since the activation of alpha 1-adrenergic receptors results in the release of Ca2+ from endoplasmic reticulum stores, the results suggest that the association of CaM with the nuclear matrix during proliferative activation is mediated by Ca2+ released from endoplasmic reticulum and show that the association with the matrix is independent of its intranuclear accumulation.     

A possible role for cyclic AMP in the initiation of DNA synthesis by isoproterenol-activated parotid gland cells

An intraperitoneal injection of the β-adrenergic agonist dl-isoproterenol hydrochloride (100 mg/Kg body weight) into a rat caused an early, very large (400-fold) cyclic AMP surge (peaking at 10 minutes) in the parotid gland which was followed by a second, much smaller (two-fold) surge 12 to 16 hours later. DNA synthesis began about 16 to 20 hours after the isoproterenol injection and peaked between 24 and 28 hours. The maximum level of DNA-synthetic activity at 24 hours was correlated positively to the magnitude of the small cyclic AMP surge at 12 hours, but not to the size of the much larger cyclic AMP surge at 10 minutes. An intraperitoneal injection of dl-propranolol hydrochloride (59 mg/Kg body weight) at 8 hours after isoproterenol injection abolished the second cyclic AMP surge at 12 hours and markedly (65-75%) reduced the incorporation of [³H]-thymidine into DNA. Injection of dibutyryl cyclic AMP (6.3 mg/Kg body weight) and theophylline (25 mg/Kg body weight) at 8 hours prevented propranolol from inhibiting DNA synthesis. Propranolol appeared specifically to affect the cyclic AMP-dependent pre-DNA-synthetic step because it did not reduce [³H]-thymidine incorporation when injected after the second cyclic AMP surge had passed and DNA synthesis had just begun. Thus, the initial, large cyclic AMP surge following β-adrenergic stimulation may not be necessary for the initiation of prereplicative development, while the much smaller second surge may be needed for the initiation of DNA synthesis.     

The control of liver regeneration by parathyroid hormone and Calcium

Following partial hepatectomy in rats, there were two bursts of hepatocyte DNA-synthetic and mitotic activity which were produced by two subpopulations having different rates of (nearly synchronous) proliferative development. Only about 50% of the cells in both subpopulations could initiate DNA synthesis and enter mitosis when exposed to the hypocalcemic conditions in the parathyroprivic rat for 24 hours before partial hepatectomy. The proliferatively incompetent hepatocytes in these hypocalcemic rats could be induced to initiate their DNA synthetic and mitotic activity by an intraperitoneal injection of the calcium-mobilizing parathyroid hormone (50 USP units/100 g) as late as 12 hours after partial hepatectomy. Single intraperitoneal injections of calcium (0.25 mg/100 g) could also restore the proliferative competence of these hepatocytes, but only when injected at specific periods following partial hepatectomy. The injection of calcium 12 to 15 hours after partial hepatectomy induced hepatocytes in the first subpopulation to finish their development and enter mitosis, but did not affect the second, more slowly developing, subpopulation. Calcium had to be injected 25 hours after partial hepatectomy to stimulate proliferation in this second subpopulation. These data suggest that the hepatocytes which became proliferatively incompetent by prolonged exposure to a hypocalcemic environment are proliferatively activated by partial hepatectomy, but their proliferative development stops at a calcium-dependent stage near the end of the pre-replicative phase of development.     

The control of liver regeneration by parathyroid hormone and calcium.

Following partial hepatectomy in rats, there were two bursts of hepatocyte DNA-synthetic and mitotic activity which were produced by two subpopulations having different rates of (nearly synchronous) proliferative development. Only about 50% of the cells in both subpopulations could initiate DNA synthesis and enter mitosis when exposed to the hypocalcemic conditions in the parathyroprivic rat for 24 hours before partial hepatectomy. The proliferatively incompetent hepatocytes in these hypocalcemic rats could be induced to initiate their DNA synthetic and mitotic activity by an intraperitoneal injection of the calcium-mobilizing parathyroid hormone (50 USP units/100 g) as late as 12 hours after partial hepatectomy. Single intraperitoneal injections of calcium (0.25 mg/100 g) could also restore the proliferative competence of these hepatocytes, but only when injected at specific periods following partial hepatectomy. The injection of calcium 12 to 15 hours after partial hepatectomy induced hepatocytes in the first subpopulation to finish their development and enter mitosis, but did not affect the second, more slowly developing, subpopulation. Calcium had to be injected 25 hours after partial hepatectomy to stimulate proliferation in this second subpopulation. These data suggest that the hepatocytes which became proliferatively incompetent by prolonged exposure to a hypocalcemic environment are proliferatively activated by partial hepatectomy, but their proliferative development stops at a calcium-dependent stage near the end of the pre-replicative phase of development.     

Induction of DNA synthesis in adult rat hepatocytes cultured in a serum-free medium

Isolated hepatocytes from adult rats were cultured for 3 days in a serum-free synthetic medium. Supplementation with fibrinogen digests, glucagon and insulin remarkably increased DNA synthesis in hepatocytes. DNA synthesis began to increase at 35 h and reached a maximum at 41 to 54 h after plating. At this time, cells were morphologically identifiable as hepatocytes. Glucagon could be replaced by dibutyryl cyclic AMP or isobutyl-methyl-xanthine. Addition of amiloride (a Na⁺ influx inhibitor) during the initial 22 h completely inhibited DNA synthesis. These results suggest that influx of Na⁺ during early prereplicative period and increase in cellular cyclic AMP levels during late prereplicative period are necessary for the induction of DNA synthesis in hepatocytes.     

Decrease of calmodulin and actin in the plasma membrane of rat liver cells during proliferative activation

After proliferative activation of rat liver cells in vivo by a partial hepatectomy a decrease of the calmodulin content in the three plasma membrane domains (blood sinusoidal, canalicular and lateral) was observed. At 24 hours after partial hepatectomy calmodulin was found to be 3 fold lower in the sinusoidal and lateral fractions whereas a 2 fold decrease was detected in the canalicular domain. Decreases on the actin levels have been also detected at 24 hours after a partial hepatectomy. Since at this time after surgery increases on nuclear actin and calmodulin have been reported, these results suggest the possibility that the actin and calmodulin dissociated from the plasma membrane after a partial hepatectomy could subsequently be translocated into the nuclei.