Characterization of the iron oxide phases formed during the synthesis of core-shell FexOy@C nanoparticles modified with Ag.

Core-shell FexOy@C nanoparticles (NPs) modified with Ag were studied with x-ray diffraction, transmission electron microscopy, energy dispersive elemental mapping, Mössbauer spectroscopy, static magnetic measurements, and optical magnetic circular dichroism (MCD). FexOy@C NPs synthesized by the pyrolysis process of the mixture of Fe(NO3)3 · 9H2O with oleylamine and oleic acid were added to a heated mixture of oleylamine and AgNO3 in different concentrations. The final product was a mixture of iron oxide crystalline NPs in an amorphous carbon shell and Ag crystalline NPs. The iron oxide NPs were presented by two magnetic phases with extremely close crystal structures: Fe3O4 and γ-Fe2O3. Ag is shown to form crystalline NPs located very close to the iron oxide NPs. An assumption is made about the formation of hybrid FexOy@C-Ag NPs. Correlations were obtained between the Ag concentration in the fabricated samples, their magnetic properties and the MCD spectrum shape. Introducing Ag led to a approximately linear decrease of the NPs saturation magnetization depending upon the Ag concentration, it also resulted into the MCD spectrum shift to the lower light wave energies. MCD was also studied for the Fe3O4@C NPs synthesized earlier with the same one-step process using different heat treatment temperatures, and MCD spectra were compared for two series of NPs. A possible contribution of the surface plasmon excitation in Ag NPs to the MCD spectrum of the FexOy@C-Ag NPs is discussed.

Mg-dependent, Zn-ATPase: enzymatic characteristics, ion specificities and tissue distribution.

Mucosal crude microsomes, prepared from proximal rat small intestine, exhibited significant Mg-dependent, Zn-ATPase activity; Vmax = 23 micromoles Pi/mg protein/hr, Km = 160 nm, and Hill Coefficient, n = 1.5. Partial purification (approximately 10-fold) was achieved by detergent extraction, and centrifugation through 250 mm sucrose: Vmax = 268 units, Km = 1 nm, and n = 6. In partially purified preparations, the assay was linear with time to 60 min, and with protein concentration to 1 microg/300 microl. Activities at pH 8 and 8.5 were higher than at pH 7.2. The ATP Km was 0.7 mm, with an optimal ATP/Mg ratio of approximately 2. Ca elicited ATPase activity but did not augment the Zn-dependent activity. In partially purified preparations, the homologous salts of Co, Cd, Cu, and Mn exhibited no detectable activity. Vanadate inhibition studies yielded two component kinetics with a Ki of 12 microm for the first component, and 96 microm for the second component, in partially purified preparations. Tissue distribution analyses revealed gradients of activity. In the proximal half of the small intestine, Mg/Zn activity increased progressively from crypt to villus tip. In long axis studies, this activity decreased progressively from proximal to distal small bowel.

Cloning and gene mapping of the chromosome 13q14 region deleted in chronic lymphocytic leukemia.

Frequent deletions and loss of heterozygosity in a segment of chromosome 13 (13q14) in cases of B-cell chronic lymphocytic leukemia (CLL) have suggested that this malignancy is caused by inactivation of an unknown tumor suppressor gene located in this region. Toward the identification of the putative CLL tumor suppressor, we have constructed a high-resolution physical map of YAC, PAC, and cosmid contigs covering 600 kb of the 13q14 genomic region. In addition to densely positioned genetic markers and STSs, this map was further annotated by localization of 32 transcribed sequences (ESTs) using a combination of exon trapping, direct cDNA selection, sample sequencing of cosmids and PACs, and homology searches. On the basis of these mapping data, allelic loss analyses at 13q14 using CLL tumor samples allowed narrowing of the genomic segment encompassing the putative CLL gene to <300 kb. Twenty-three ESTs located within this minimally deleted region are candidate exons for the CLL-associated tumor suppressor gene.

Nucleotide sequence of the Kaposi sarcoma-associated herpesvirus (HHV8).

The genome of the Kaposi sarcoma-associated herpesvirus (KSHV or HHV8) was mapped with cosmid and phage genomic libraries from the BC-1 cell line. Its nucleotide sequence was determined except for a 3-kb region at the right end of the genome that was refractory to cloning. The BC-1 KSHV genome consists of a 140.5-kb-long unique coding region flanked by multiple G + C-rich 801-bp terminal repeat sequences. A genomic duplication that apparently arose in the parental tumor is present in this cell culture-derived strain. At least 81 ORFs, including 66 with homology to herpesvirus saimiri ORFs, and 5 internal repeat regions are present in the long unique region. The virus encodes homologs to complement-binding proteins, three cytokines (two macrophage inflammatory proteins and interleukin 6), dihydrofolate reductase, bcl-2, interferon regulatory factors, interleukin 8 receptor, neural cell adhesion molecule-like adhesin, and a D-type cyclin, as well as viral structural and metabolic proteins. Terminal repeat analysis of virus DNA from a KS lesion suggests a monoclonal expansion of KSHV in the KS tumor.

A high-resolution annotated physical map of the human chromosome 13q12-13 region containing the breast cancer susceptibility locus BRCA2.

Various types of physical mapping data were assembled by developing a set of computer programs (Integrated Mapping Package) to derive a detailed, annotated map of a 4-Mb region of human chromosome 13 that includes the BRCA2 locus. The final assembly consists of a yeast artificial chromosome (YAC) contig with 42 members spanning the 13q12-13 region and aligned contigs of 399 cosmids established by cross-hybridization between the cosmids, which were selected from a chromosome 13-specific cosmid library using inter-Alu PCR probes from the YACs. The end sequences of 60 cosmids spaced nearly evenly across the map were used to generate sequence-tagged sites (STSs), which were mapped to the YACs by PCR. A contig framework was generated by STS content mapping, and the map was assembled on this scaffold. Additional annotation was provided by 72 expressed sequences and 10 genetic markers that were positioned on the map by hybridization to cosmids.

Serum independence of low K+ induction of Na,K-ATPase: possible role of c-fos.

Cultured ARL15 cells respond to abnormally low extracellular K+ concentrations by increasing the abundance of Na,K-ATPase (the Na/K pump). This response is preceded by significant increases in the mRNAs of the alpha 1 and beta 1 subunits of this enzyme, implying transcriptional or post-transcriptional regulation in the response. The present study concerned the possible participation of serum factors in low K+ induction of Na,K-ATPase. In normal K+ (4.5 mM) or low K+ (0.68 mM) the presence of 10% calf serum had no effect on Na,K-ATPase activity. The serum independence of the response to low K+ raised the possibility that low K+ may itself elicit a "growth" response. Accordingly, the effect of low K+ on mRNA abundances of four proto-oncogenes (c-fos, c-myc, c-jun and c-ski) was evaluated in the early phase of the response by quantitative Northern blot analysis. The mRNA for c-fos was transiently elevated by low K+, with a peak at 30 min. In contrast, low K+ had no measurable effect on the abundances of c-myc, c-jun and c-ski, for up to 2 hr of exposure. The early elevation of c-fos mRNA makes it a candidate mediator in this signal-transduction pathway. Induction of c-fos mRNA by the phorbol ester, PMA, or by dioctanoyl glycerol, however, had no effect on Na,K-ATPase activity. These results indicate that an increase in c-fos mRNA alone is not sufficient to induce Na,K-ATPase. Whether induction of c-fos is necessary for the response to low K+ remains to be determined in future studies.

Anomalous mobilities of Na,K-ATPase alpha subunit isoforms in SDS-PAGE: identification by N-terminal sequencing.

Three isoforms of the alpha subunit of Na,K-ATPase, alpha 1, alpha 2, and alpha 3 have been characterized at the DNA, mRNA and protein levels. In admixtures, isoforms migrate as doublets (i.e. alpha 1 and another band originally designated alpha +, comprising alpha 2 + alpha 3) when analyzed by SDS-PAGE. As deduced from cDNA sequences their masses range from 111.7 to 112.6 kDa. With conventional protein standards, however, SDS-PAGE yields nominal masses of 85-105 kDa. In this system, the presence of a doublet that reacted with a polyclonal anti-Na,K-ATPase antibody in the kidney was interpreted as indicating two molecular or conformational species of the kidney alpha sub-unit (Siegel, G.J. and Desmond, T.J. (1989) J. Biol. Chem. 264, 4751-4754). We report that Na,K-ATPase purified from dog, guinea pig and rat kidney medulla or from rat brain, can yield two distinct bands when analyzed by SDS-PAGE or STS-PAGE, migrating between 85 and 105 kDa. An additional band migrating at 117 and 120 kDa appears often in enzyme purified from rat and guinea pig kidney medulla. The apparent molecular weights and relative intensities of these bands vary with temperature and duration of incubation during sample preparation. N-terminal sequencing and monospecific antibody probes revealed that the two distinct bands obtained from the kidney enzyme consist only of the alpha 1 isoform. The band appearing at 117-120 kDa also contains only the alpha 1 N-terminal sequence. In contrast, as reported earlier (Sweadner, K.J. (1979) J. Biol. Chem. 254, 6060-6067), the doublet seen in brain preparations consists of alpha 1 and alpha 2 or (alpha 2 + alpha 3). We conclude that monospecific antibody probes or N-terminal sequencing must be used to identify Na,K-ATPase isoforms by SDS- or STS-PAGE. In addition, gel conditions that may affect the mobilities of the isoforms are discussed.

Na(+)-K(+)-ATPase in adipocyte differentiation in culture.

Differentiation of 3T3-L1 cells from a fibroblast to an adipocyte phenotype results in an approximately 50% decline in Na(+)-K(+)-ATPase activity and ouabain-sensitive 86Rb uptake. Kinetic analysis revealed a K 1/2 for Na+ of approximately 14 mM, a Km for ATP of approximately 0.4 mM, and maximal activation by sodium dodecyl sulfate at a 0.05 (wt/wt) detergent/protein ratio in both mature fibroblasts and adipocytes. Both fibroblasts and adipocytes exhibited Na(+)-K(+)-ATPase activity with an inhibition constant (Ki) for ouabain of approximately 10(-4) M. In addition, adipocytes exhibited a second component representing 30% of total activity with a Ki of approximately 5 x 10(-7) M. The emergence of biphasic ouabain inhibition kinetics in adipocytes raised the possibility of a change in alpha-subunit isoform composition with cytodifferentiation. This inference was evaluated by isoform-specific mRNA analysis (Northern blots) and by alpha-isoform-specific immunoassays (Western blots). Northern blots revealed a modest decrease in mRNA alpha 1, a striking increase in mRNA alpha 2, and a significant loss of mRNA beta content with differentiation of fibroblasts to adipocytes. By immunoassay, fibroblasts exhibited the alpha 1-isoform. Adipocytes exhibited an admixture of alpha 1- and alpha 2-isoforms, with alpha 2 being the more abundant isoform. There was no one-to-one correspondence either between the mRNA isoform and alpha-subunit abundances or between alpha-subunit abundances and enzymatic activity, suggesting that regulation occurs at multiple levels in this system. Findings indicate, however, that a shift in alpha-isoform composition accompanied by a change in ouabain inhibition kinetics occurs with cytodifferentiation.

Effect of high extracellular K+ on Na-K-ATPase in cultured canine kidney cells.

The Madin-Darby canine kidney (MDCK) cell line was used to evaluate the influence of high extracellular K+, independent of hormonal effects, on renal Na-K-adenosinetriphosphatase (ATPase) activity and abundance. Confluent cell monolayers were incubated in control (5 mM) or high K+ (7.5 mM) medium for 24 h. Exposure to high K+ elicited a 46% rise in Na-K-ATPase activity and a 55% increase in ouabain-sensitive 86Rb uptake. Na-K-ATPase abundance, estimated from the number of ouabain-binding sites, also increased 63% over control in cells exposed to 7.5 mM K+, and as a consequence there was no statistically significant change in the catalytic turnover number. Northern blot analysis using rat cDNA probes for the alpha 1- and beta-subunits showed no corresponding changes in subunit-specific mRNA abundances at 24 h. We conclude that chronic exposure to high extracellular K+ produces a rise in renal epithelial Na-K-ATPase activity and active K+ transport, independent of changes in aldosterone, renal blood flow, or extracellular Na+ concentration. This effect is due to an increase in enzyme abundance rather than a change in catalytic turnover rate. The results of Northern analysis suggest that regulation of Na-K-ATPase activity and abundance by high K+ may involve translational or posttranslational mechanisms, but further study with cDNA probes of canine origin is needed to resolve this issue.

Cell-free transcription and translation of Na,K-ATPase alpha and beta subunit cDNAs.

Synthetic mRNAs (i.e. cRNA alpha and cRNA beta) were obtained by cell-free transcription of M13 KS(+) (Bluescript) expression vectors which contained the entire coding region of the alpha or beta subunits of lamb kidney Na,K-ATPase. Translation in reticulocyte lysates of cRNA alpha yielded full length alpha polypeptide, as well as a limited array of immunoprecipitable lower molecular weight products. cRNA beta yielded a single immunoprecipitable full length polypeptide. Association of the alpha polypeptide with the microsomal membranes was obtained only co-translationally. Fifteen to 50% of the membrane-associated alpha subunit was resistant to extraction with alkali. The resistance of a 29-kDa fragment to trypsinolysis indicated that the alpha subunit was inserted into microsomal membranes. In the presence of dog pancreatic microsomes, the beta polypeptide was glycosylated as indicated by the appearance of three higher molecular weight polypeptides that were sensitive to endoglycosidase H and bound to Concanavalin A. The beta subunit was predominantly translocated into the lumen of the endoplasmic reticulum since 90% of the mass of the membrane-associated beta polypeptide was resistant to trypsin (i.e. reduced in size from 40 kDa to 37.5 kDa), and 95% of all of the beta chains were resistant to extraction with alkali. Neither the alpha nor the beta subunits have NH2-terminal leader signal sequences, but both may require the signal recognition receptor for membrane insertion, as evidenced by inhibition of incorporation of both subunits into microsomes pretreated with N-ethylmaleimide. Simultaneous translation of cRNA alpha and cRNA beta did not enhance membrane insertion of either the alpha or beta polypeptide.

Isoforms of Na,K-ATPase in Artemia salina: II. Tissue distribution and kinetic characterization.

To characterize the molecular properties conveyed by the isoforms of the alpha subunit of Na,K-ATPase, the two major transepithelial transporting organs in the brine shrimp (Artemia salina), the salt glands and intestines, were isolated in pure form. The alpha isoforms were quantified by ATP-sensitive fluorescein isothiocyanate (FITC) labeling. The salt gland enzyme exhibits only the alpha 1 isoform, whereas the intestinal enzyme exhibits both the alpha 1 and the alpha 2 isoforms. After 32 hours of development, Na,K-ATPase activity [in mumol Pi/mg protein/hr (1 mu)] in whole homogenates was 32 +/- 6 in the salt glands and 12 +/- 3 in the intestinal preparations (mean +/- SEM). The apparent half-maximal activation constants (K1/2) of the salt gland enzyme as compared to the intestinal enzyme were 3.7 +/- 0.6 mM vs. 23.5 +/- 4 mM (P less than 0.01) for Na+, 16.6 +/- 2.2 mM vs. 8.29 +/- 1.5 mM for K+ (P less than 0.01), and 0.87 +/- 0.8 mM vs. 0.79 +/- 1.1 mM for ATP (NS). The apparent Ki's for ouabain inhibition were 1.1 x 10(-4) M vs. 2 x 10(-5) M, respectively. Treatment of whole homogenates with deoxycholic acid (DOC) produced a maximal Na,K-ATPase activation of 46% in the salt gland as compared to 23% in the intestinal enzyme. Similar differences were found with sodium dodecyl sulfate (SDS). The two distinct forms of Na,K-ATPase isolated from the brine shrimp differed markedly in three kinetic parameters as well as in detergent sensitivity.(ABSTRACT TRUNCATED AT 250 WORDS)

Isoforms of Na,K-ATPase in Artemia saline: I. Detection by FITC binding and time course.

Partially purified Na,K-ATPase from whole nauplii at various stages of development, analyzed by SDS-PAGE, reveals a polydisperse beta and two alpha subunits (denoted alpha 1 and alpha 2). In the absence of Ca2+, ATP-inhibitable fluorescein isothiocyanate (FITC) labeling is restricted to the alpha subunit of this enzyme, even in crude naupliar homogenates. The intensity of the alpha-specific fluorescent signal (i.e., the sum of the yield from both alpha isoforms) is proportional to Na,K-ATPase activity during development. FITC-labeled subunits were detected at 8 hr of development prior to the detection of measurable Na,K-ATPase activity. The alpha 2/alpha 1 ratio changed from an initial value of 1.25 to a peak of 1.75 at 32 hr of development, then reverted to a ratio of 1.25 by 42 hr, and remained constant thereafter. Pulse chase studies with 35S-methionine indicated that the developmental increase in enzyme activity is coincident with amino acid incorporation into the alpha subunits, implying that enzyme synthesis is active during enzyme accumulation.

Internal image properties of a monoclonal auto-anti-idiotypic antibody and its binding to aldosterone receptors.

A monoclonal anti-idiotypic antibody (H10E4C9F) that interacts with the aldosterone receptors was generated using an auto-anti-idiotypic approach by immunizing a mouse with a 3-O-carboxymethyloxime of aldosterone coupled to bovine serum albumin. This antibody, an IgG1, displayed internal image properties of aldosterone and was considered as an Ab2 beta according to the following criteria. (i) H10E bound to Fab fragments of affinity-purified rabbit anti-aldosterone antibody that had high affinity for aldosterone (Kd = 5 x 10(-10) M). Binding was inhibited by aldosterone but not by estradiol. (ii) H10E inhibited [3H]aldosterone binding to rabbit polyclonal antibodies and also to murine monoclonal antibodies raised during the same fusion. Inhibition was concentration-dependent. These results are consistent with the antibody recognizing an interspecies cross-reacting epitope involved in the aldosterone combining site. (iii) The antibody could be affinity-purified on an immobilized monoclonal anti-aldosterone antibody. (iv) It inhibited [3H]aldosterone binding to rabbit kidney cytosolic aldosterone receptors but had no effect on glucocorticoid receptors. Additional evidence for the interaction of H10E with aldosterone receptors was provided by glycerol gradients analyses: the anti-idiotypic antibody displaced [3H]aldosterone and [3H]corticosterone from the native untransformed 9 S aldosterone receptor in the presence of RU 26988, a specific marker of glucocorticoid receptors. All of the above are consistent with the first successful production of a monoclonal antibody that mimics aldosterone and interacts specifically with the steroid binding domain of aldosterone receptors.

Thyroidal regulation of rat renal and hepatic Na,K-ATPase gene expression.

Na,K-ATPase activity, Na,K-ATPase alpha- and beta-subunit mRNA abundance (mRNA alpha and mRNA beta), and gene transcription rates were determined in kidney cortex and liver of hypothyroid and triiodothyronine (T3)-treated rats. In hypothyroid rats, Na,K-ATPase activity (expressed per unit of DNA) was 3.6-fold greater in kidney cortex than liver, and the abundance of mRNA alpha and mRNA beta in kidney cortex exceeded that of liver by 2.8- and 5.2-fold, respectively. In vitro nuclear run-on analysis revealed similar rates of Na,K-ATPase alpha and beta gene transcription in nuclei isolated from either kidney cortex or liver. Administration of T3 for 72 h elicited a 2.3-fold stimulation of renal Na,K-ATPase activity that was associated with a 3.1- and 2.6-fold increase of mRNA alpha and mRNA beta content, respectively. In contrast, T3 induced a 1.3-fold stimulation of liver Na,K-ATPase activity accompanied by a 7.3-fold increase in mRNA alpha and no change in mRNA beta abundance. Transcription rates of alpha and beta genes (assayed by nuclear run-on) in renal cortex were both stimulated 1.8-fold in response to T3 injection. Similarly in liver nuclei, T3 treatment produced a 1.4- and 1.3-fold stimulation in the rate of alpha and beta gene transcription, respectively. These results indicate that significant discrepancies exist in the quantitative relationships between control and T3-induced changes in renal and hepatic enzyme activity, mRNA abundance and rate of gene transcription, and imply that the T3-induced increase in Na,K-ATPase abundance is mediated at both transcriptional and post-transcriptional steps.

Increased abundance of Na+-K+-ATPase mRNAs in response to low external K+.

Exposure of ARL 15 cells, an established line from adult rat liver, to external K+ concentrations less than 1 mM for 24 h increases Na+-K+ pump abundance (Na+-K+-ATPase) (J. Gen. Physiol. 87:591-606, 1986). We found that treatment of confluent monolayers of ARL 15 cells with low-K+ medium (0.65 mM) caused a 100% increase in total RNA content per plate after 24 h, as well as a 25% increase in DNA and protein content per plate. Concomitant with this growth effect, low-K+ exposure for 6 h elicited 60% increases in mRNA alpha and mRNA beta, the mRNAs that encode the constituent subunits of the Na+-K+-ATPase, in a polyadenylated RNA fraction. At 24 h, however, the abundance of mRNA alpha increased by 290%, whereas mRNA beta increased by only 70%. Moreover, in both control and low-K+-treated cells, mRNA alpha was 30-fold or more greater in abundance than mRNA beta. This discrepancy in abundance was also present in rat liver, but not in cultured MDCK cells. The differences in abundance of mRNA alpha and mRNA beta suggest that the liver may have an unusual subunit composition or biosynthetic mechanism. Nevertheless, the increases in the abundance of mRNA alpha and mRNA beta are sufficient to account for the observed 70-100% increase in Na+-K+-ATPase activity in response to low external K+.

Kinetic analysis of Na,K-activated adenosine triphosphatase induced by low external K+ in a rat liver cell line.

Exposure of ARL 15 cells to medium containing reduced concentrations of K+ (0.65 mM) elicited a 50-100% increase in Na,K-ATPase activity. The inhibition by ouabain of both the basal and the induced enzyme conformed to a single-site model (KI = 1 x 10(-4) M). The low K+-induced increment in Na,K-ATPase activity was accompanied by an equivalent increase in the abundance of Na,K-pump sites estimated by ouabain-stabilized ("back-door") phosphorylation, such that the calculated catalytic turnover number of approximately 8000/min was minimally changed. Comparison of the dependence of ouabain-inhibitable K+ uptake on intracellular Na+ and on extracellular K+ concentrations in control and low K+-treated cells revealed no change in the respective half-maximal stimulatory concentrations for these cations, whereas the maximal rate of active K+ uptake in cells exposed to low external K+ increased by nearly 100%. The derived Hill coefficients for active K+ transport rate were also unchanged by the low K+ treatment (i.e. approximately 1.4 for extracellular K+ and 2.6 for intracellular Na+). Na,K-ATPase activity of basal and low K+-induced cells calculated from the measured maximal Na,K transport rate closely approximated the Na,K-ATPase activity measured enzymatically in unfractionated cell lysates under Vmax conditions, suggesting that all or most of the Na,K-ATPase enzymatic units present in both basal and stimulated states are functionally active. Northern blot analysis of RNA isolated from control cells indicated the presence of the Na,K-ATPase alpha-I isoform of the enzyme which increased by nearly 200% following incubation of the cells in low-K+ medium. By contrast, the alpha-II and alpha-III mRNAs were undetectable in either the basal or low K+-stimulated state. These results indicate that the Na,K-ATPase induced by incubation of ARL 15 cells in low-K+ medium is kinetically and functionally indistinguishable from the basal enzyme, and that only the alpha-I isoform is expressed under control and low-K+ conditions.