Glutamine synthetase regulation by dexamethasone,RU486, and compound A in astrocytes derived from aged mouse cerebral hemispheres is mediated via glucocorticoid receptor

Molecular and Cellular Biochemistry - Glucocorticoids (GCs) regulate astrocyte function, while glutamine synthetase (GS), an enzyme highly expressed in astrocytes, is one of the most remarkable...     

Novel lipophilic amidate oxorhenium and oxotechnetium complexes as potential brain agents: synthesis, characterization and biological evaluation

Novel oxorhenium and oxotechnetium complexes based on the tetradentate 1-(2-hydroxybenzamido)-2-(pyridinecarboxamido)benzene, H3L, ligand have been synthesized and characterized herein. Thus, by reacting equimolar quantities of the triply deprotonated ligand L3- with the suitable MO3+ precursor, the following neutral MOL complexes could be easily produced following similar synthetic routes: M = Re (1), M = 99gTc (2), and M = 99mTc (3). Complexes 1 and 2, prepared in macroscopic amounts, were chemically characterized and their structure determined by single-crystal X-ray analysis. They are isostructural metal chelates, adopting a distorted square pyramidal geometry around the metal. The N3O donor atom set of the tetradentate ligand defines the basal plane and the oxygen atom of the M = O core occupies the apex of the pyramid. Complex 3 forms quantitatively at tracer level by mixing the H3L ligand with Na99mTcO4 generator eluate in aqueous alkaline media and using tin chloride as reductant in the presence of citrate. Its structure was established by chromatographic comparison with prototypic complexes 1 and 2 using high-performance liquid chromatographic techniques. When challenged with excess glutathione in vitro, complex 3 is rapidly converted to hydrophilic unidentified metal species. Tissue distribution data after administration of complex 3 in vivo revealed a significant uptake and retention of this compound in brain tissue.     

Tetraamine‐modified octreotide and octreotate: labeling with 99mTc and preclinical comparison in AR4‐2J cells and AR4‐2J tumor‐bearing mice

Two somatostatin analogues, [^99mTc]Demotide and [^99mTc]Demotate 4, were compared with [^99mTc]Demotate 1, a previously reported somatostatin receptor subtype 2 (sst₂) targeting tracer. Conjugates were prepared by coupling an open‐chain tetraamine chelator to D ‐Phe¹ of [Tyr³]‐octreotide or [Tyr³]‐octreotate, respectively, via a p‐benzylaminodiglycolic acid spacer adopting solid‐phase peptide synthesis techniques. Peptide conjugates were collected in a highly pure form after chromatographic purification. Eventually, [^99mTc]Demotide and [^99mTc]Demotate 4 were obtained in ～1 Ci/µmol specific activity and >96% purity after labeling under alkaline conditions. Demotide and Demotate 4 exhibited similar high binding affinities for the sst₂ expressed in AR4‐2J cells with IC₅₀ values 0.16 and 0.10 nM, respectively. The (radio)metallated analogues [^99mTc]Demotide and [^99mTc]Demotate 4 showed equally high affinities to the sst₂ during saturation binding assays in AR4‐2J cell membranes (K_ds 0.08 and 0.07 nM, respectively). During incubation at 37 °C with AR4‐2J cells, the radiopeptides internalized effectively via a receptor‐mediated process, with [^99mTc]Demotate 4 exhibiting a faster internalization rate than [^99mTc]Demotide. After injection in athymic mice bearing sst₂‐expressing AR4‐2J tumors, the radiotracers showed high and specific uptake in the tumor (>25%ID/g at 1 h) and in the sst₂–positive organs. However, both [^99mTc]Demotide and [^99mTc]Demotate 4 showed unfavorably higher background activity, especially in the abdomen, in comparison to [^99mTc]Demotate 1 and are, therefore, less suited than [^99mTc]Demotate 1 for sst₂‐targeted tumor imaging in man. Copyright © 2005 European Peptide Society and John Wiley & Sons, Ltd.     

Plasma Membrane Mechanical Stress Activates TRPC5 Channels

Mechanical forces exerted on cells impose stress on the plasma membrane. Cells sense this stress and elicit a mechanoelectric transduction cascade that initiates compensatory mechanisms. Mechanosensitive ion channels in the plasma membrane are responsible for transducing the mechanical signals to electrical signals. However, the mechanisms underlying channel activation in response to mechanical stress remain incompletely understood. Transient Receptor Potential (TRP) channels serve essential functions in several sensory modalities. These channels can also participate in mechanotransduction by either being autonomously sensitive to mechanical perturbation or by coupling to other mechanosensory components of the cell. Here, we investigated the response of a TRP family member, TRPC5, to mechanical stress. Hypoosmolarity triggers Ca²⁺ influx and cationic conductance through TRPC5. Importantly, for the first time we were able to record the stretch-activated TRPC5 current at single-channel level. The activation threshold for TRPC5 was found to be 240 mOsm for hypoosmotic stress and between −20 and −40 mmHg for pressure applied to membrane patch. In addition, we found that disruption of actin filaments suppresses TRPC5 response to hypoosmotic stress and patch pipette pressure, but does not prevent the activation of TRPC5 by stretch-independent mechanisms, indicating that actin cytoskeleton is an essential transduction component that confers mechanosensitivity to TRPC5. In summary, our findings establish that TRPC5 can be activated at the single-channel level when mechanical stress on the cell reaches a certain threshold.     

Differential responsiveness of late passage C-6 glial cells and advanced passages of astrocytes derived from aged mouse cerebral hemispheres to cytokines and growth factor: Glutamine synthetase activity

In this study, we were interested to compare the responsiveness to growth factors, NGF, b-FGF and EGF and cytokines, IL1β, and TNF-α, in late passages (74–79) C6 glial cells committed astrocytes and astrocytes of advanced passages (26–28) in cultures derived from aged mouse cerebral hemispheres (MACH). Cultures were grown in either DMEM or chemically defined medium (CDM/TIPS) in order to test the effects of growth factors or cytokines. The activity of glutamine synthetase (GS), a marker for astrocytes, was used as a test parameter. We found that treatment with growth factors increased GS activity in both glial cell culture systems with the exception of EGF in C-6 glial cells. Treatment with cytokines markedly decreased GS activity in the late passage C6 glial cells whereas only TNF-α had a similar effect on MACH astrocytes. In view of the generally opposite effects of growth factors and cytokines on GS activity, we-speculate that these molecules which are also endogenously present in glial cells may play a role in the maintenance of cellular homeostasis.     

Two classes of ouabain receptors in chick ventricular cardiac cells and their relation to (Na+,K+)-ATPase inhibition, intracellular Na+ accumulation, Ca2+ influx, and cardiotonic effect

The biochemical and pharmacological properties of the (Na+,K+)-ATPase have been studied at different stages of chick embryonic heart development in ovo and under cell culture conditions. The results show the existence of two families of ouabain binding sites: a low affinity binding site with a dissociation constant (Kd) of 2-6 microM for the ouabain-receptor complex and a high affinity binding site with a Kd of 26-48 nM. Levels of high affinity sites gradually decrease during cardiac ontogenesis to reach a plateau near 14 days of development. Conversely the number of low affinity binding sites is essentially invariant between 5 days and hatching. Cultured cardiac cells display the same binding characteristics as those found in intact ventricles. Inhibition of 86Rb+ uptake in cultured cardiac cells and an increase in intracellular Na+ concentration, due to (Na+,K+)-ATPase blockade, occur in a ouabain concentration range corresponding to the saturation of the low affinity ouabain site. Ouabain-stimulated 45Ca2+ uptake increases in parallel with the increase in the intracellular Na+ concentration. It is suppressed in Na+-free medium or when Na+ is replaced by Li+ suggesting that the increase is due to the indirect activation of the Na+/Ca2+ exchange system in the plasma membrane. Dose-response curves for the inotropic effects of ouabain on papillary muscle and on ventricular cells in culture indicate that the development of the cardiotonic properties is parallel to the saturation of the low affinity binding site for ouabain. Therefore, inhibition of the cardiac (Na+,K+)-ATPase corresponding to low affinity ouabain binding sites seems to be responsible for both the cardiotonic and cardiotoxic effects of the drug.     

Ontogenic appearance of Ca2+ channels characterized as binding sites for nitrendipine during development of nervous, skeletal and cardiac muscle systems in the rat

The appearance of specific receptors for the Ca2+ channel antagonist nitrendipine has been followed during the fetal and post-natal development of rat brain without cerebellum, cerebellum, skeletal muscle and cardiac muscle. The number of nitrendipine receptors is low at the fetal stage and increases drastically during post-natal development of brain, cerebellum, skeletal muscle and cardiac muscle. The time course of this increase is different for each type of tissue studied. No significant change in receptor ligand dissociation constant (Kd) can be detected over the development period studied. The results are discussed in relation with the known properties of the differentiation process in the four types of excitable tissues studied.     

K-Cl cotransporter gene expression during human and murine erythroid differentiation

The K-Cl cotransporter (KCC) regulates red blood cell (RBC) volume, especially in reticulocytes. Western blot analysis of RBC membranes revealed KCC1, KCC3, and KCC4 proteins in mouse and human cells, with higher levels in reticulocytes. KCC content was higher in sickle versus normal RBC, but the correlation with reticulocyte count was poor, with inter-individual variability in KCC isoform ratios. Messenger RNA for each isoform was measured by real time RT-quantitative PCR. In human reticulocytes, KCC3a mRNA levels were consistently the highest, 1-7-fold higher than KCC4, the second most abundant species. Message levels for KCC1 and KCC3b were low. The ratios of KCC RNA levels varied among individuals but were similar in sickle and normal RBC. During in vivo maturation of human erythroblasts, KCC3a RNA was expressed consistently, whereas KCC1 and KCC3b levels declined, and KCC4 message first increased and then decreased. In mouse erythroblasts, a similar pattern for KCC3 and KCC1 expression during in vivo differentiation was observed, with low KCC4 RNA throughout despite the presence of KCC4 protein in mature RBC. During differentiation of mouse erythroleukemia cells, protein levels of KCCs paralleled increasing mRNA levels. Functional properties of KCCs expressed in HEK293 cells were similar to each other and to those in human RBC. However, the anion dependence of KCC in RBC resembled most closely that of KCC3. The results suggest that KCC3 is the dominant isoform in erythrocytes, with variable expression of KCC1 and KCC4 among individuals that could result in modulation of KCC activity.     

Intramolecular azo-bridge as a cystine disulfide bond surrogate: Somatostatin-14 and brain natriuretic peptide (BNP) analogs

Cystine disulfide bond is a common feature in numerous biologically active peptides and proteins and accordingly its replacement by various surrogates presents a potential route to obtain analogs with improved pharmacokinetic characteristics. The purpose of the present study was to assess whether an azo-bridge can serve as such a surrogate. In view of the marked clinical significance of somatostatin and the brain natriuretic peptide (BNP) we choose these peptides as a model. Three cyclic-azo somatostatin analogs and three cyclic-azo BNP analogs were effectively prepared in solution through azo bond formation between p-amino phenylalanine and His or Tyr residues that were positioned in the peptide sequences in place of the native Cys residues. The peptides binding affinities to the sst? and ANP-receptor (NPR-A) expressed on rat acinar pancreating carcinoma AR4-2J cell membranes and HeLa cells, respectively, were examined. The somatostatin analogs displayed good to moderate affinities to the rat sst? in the nM range with best results obtained with peptide 2, that is, IC?? = 8.1 nM. Molecular dynamics simulations on these peptides suggests on a correlation between the observed binding potencies and the degree of conformational space overlapping with that of somatostatin. The BNP analogs exhibited binding affinities to the NPR-A in the nM range with best results obtained with BNP-1, that is, IC?? = 60 nM.     

Ontogenic appearance of Na+ channels characterized as high affinity binding sites for tetrodotoxin during development of the rat nervous and skeletal muscle systems

The appearance of the voltage-dependent Na+ channel during the fetal and post-natal development of rat brain, cerebellum and skeletal muscle has been followed using a highly radiolabelled derivative of tetrodotoxin. The number of Na+ channels is low at the fetal stage and increases drastically during post-natal development. The time-course of this increase is different in brain, cerebellum and skeletal muscle. Changes in affinity of the Na+ channel for tetrodotoxin occur during brain and cerebellum development. The results are discussed in relation with the maturation of the three types of excitable tissues.