Nuclear location of ribonuclease H and increased level of magnesium-dependent ribonuclease H in rat liver on thioacetamide treatment

Rat liver nuclei were isolated in aqueous solutions of low ionic strength or anhydrous glycerol. The presence of ribonuclease H (RNase H) [EC 3.1.4.34] activity in the cytoplasm is due to extraction of the nuclear enzyme by buffer and inorganic salts. Two forms of RNase H were separated from rat liver nuclei by affinity chromatography using a DNA-cellulose column. When the RNase H in the wash solution of nuclei with 0.3 M sucrose and in nuclear solution extracted with 0.15 M NaCl were fractionated on a single-stranded DNA-cellulose column, two peaks corresponding to Mn2+- and Mg2+-dependent RNases H were eluted at 0.1 M and 0.2 M NaCl, respectively, and a peak having both RNase H activities was recovered in the wash-through fraction from the column. Among the enzymes from these two fractions in the nuclei, the activity of the Mg2+-dependent RNase H which binds to DNA-cellulose increased several-fold within 24 h of a single injection of thioacetamide. The activities of Mg2+-dependent RNase H extracted with higher-salt solution from the nuclei and recovered in the flow-through fraction from the DNA-cellulose column and the Mn2+-dependent RNase H activities were relatively unaffected by an injection of thioacetamide.     

Fractionation of rat ventricular nuclei.

Myocardial cells were isolated after treatment with collagenase (0.05%) and hyaluronidase (0.1%) by discontinuous-gradient centrifugation on 3% Ficoll. Nuclei derived from these myocardial cells were then fractionated on a discontinuous sucrose density gradient with the following steps: (I) 2.0M/2.3M, (II) 2.3M/2.4M, (III) 2.4M/2.5M, (IV) 2.5M/2.6M, and (V) 2.6M/2.85M. The myocardial nuclei were sedimented in the interfaces of gradient fractions (II) and (III). Nuclei from whole ventricles that had been treated with the enzymes before isolation sedimented into five major subsets of nuclei. These findings suggest that nuclei sedimented in the isopycnic gradient at fractions (II) and (III) are most probably derived from myocardial cells. However, this procedure is laborious and lengthy, and the recovery of myocardial-cell nuclei is low. An alternative method was developed to isolate an enriched fraction of myocardial-cell nuclei from whole ventricular tissue without exposing the tissues to enzyme digestion. These ventricular nuclei could be fractionated into five nuclear subsets by using the same discontinuous sucrose density gradient as that described above. The content of DNA, RNA and protein per nucleus for each band was determined. Although the DNA content per nucleus was constant (10pg), that of RNA varied from 1.5 to 4.5pg and that of protein from 16 to 24pg. Nuclei from each band were examined by light-microscopy: large nuclei occurred in the ligher regions whereas smaller nuclei were found in the denser regions of the gradient. From the size distribution pattern of myocardial-cell nuclei compared with that of total ventricular nuclei, it was found that nuclear subsets (II), (III), and (IV) were similar to myocardial nuclei. Electrophoretic analyses of the proteins solubilized in sodium dodecyl sulphate/phenol or Tris/EDTA/2-mercaptoethanol/phenol obtained from each nuclear subset indicate that these fractions are similar, with limited qualitative differences. These findings indicate that isolation of an enriched fraction of myocardial-cell nuclei could be achieved by discontinuous-sucrose-density-gradient centrifugation.     

The presence of glycosyltransferases on chromatin acceptors in monkey liver nuclear membranes (author's transl)

Nuclei were prepared from monkey hepatocytes by centrifugation of the homogenate on a cushion of 2.3 M sucrose, during 45 min at 100000 X g. The yield was 2.2 x 10(7) nuclei per g of liver, and 70% of te homogenate DNA was recovered in these nuclei. An electron microscopic study as well as a biochemical analysis of marker enzymes showed that the nuclei are not contaminated by other subcellular fractions, especially endoplasmic reticulum. A mannosyltransferase and an N-acetylglucosaminyltransferase, working on endogenous glycoproteic acceptors, are present in the nuclei for 1.4 and 6.5% of the homogenate activities, respectively. The nuclei are hydrolysed by DNAse I. The suspension, adjusted in 1.9 M sucrose, was centrifuged for 2 h at 100000 X g, under buffer layer. Purified nuclear membranes were collected at the interface. These membranes did not contain any more endoplasmic reticulum enzyme activities, but the mannosyl and N-acetylglucosaminyltransferase activities were still present. They essentially work on an exogenous chromatin acceptor, prepared by lysis of the nuclei. The eventual role of these glycosyltransferases in the glycosylation of non-histone proteins is discussed.     

Studies on the nuclear binding of steroid hormone-receptor complex; characteristics of binding of nuclei from fetal rat liver to 3H-dexamethasone-liver cytoplasmic receptor complex

Binding of 3H-dexamethasone (Dex)-rat liver cytoplasmic receptor complex to nuclei from fetal rat livers in vitro exhibited a high-affinity and saturable nature (Kd=1.5 X 10- M, maximal binding sites=470 fmole/mg DNA), and the binding was inhibited competitively by prior injection of Dex in vivo. While binding of 3H-Dex-receptor complex to nuclei from adult rat liver was in low affinity and unsaturable, and injection of Dex prior to the sacrifice of animals did not influence the nuclear binding to 3H-Dex-receptor complex in vitro. Differential salt-extraction with KCl solution of the nuclear bound 3H-Dex receptor complex revealed the presence of salt-extractable and residual forms of bound receptors. The amount of the fraction extracted with 0.3 M KCl reached its maximum at 10 min after the start of incubation, while the 1.0 M KCl-extractable and residual fractions reached their maximum plateaus after 30 min of the incubation. Scatchard analysis revealed that the binding of the receptor complex to the 0.3M and 1.0M KCl fractions was saturable, while the residual fraction did not show any tendency of saturation under the experimental conditions employed in the present study. The results obtained in this work were compared to those which have been reported by other investigators.     

Fractionation of nucleosomes by salt elution from micrococcal nuclease- digested nuclei

The solubilization of nucleosomes and histone H1 with increasing concentrations of NaCl has been investigated in rat liver nuclei that had been digested with micrococcal nuclease under conditions that did not substantially alter morphological properties with respect to differences in the extent of chromatin condensation. The pattern of nucleosome and H1 solubilization was gradual and noncoordinate and at least three different types of nucleosome packing interactions could be distinguished from the pattern. A class of nucleosomes containing 13-- 17% of the DNA and comprising the chromatin structures most available for micrococcal nuclease attack was eluted by 0.2 M NaCl. This fraction was solubilized with an acid-soluble protein of apparent molecular weight of 20,000 daltons and no histone H1. It differed from the nucleosomes released at higher NaCl concentrations in content of nonhistone chromosomal proteins. 40--60% of the nucleosomes were released by 0.3 M NaCl with 30% of the total nuclear histone H1 bound. The remaining nucleosomes and H1 were solublized by 0.4 M or 0.6 M NaCl. H1 was not nucleosome bound at these ionic strengths, and these fractions contained, respectively, 1.5 and 1.8 times more H1 per nucleosome than the population released by 0.3 M NaCl. These fractions contained the DNA least available for micrococcal nuclease attach. The strikingly different macromolecular composition, availability for nuclease digestion, and strength of the packing interactions of the nucleosomes released by 0.2 M NaCl suggest that this population is involved in a special function.     

Analog modeling of glucagon-induced autophagy in rat liver. II. Evaluation of iron labeling as a means for identifying telolysosome, autophagosome and autolysosome populations.

To evaluate the potential usefulness of iron labeling as a means for identifying the telolysome, autophagosome and autolysosome populations of rat liver, animals treated with Jectofer (iron-citric acid-sorbitol complex), or with Jectofer followed by glucagon, have been studied with a variety of biochemical and morphological methods. Differential centrifugation studies of liver homogenates revealed that the sedimentation velocity and mechanical fragility of acid phosphatase bearing particles increase with the duration of Jectofer treatment and that iron accumulates in the mitochondrial and nuclear fractions. Rate sedimentation studies confirmed the change in sedimentation velocity, which was shown to be due in part to a marked increase in particle density. Quantitative morphological analysis of liver M + L and N + M + L fractions revealed a nearly complete absence of pericanalicular dense bodies after 6–7 days of Jectofer treatment. In these fractions a new type of particle containing fine electron dense granules was seen. The mean volume of these particles was decreased and their number increased when compared to dense bodies but the general morphology and overall size distribution of the two particle classes were similar. In animals given both Jectofer and glucagon, autophagic vacuole formation was similar to that found in animals receiving only glucagon. However, the increase in osmotic fragility of acid phosphatase bearing particles usually seen after glucagon administration occurred at a significantly slower rate. Examination of paniculate fractions revealed the presence of autophagic vacuoles with (autolysosomes) and without (autophagosomes) fine dense granules. The number of autolysosomes and their relative proportion in the autophagic vacuole population were correlated with an increase in the osmotic fragility of the acid phosphatase bearing particles in the same fraction. Organelle degeneration was observed more frequently in autolysosome profiles. These results support the contention that iron labeling can be used to separate the principal particle populations participating in the autophagic response induced by glucagon.     

Incorporation of 1-(14)C linoleic acid in rat liver nuclei and chromatin fractions

The incorporation of 1-(14)C linoleic acid in several chromatin fractions of rat liver nuclei was investigated using two different procedures: (1) rat liver nuclei were incubated with ATP, CoASH, Mg(++) and 1-(14)C linoleic acid. After 40 min at 37 degrees C the chromatin obtained by sonication of nuclei suspended in 0.25 M sucrose was fractionated by differential sedimentation; (2) chromatin fractions obtained by differential sedimentation were incubated separately with ATP, CoASH, Mg(++) and 1-(14)C linoleic acid 40 min at 37 degrees C in order to characterize the fatty acid incorporation in isolated chromatin. A comparative study of the incorporation of 1-(14)C linoleic acid in microsomes and nuclei isolated from rat liver is also presented for the purpose of comparison. Linoleic acid was incorporated into nuclear lipids as well as in chromatin fractions. The fatty acid incorporation was stimulated considerably in the acylation system when compared to control, it appears to be highly dependent on the state of condensation of chromatin, being barely detectable in the lowest density fraction. The major proportion of 1-(14)C linoleic acid was found in phospholipids and in a lesser proportion it remained esterified to triglycerides and cholesteryl esters. The distribution of radioactivity in different classes of phospholipids present in microsomes and nuclei isolated from rat liver, showed a similar profile of distribution. The major proportion of radioactivity, approximately 50% was found in phosphatidylcholine and in a lesser proportion in sphingomyelin, phosphatidylserine and phosphatidylethanolamine. When chromatin fractions were incubated separately, it was observed that the major proportion of 1-(14)C linoleic acid in phospholipids was found in heavy chromatin fractions whereas low density chromatin fraction only incorporated in a lesser proportion.     

Presence de glycosyltransferases a accepteurs chromatiniens dans les membranes nucleaires d'hepatocytes de singeThe presence of glycosyltransferases on chromatin acceptors in monkey liver nuclear membranes

Nuclei were prepared from monkey hepatocytes by centrifugation of the homogenate on a cushion of 2.3 M sucrose, during 45 min at 100 000 × g. The yield was 2.2 · 10⁷ nuclei per g of liver, and 70% of the homogenate DNA was recovered in these nuclei. An electron microscopic study as well as a biochemical analysis of marker enzymes showed that the nuclei are not contaminated by other subcellular fractions, especially endoplasmic reticulum. A mannosyltransferase and an N-acetylglucosaminyltransferase, working on endogenous glycoproteic acceptors, are present in the nuclei for 1.4 and 6.5% of the homogenate activities, respectively.The nuclei are hydrolysed by DNAase I. The suspension, adjusted in 1.9 M sucrose, was centrifuged for 2 h at 100 000 × g, under a buffer layer. Purified nuclear membranes were collected at the interface. These membranes did not contain any more endoplasmic reticulum enzyme activities, but the mannosyl and N-acetylglucosaminyltransferase activities were still present. They essentially work on an exogenous chromatin acceptor, prepared by lysis of the nuclei. The eventual role of these glycosyltransferases in the glycosylation of non-histone proteins is discussed.     

Binding of dexamethasone to rat liver nuclei in vivo and in vitro: evidence for two distinct binding sites

The binding of [3H]dexamethasone (DEX) to rat liver nuclei in vitro and in vivo have been compared. In vitro, purified nuclei displayed a single class of specific glucocorticoid binding sites with a dissociation constant (Kd) of approximately 10(-7) M for [3H]DEX at 4 degrees C. The glucocorticoid agonists prednisolone, cortisol, and corticosterone and the antagonists progesterone and cortexolone competed avidly for this site, but the potent glucocorticoid triamcinolone acetonide (TA) competed poorly in vitro. Nuclei isolated from the livers of intact rats contained 1-2 X 10(4) [3H]DEX binding sites/nucleus. Up to 85% of the binding sites were recovered in the nuclear envelope (NE) fraction when NE were prepared either before or after labeling with [3H]DEX in vitro. After adrenalectomy, the specific [3H]DEX binding capacity of both nuclei and NE decreased to 15-20% of control values, indicating sensitivity of the binding sites to hormonal status of the animals. Efforts to restore the binding capacity by administration of exogenous glucocorticoids, however, were unsuccessful. After labeling of rat liver nuclei in vivo by intraperitoneal injection of [3H]DEX or [3H]TA into living animals, the steroid specificity and subnuclear localization of radiolabel were different. Both [3H]TA (which did not bind in vitro) and [3H]DEX became localized to nuclei in a saturable fashion in vivo. With either of these ligands, approximately 20% of the total nuclear radiolabel was recovered in the NE fraction. These results suggest the presence of two separate and distinct binding sites in rat liver nuclei, one which is localized to the NE and binds [3H]DEX (but not [3H]TA) in vitro, and another which is not localized to the NE but binds [3H]DEX and [3H]TA in vivo.     

Separation and characterization of receptor-translocation inhibitors from AH 130 tumor cells

The objective of this investigation was to study the relationship between glucocorticoid resistance and macromolecular receptor-translocation inhibitors ( MTIs ). MTIs in various cytoplasmic preparations are known to inhibit the "activated" receptor-steroid complex association with isolated nuclei, chromatin, or DNA. It was found that the MTI in the cytosol of AH 130 tumor cells (glucocorticoid resistant cells) appeared to be about 5 times more inhibitory than crude MTI from rat liver. Another difference between these MTI preparations was that ATP decreased the inhibition by crude MTI from rat liver, but had little effect on that of MTI from the tumor cells. Both preparations gave three fractions of material with inhibitory activity on DEAE-cellulose chromatography. The first fraction (Peak I), eluted with about 0.1 M NaCl, was the largest fraction separated from the tumor cytosol, but a minor fraction of that from liver. In the presence of 5 mM ATP, Peak I from rat liver enhanced nuclear binding, but that from the tumor did not, suggesting that these fractions were qualitatively different. The other two fractions (Peak II and Peak III), eluted with about 0.2 M and 0.3 M NaCl, respectively, were comparable in the two preparations.     

Hybridizable ribonucleic acid of rat brain

1. Cerebral RNA of adult and newborn rats was labelled in vivo by intracervical injection of [5-³H]uridine or [³²P]phosphate. Hepatic RNA of similar animals was labelled by intraperitoneal administration of [6-¹⁴C]orotic acid. Nuclear and cytoplasmic fractions were isolated and purified by procedures involving extraction with phenol and repeated precipitation with ethanol. 2. The fraction of pulse-labelled RNA from cerebral nuclei that hybridized to homologous DNA exhibited a wide range of turnover values and was heterogeneous in sucrose density gradients. 3. Base composition of the hybridizable RNA was similar to that of the total pulse-labelled material; both were DNA-like. 4. Pulse-labelled cerebral nuclear RNA hybridized to a greater extent than cytoplasmic RNA for at least a week after administration of labelled precursor. This finding suggested that cerebral nuclei contained a hybridizable component that was not transferred to cytoplasm. 5. The rates of decay of the hybridizable fractions of cerebral nuclei and cytoplasm were faster in the newborn animal than in the adult. Presumably a larger proportion of labile messenger RNA molecules was present in the immature brain. 6. Cerebral nuclear and cytoplasmic RNA fractions from newborn or adult rats, labelled either in vivo for periods varying from 4min. to 7 days or in vitro by exposure to [³H]-dimethyl sulphate, uniformly hybridized more effectively than the corresponding hepatic preparation. These data suggested that a larger proportion of RNA synthesis was oriented towards messenger RNA formation in brain than in liver.     

INCORPORATION IN VIVO OF RADIOACTIVE LEUCINE INTO NEURONAL AND GOAL NUCLEAR PROTEINS OF RAT BRAIN

Purified neuronal and glial nuclei were separated from rat brain cells. The fraction rich in neuronal nuclei contained 68 ± 9 per cent neuronal nuclei and the fraction rich in glial nuclei contained 89 ± 6 per cent glial nuclei. The fraction rich in neuronal nuclei isolated from cells of adult rat brain incorporated l -[4,5-³H]leucine into TCA-insoluble material at a rate comparable to those of the microsomal and the soluble fractions of the brain, and at a much higher rate than the fraction rich in glial nuclei. The proteins soluble in buffered-saline, the acid-soluble deoxyribonucleoproteins, and the residual proteins of the neuronal nuclei are apparently the proteins which account for the higher specific activity of neuronal proteins compared with glial nuclear proteins. In liver and kidney, the incorporation of [³H]leucine into nuclear proteins was lower than into other subcellular fractions from the same organs.     

Binding of the glucocorticoid receptor to the rat liver nuclear matrix. The role of disulfide bond formation

The nuclear matrix is a putative skeletal structure which has been implicated in many nuclear functions. To assess a possible role of the nuclear matrix in glucocorticoid action, purified rat liver nuclei containing glucocorticoid-receptor complexes were treated with DNase I +/- RNase A followed by 1.6 M NaCl, thus yielding salt-extractable and salt-resistant (nuclear matrix) fractions. The subnuclear distribution of hormone-receptor complexes was determined by following the fate of unmetabolized radiolabel after injection of labeled triamcinolone acetonide into adrenalectomized animals and subjecting various subfractions to immunoblotting using a monoclonal antibody which recognizes the glucocorticoid receptor. Both techniques indicated that 50-70% of the total nuclear hormone-receptor complexes were recovered in the nuclear matrix fraction. Previous results (Kaufmann, S. H., and Shaper, J. H. (1984) Exp. Cell Res. 155, 477-495) suggest that a variety of nuclear polypeptides become nuclease- and salt-resistant as a result of the formation of intermolecular disulfide bonds. The following evidence suggests that disulfide bonds mediate the association between the glucocorticoid receptor and the nuclear matrix. When nuclei were isolated in the absence of sulfhydryl-blocking and -cross-linking reagents, sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions revealed that the receptor was present as a high molecular weight disulfide-cross-linked complex. When nuclei were isolated in the presence of the irreversible sulfhydryl-blocking reagent iodoacetamide, the disulfide bonds which cross-linked the receptor into high molecular weight complexes were absent; and 85-100% of the hormone-receptor complexes were salt-extractable. When nuclei (isolated in the absence of iodoacetamide) were treated with the sulfhydryl-cross-linking reagent sodium tetrathionate, greater than 95% of the nuclear hormone-receptor complexes became resistant to extraction with nucleases and 1.6 M NaCl. The implications of these results for other matrix-associated nuclear functions are discussed.     

Yeast nuclear envelope proteins cross react with an antibody against mammalian pore complex proteins

We have used a monoclonal antibody raised against rat liver nuclear proteins to study two cross-reactive proteins in the yeast nucleus. In rat liver, this monoclonal antibody, mAb 414, binds to nuclear pore complex proteins, including one of molecular weight 62,000 (Davis, L. I., and G. Blobel. 1987. Proc. Natl. Acad. Sci. USA. 84:7552-7556). In yeast, mAb 414 cross reacts by immunoblotting with two proteins that have apparent molecular weights of 110,000 and 95,000, and are termed p110 and p95, respectively. Examination of subcellular fractions by immunoblotting shows that both p110 and p95 are located exclusively in the nuclear fraction. The mAb 414 immunoprecipitates several proteins from a crude yeast cell extract, including p110, p95, and a approximately 55-kD protein. Immunoprecipitation from subcellular fractions yields only p110 and p95 from purified nuclei, whereas the approximately 55-kD protein is immunoprecipitated from the soluble fraction. Digestion of purified nuclei with DNase to produce nuclear envelopes releases some of p110, but the majority of p110 is solubilized only after treatment of envelopes with 1 M NaCl. Immunofluorescence localization using yeast cells and isolated nuclei shows a punctate and patchy staining pattern of the nucleus. Confocal laser scanning immunofluorescence microscopy resolves the punctate and patchy staining pattern better and shows regions of fluorescence at the nuclear envelope. Postembedding immunogold electron microscopy using purified nuclei and mAb 414 shows colloidal gold decoration of the yeast nuclear envelope, but resolves pore complexes too poorly to achieve further ultrastructural localization. Immunogold labeling of nuclei followed by embedding suggests decoration of pore complexes. Thus, p110 and/or p95 are localized to the nuclear envelope in yeast, and may be components of the nuclear pore complex.     

Properties of isolated frog liver and kidney nuclei

In order for a nuclear preparation to be used for analytical purposes, the method of isolation and composition of the suspension medium must be carefully examined. Accordingly, satisfactory techniques for the isolation of frog liver and kidney nuclei were developed. The medium for frog liver nuclei consisted of: 55% glycerol, 0.001 M magnesium chloride, 0.033 M sodium β-glycerophosphate and/or 0.002 M KH₂PO₄, K₂HPO₄ (pH 6.8), however, the addition of 0.15 M sucrose was essential for satisfactory isolation of kidney nuclei. Inclusion of sucrose (0.15 M ) in the isolation medium promoted nucleolar swelling and a decrease in nuclear volume in liver cell nuclei. Nucleolar migration and extrusion were noted in solutions with high cationic content. The morphological appearance of isolated nuclei was found to be extremely sensitive to the ionic strength of the isolation medium, as was the isolation procedure in toto. Effects were considered to be the result of precipitation and swelling of nucleoprotein. Dissociation of nucleoprotein was considered to be associated with temperature change. The uptake of supra-vital dyes aided in recognition of the morphological alterations and was also an indicator of nuclear viability. Trypsin readily altered the nuclear membrane and a rapid decrease in nuclear density occurred, but the nucleolus remained intact. The diverse response of liver and kidney nuclei as compared with the nucleated red blood cells (a contaminant) to treatment with trypsin was noted and its implications discussed.     

A cyto-chemical study on the pancreas of the guinea pig. III. In vivo incorporation of leucine-1-C14 into the proteins of cell fractions

DL-leucine-1-C(14) was administered by intracardiac injection to guinea pigs and its in vivo incorporation into the proteins of various pancreatic cell fractions followed over a period of 2 hours. The pancreas was homogenized in 0.88 M sucrose and fractionated by differential centrifugation to give nuclear, zymogen, mitochondrial, microsomal, postmicrosomal, and final supernatant fractions. The proteins of these fractions, obtained by precipitation with trichloroacetic acid followed by washing, were counted. The proteins of the microsomal fraction showed the highest early specific activity and were followed by those of the zymogen and mitochondrial fractions. The microsomal fraction was broken up into two subfractions: one consisting of detached RNP particles, the other representing mainly the microsomal content and membranes. The incorporation of labelled leucine into the proteins of microsomal subtractions and in those of postmicrosomal fractions was studied comparatively in the pancreas of fasted and fed guinea pigs as well as in the liver and pancreas of fasted animals. A tentative cytological picture of protein synthesis and transport based on these findings is presented.     

Activity and subcellular distribution of protein kinase dependent on adenosine 3':5'-monophosphate in liver from normal and adrenalectomized rats.

We have examined whether glucocorticoids control the activity and (or) the subcellular distribution of protein kinase dependent on cyclic AMP (adenosine 3':5'-monophosphate), since they influence cyclic-AMP-dependent responses to other hormones. Protein kinase activity was determined in rat liver homogenates and subcellular fractions, nuclear, large granular, microsomal and supernatant obtained by differential sedimentation in 0.25 M sucrose. 63% of the tissue protein kinase activity detected in absence of cyclic AMP reside in the particulate fractions. Upon addition of exogenous cyclic AMP, protein kinase activity is stimulated 1.8, 1.2, 1.2 and 4.5-fold in nuclear, large granular, microsomal and supernatant fractions, respectively. Under these conditions, 66% of tissue activity are found in the supernatant fraction. The activity sensitive to exogenous cyclic AMP resolves into a major (84%) cytosoluble and a minor (16%) nucleomicrosomal component. The latter activity resists elution with isotonic saline and is increased in the presence of Triton X-100. Three groups of rats were studied: control and adrenalectomized with or without cortisol treatment. In whole liver homogenates, both protein kinase activity detected in absence of exogenous cyclic AMP and sensitivity of the enzyme to cyclic AMP were comparable in all groups. Moreover, the distribution patterns of proteins kinase activity amoung the fractions were essentially the same in all groups of animals, whether or not particles had been treated with Triton X-100. Finally, in cell-free experiments, glucocorticoids alone or in combination with their intracellular receptor did not modify protein kinase activity of rat liver. Thus the results reported do not support the possibility that glucocorticoids influence cyclic AMP-dependent protein kinase in rat liver. Yet, this study provides data, not available before, on subcellular distribution of this enzyme in rat liver.     

The fractionation of nuclei from mammalian cells by zonal centrifugation

1. Purified liver nuclei from adult rats separate into two main zones when centrifuged in the slow-speed zonal rotor. One zone contains diploid nuclei, the other tetraploid. 2. The effect of age on the pattern of rat liver ploidy was examined. Tetraploid nuclei are virtually absent from young animals. They increase in proportion steadily with age. Partial hepatectomy disturbs the pattern of ploidy. 3. The zonal centrifuge permits the separation of diploid, tetraploid, octaploid and hexadecaploid nuclei from mouse liver. 4. Rat liver nuclei are isopycnic with sucrose solutions of density 1.35 at 5 degrees .     

Interaction of calf uterine estrogen receptors with chicken target cell nuclei

The calf uterine estrogen receptor (ER) was used to study the capacity and the characteristics of the acceptor sites in chicken target cell nuclei. The temperature-activated ER is bound at 0 degrees C with a high affinity to all chicken cell nuclei tested (Kd = 0.4-1.0 nM). The nuclear binding displayed tissue specificity: oviduct greater than liver, heart greater than spleen greater than erythrocytes and was salt-dependent. ER binding to liver nuclei measured in 0.15 M KCl varied between 3000 and 6000 acceptor sites per nucleus. Liver nuclei isolated from estrogen-treated cockerels showed a 2-fold lower binding capacity than nuclei from non-treated chickens. When nuclei were incubated with [3H]ER from embryo liver and increasing concentrations of uterine non-radioactive-ER a progressive inhibition of the binding of the liver ER was found. These experiments suggest that liver and uterine ER compete for a common acceptor site. Liver nuclei charged in vitro with calf uterine ER were digested at 0 degree C with DNAase I and micrococcal nuclease. Both enzymes excised the ER in the form of a chromatin-ER complex. A considerable portion was associated with nucleosomal subunits and a minor fraction was associated with a nuclease-sensitive, protein-poor fraction of the chromatin.