Biochemical and functional responses stimulated by platelet-activating factor in murine peritoneal macrophages.

Platelet-activating factor (PAF) is a potent stimulant of leukocytes, including macrophages. To analyze the mechanisms of its effects upon macrophages, we determined whether macrophages bear specific surface receptors for PAF. By competitive radioactive binding assays, we determined two classes of specific receptors to be present on purified membranes derived from murine peritoneal macrophages (one having a Kd of approximately 1 X 10(-10) M and one a Kd of approximately 2 X 10(-9) M). When the macrophages were incubated with PAF, rapid formation of several inositol phosphates including inositol 1,4,5-trisphosphate and inositol 1,3,4,5-tetrakisphosphate were observed. PAF also elevated intracellular levels of calcium to 290 +/- 27% of basal levels which were 82.7 +/- 12 nM. Increases in calcium were observed first in submembranous areas of the macrophages. PAF also led to increases of 1,2-diacylglycerol of approximately 200 pmol/10(7) cells. A characteristic pattern of enhanced protein phosphorylation, similar to that initiated by both phorbol 12,13-myristate and lipopolysaccharide, was observed and involved enhanced phosphorylation of proteins of 28, 33, 67, and 103 kD. The half-maximal dose of PAF for initiating all the above effects was approximately 5 X 10(-9) M. PAF also initiated significant chemotaxis of the cells; the half-maximal dose for this effect was approximately 1 X 10(-11) M. Taken together, these observations suggest that murine mononuclear phagocytes bear specific membrane receptors for PAF and that addition of PAF leads to generation of break-down products of polyphosphoinositides, subsequent changes in intracellular calcium and protein phosphorylation, and chemotaxis.

The accumulation of an E2F-p130 transcriptional repressor distinguishes a G0 cell state from a G1 cell state.

Previous studies have demonstrated cell cycle-dependent specificities in the interactions of E2F proteins with Rb family members. We now show that the formation of an E2F-p130 complex is unique to cells in a quiescent, G0 state. The E2F-p130 complex does not reform when cells reenter a proliferative state and cycle through G1. The presence of an E2F-p130 complex in quiescent cells coincides with the E2F-mediated repression of transcription of the E2F1 gene, and we show that the E2F sites in the E2F1 promoter are important as cells enter quiescence but play no apparent role in cycling cells. In addition, the decay of the E2F-p130 complex as cells reenter the cell cycle requires the action of G1 cyclin-dependent kinase activity. We conclude that the accumulation of the E2F-p130 complex in quiescent cells provides a negative control of certain key target genes and defines a functional distinction between these G0 cells and cells that exist transiently in G1.

The adenovirus-inducible factor E2F stimulates transcription after specific DNA binding.

The promoter-specific factor E2F interacts with critical regulatory sequences within the adenovirus E2 promoter. In addition, the level of active factor increases markedly during a virus infection, dependent on E1A function and coincident with the trans activation of E2 transcription. We have purified the E2F factor through a combination of standard biochemical procedures and DNA affinity chromatography. The purified factor was a single polypeptide of 54,000 molecular weight, as determined by UV crosslinking and renaturation of gel-fractionated protein. Addition of affinity-purified factor to an in vitro transcription system resulted in stimulation of transcription from a promoter containing two E2F-binding sites but not promoters lacking binding sites. We thus conclude that E2F is indeed capable of stimulating transcription once it has bound to the promoter.

Identification of a novel E2F3 product suggests a mechanism for determining specificity of repression by Rb proteins.

The tumor suppressor function of Rb is intimately related to its ability to interact with E2F and repress the transcription of E2F target genes. Here we describe a novel E2F product that specifically interacts with Rb in quiescent cells. This novel E2F, which we term E2F3b, is encoded by a unique mRNA transcribed from an intronic promoter within the E2F3 locus. The E2F3b RNA differs from the previously characterized E2F3 RNA, which we now term E2F3a, by the utilization of a unique coding exon. In contrast to the E2F3a product that is tightly regulated by cell growth, the E2F3b product is expressed equivalently in quiescent and proliferating cells. But, unlike the E2F4 and E2F5 proteins, which are also expressed in quiescent cells and form complexes with the p130 protein, the E2F3b protein associates with Rb and represents the predominant E2F-Rb complex in quiescent cells. Thus, the previously described specificity of Rb function as a transcriptional repressor in quiescent cells coincides with the association of Rb with this novel E2F product.

Polymorphonuclear leukocyte function in psoriasis: chemotaxis, chemokinesis, beta-adrenergic receptors, and proteolytic enzymes of polymorphonuclear leukocytes in the peripheral blood from psoriatic patients.

Psoriatic patients, particularly those with psoriatic arthritis, have neutrophilic and eosinophilic leukocytosis. Isolated polymorphonuclear leukocytes (PMNLs) from psoriatic patients have normal concentrations of proteolytic enzymes and they have beta-adrenergic receptors of normal density and affinity. PMNLs from psoriatic patients responded normally to the synthetic chemotactic peptide, f-Met-Leu-Phe (formyl-methionine-leucine-phenylalanine). The chemotactic activities of sera from psoriatic patients were similar to those of normal sera. Sera from psoriatic patients enhanced chemokinesis of PMNLs more than normal control sera at a final concentration of 1%; no difference in chemokinetic response between psoriatic and normal sera was found at serum concentrations greater than 2.5%. This study suggests that the peripheral PMNLs from psoriatic patients are normal, but the sera of psoriatic patients has more chemokinetic activity for PMNLs than does normal serum.

Selective biliary secretion of basal and glucagon-inhibited neutral sterol after triparanol administration.

Biliary cholesterol secretion was studied in dogs with chronic bile fistulas, using glucagon, an inhibitor of biliary cholesterol secretion, and triparanol, an inhibitor of cholesterol synthesis. Glucagon inhibited neutral sterol secretion before and after triparanol administration. Triparanol caused a significant accumulation in bile of the cholesterol precursor desmosterol which comprised a significant portion of the neutral sterol in bile but not in blood. Glucagon inhibited both biliary desmosterol and cholesterol secretions to a similar degree. These findings suggest that biliary cholesterol is derived from newly synthesized hepatic sterol as well as from equilibrated sources. Furthermore, glucagon suppressed biliary secretion of both equilibrated as well as newly synthesized neutral sterol, suggesting that glucagon inhibits the movement of neutral sterol to or through the canalicular membrane.

A combinatorial mechanism for determining the specificity of E2F activation and repression.

Various studies have detailed the role of E2F proteins in both transcription activation and repression. Further study has shown that distinct promoter elements, but comprising the same E2F-recognition motif, confer positive or negative E2F control and that this reflects binding of either activator or repressor E2F proteins, respectively. We now show that the specificity of binding of an activator or repressor E2F protein is determined by adjacent sequences that bind a cooperating transcription factor. We propose that the functional E2F element is a module comprising not only the E2F-binding site but also the adjacent site for the cooperating transcription factor.

Alterations of rat hepatic cholesterogenesis by heterologous lipoproteins.

Heterologous human lipoproteins were infused into rats in order to change acutely the lipoprotein pattern to a predominant kind and the effect on hepatic cholesterogenesis was subsequently observed. A 4-h intravenous infusion of human low density and very low density lipoproteins into rats produced a significant decrease in the incorporation of acetate into cholesterol in both liver slices and homogenates. An infusion of similar concentrations of human high density lipoprotein produced a significant increase in hepatic cholesterol synthesis. These infusions did not change mevalonate conversion to cholesterol in either the homogenates or slices. Concomitant with the changes in hepatic cholesterol synthesis were changes of similar magnitudes in the activity of the enzyme 3-hydroxy-3-methylglutaryl coenzyme A reductase. These alterations in hepatic cholesterol synthesis were associated with significant changes in microsomal cholesterol content. There was a significant increase in hepatic cholesterol synthesis with the infusion of apoproteins of high density lipoprotein. The apoproteins of very low density lipoprotein had no effect on hepatic cholesterogenesis. These studies indicate that circulating lipoproteins modify hepatic cholesterol synthesis and that the apoproteins of these lipoproteins may themselves be important for this action.

The sources of rat biliary cholesterol and bile acid.

The precursor sources of bile acid and bile neutral sterol were evaluated in the rat using Triparanol to inhibit the terminal reduction in the synthesis of cholesterol. During the initial period of Triparanol administration, the accumulation of hepatic desmosterol acts to segregate relatively newly synthetic hepatic sterol from the bulk of the equilibrated sterol mass. Biliary excretion of newly synthetic sterol can then be determined in acute studies, assuming no great differences between desmosterol and cholesterol as precursors of biliary neutral sterol or bile acid. It has been determined in this model that newly synthetic sterol comprises a mean of about 28% of the total biliary neutral sterol output. This fraction fell when hepatic cholesterogenesis was suppressed by prior cholesterol feeding. By using this approach in conjunction with the administration of labeled mevalonate to a renal pedicle-ligated rat, it was possible to calculate the amount of bile acid produced from either newly synthesized sterol or the equilibrated sterol pool. It has been estimated that the bulk of bile acid synthesis arises from this equilibrated source when these determinations were made within two hours of creating the fistula. With more prolonged fistula times, more of the bile acid originated from the newly synthesized sterol.

A unique role for the Rb protein in controlling E2F accumulation during cell growth and differentiation.

Examination of the interactions involving transcription factor E2F activity during cell growth and terminal differentiation suggests distinct roles for Rb family members in the regulation of E2F accumulation. The major species of E2F in quiescent cells is a complex containing the E2F4 product in association with the Rb-related p130 protein. As cells enter the cell cycle, this complex disappears, and there is a concomitant accumulation of free E2F activity of which E2F4 is a major component. E2F4 then associates with the Rb-related p107 protein as cells enter S phase. Rb can be found in interactions with each E2F species, including E2F4, during G1, but there appears to be a limited amount of Rb with respect to E2F, likely due to the maintenance of most Rb protein in an inactive state by phosphorylation. A contrasting circumstance can be found during the induction of HL60 cell differentiation. As these cells exit the cell cycle, active Rb protein appears to exceed E2F, as there is a marked accumulation of E2F-Rb interactions, involving all E2F species, including E2F4, which is paralleled by the conversion of Rb from a hyperphosphorylated state to a hypophosphorylated state. These results suggest that the specific ability of Rb protein to interact with each E2F species, dependent on concentration of active Rb relative to accumulation of E2F, may be critical in cell-growth decisions.

Oncogenic capacity of the E2F1 gene.

Previous experiments have identified the E2F transcription factor as a potential downstream target for the action of cellular regulatory activities, such as the Rb tumor suppressor protein, that control cell growth and that, when altered, contribute to the development of human tumors. In light of these findings, we have assayed the ability of the E2F1 and DP1 genes, which encode heterodimeric partners that together create E2F activity, to act in an oncogenic fashion. We find that E2F1, particularly in combination with the DP1 product, cooperates with an activated ras oncogene to induce the formation of morphologically transformed foci in primary rat embryo fibroblast cultures. In addition, an E2F1 chimeric protein, in which sequences involved in Rb binding have been replaced with the herpesvirus VP16 activation domain, exhibits increased transformation activity. Cells transfected with E2F1 and DP1 or the E2F1-VP16 chimera form colonies in soft agar and induce tumor formation in nude mice. We conclude that deregulated E2F1 expression and function can have oncogenic consequences.

Distinct roles for E2F proteins in cell growth control and apoptosis.

E2F transcription activity is composed of a family of heterodimers encoded by distinct genes. Through the overproduction of each of the five known E2F proteins in mammalian cells, we demonstrate that a large number of genes encoding proteins important for cell cycle regulation and DNA replication can be activated by the E2F proteins and that there are distinct specificities in the activation of these genes by individual E2F family members. Coexpression of each E2F protein with the DP1 heterodimeric partner does not significantly alter this specificity. We also find that only E2F1 overexpression induces cells to undergo apoptosis, despite the fact that at least two other E2F family members, E2F2 and E2F3, are equally capable of inducing S phase. The ability of E2F1 to induce apoptosis appears to result from the specific induction of an apoptosis-promoting activity rather than the lack of induction of a survival activity, because co-expression of E2F2 and E2F3 does not rescue cells from E2F1-mediated apoptosis. We conclude that E2F family members play distinct roles in cell cycle control and that E2F1 may function as a specific signal for the initiation of an apoptosis pathway that must normally be blocked for a productive proliferation event.

Myc and Ras collaborate in inducing accumulation of active cyclin E/Cdk2 and E2F.

Considerable evidence points to a role for G1 cyclin-dependent kinase (CDK) in allowing the accumulation of E2F transcription factor activity and induction of the S phase of the cell cycle. Numerous experiments have also demonstrated a critical role for both Myc and Ras activities in allowing cell-cycle progression. Here we show that inhibition of Ras activity blocks the normal growth-dependent activation of G1 CDK, prevents activation of the target genes of E2F, and results in cell-cycle arrest in G1. We also show that Ras is essential for entry into the S phase in Rb+/+ fibroblasts but not in Rb-/- fibroblasts, establishing a link between Ras and the G1 CDK/Rb/E2F pathway. However, although expression of Ras alone will not induce G1 CDK activity or S phase, coexpression of Ras with Myc allows the generation of cyclin E-dependent kinase activity and the induction of S phase, coincident with the loss of the p27 cyclin-dependent kinase inhibitor (CKI). These results suggest that Ras, along with the activation of additional pathways, is required for the generation of G1 CDK activity, and that activation of cyclin E-dependent kinase in particular depends on the cooperative action of Ras and Myc.

Chemoattractant-mediated stimulation of the respiratory burst in human polymorphonuclear leukocytes may require appearance of protein kinase activity in the cells' particulate fraction.

Low doses of aliphatic alcohols produce divergent effects on the function of chemoattractant receptors on human polymorphonuclear leukocytes (PMNs) since they enhance chemotaxis but inhibit stimulation of superoxide production by chemoattractants. As such, alcohols can provide useful pharmacologic tools to probe the mechanisms of stimulus-response coupling in leukocytes. A role for protein kinase C has been implicated in the activation of the respiratory burst in PMNs. Although the vast majority of this enzyme activity is located in the cytosolic fraction of unactivated PMNs, protein kinase C activity appears in the particulate fraction of the cells when they are stimulated to produce superoxide by either chemoattractants or by phorbol myristate acetate (PMA). Doses of the alcohols that selectively inhibited stimulation of superoxide production by chemoattractants also inhibited the appearance of protein kinase C activity as well as an undefined protein kinase activity in the particulate fraction of the cells. In contrast, the alcohols did not affect either the ability of PMA to stimulate the production of superoxide in PMNs nor the appearance of protein kinase activity in the cells' particulate fraction. PMA is known to bind and activate protein kinase C directly, thus bypassing receptor-mediated events. These data suggest that alcohols inhibit the stimulation of the respiratory burst by chemoattractants in PMNs by blocking the ability of receptor occupancy to induce the appearance of protein kinase activity in particulate fractions. These results moreover suggest that the appearance of protein kinase activity in the particulate fraction may be required for activation of the respiratory burst in PMNs.

A guanine nucleotide regulatory protein controls polyphosphoinositide metabolism, Ca2+ mobilization, and cellular responses to chemoattractants in human monocytes.

Previous studies demonstrated that oligopeptide chemoattractant receptors on PMN and macrophages exist in high and low affinity states which are interconvertible by guanosine di- and triphosphates. These observations suggest that guanine nucleotide regulatory (N) proteins play a role in phagocyte activation by chemotactic factors. The data presented here indicate that chemotactic factor receptors on monocytes utilize an N protein to activate phospholipase C and subsequent biologic responses by the cells. This conclusion is based on the findings that inactivation of an N protein of 41,000 m.w. by Bordetella pertussis toxin (PT) treatment abolishes monocyte responsiveness to chemoattractants but not to lectins, PMA, or the Ca2+ ionophore A23187. Treatment with PT inhibited IP3 production, Ca2+ mobilization, and cellular activation as assessed by chemotaxis and changes in forward light scattering in response to the chemoattractants by at least 80%. Therefore, a PT-sensitive N protein plays an important role in the activation of monocytes by chemoattractants.

E2F1-specific induction of apoptosis and p53 accumulation, which is blocked by Mdm2.

Previous work has demonstrated a role for E2F transcription factor activity in the regulation of cell growth during the G0/G1-S phase transition. Indeed, overexpression of E2F proteins, including the E2F1 and E2F2 products, induces DNA synthesis in quiescent fibroblasts. Other experiments have shown that E2F1 expression also induces apoptosis, dependent on p53. Although this could represent a response to aberrant cell cycle progression, we show that only E2F1 induces apoptosis and that this coincides with an ability of E2F1 to induce accumulation of p53 protein. We also find that coexpression of Mdm2, which is known to regulate p53 activity, blocks the E2F1-mediated induction of apoptosis and also blocks the E2F1-mediated accumulation of p53. We propose that E2F1 acts as a specific signal for the induction of apoptosis by affecting the accumulation of p53, which under normal proliferative conditions may be controlled by Mdm2.

Collaborative role of E2F transcriptional activity and G1 cyclindependent kinase activity in the induction of S phase.

A considerable body of evidence points to a role for both cyclin E/cyclin-dependent kinase (cdk)2 activity and E2F transcription activity in the induction of S phase. We show that overexpression of cyclin E/cdk2 in quiescent cells induces S phase, that this coincides with an induction of E2F activity, and that coexpression of E2F enhances the cyclin E/cdk2-mediated induction of S phase. Likewise, E2F overexpression can induce S phase and does so in the apparent absence of cyclin E/cdk2 activity. In addition, although the inhibition of cyclin E/cdk2 activity blocks the induction of S phase after growth stimulation of normal mouse embryo fibroblasts, inhibition of cyclin E/cdk2 does not block S phase induction in Rb-/- cells where E2F activity is deregulated. These results point to the important roles for E2F and cyclin E/cdk2 in the induction of S phase. Moreover, the nature of the E2F targets and the suspected targets for cyclin E/cdk2 suggests a potential molecular mechanism for the collaborative action of cyclin E/cdk2 and E2F in the induction of S phase.

Effect of apolipoproteins on the induction of hepatic steatosis in rats.

The incorporation of apolipoprotein E isolated from human very low density lipoproteins on a triglyceride emulsion produced a substantial increment in hepatic triglyceride after 1 h of in vitro perfusion through the isolated liver of a fasted rat. Both gross and microscopic morphology confirmed a substantial steatosis. Perfusions with triglyceride emulsions which contained no apoipoproteins resulted in a modest increment in hepatic triglyceride although considerably less than emulsions with the E protein, and no morphologic features of steatosis. The steatosis induced in the in vitro perfused fasted livers by the emulsions with E protein could be prevented when CIII-1 apoprotein was also incorporated on the emulsion. A fed rat liver perfused with the E-enriched emulsion accumulated significantly less triglyceride than the fasted preparation. These data suggest that the apoprotein patterns of the plasma triglyceride-rich lipoproteins are of considerable importance for the partition of triglyceride between liver and plasma.