Metabolic characteristics of mitochondria isolated from rabbit brain

Abstract— Data on the metabolic characteristics of mitochondria from rabbit brain have been obtained using low concentrations (100–300 μm) of ¹⁴C-labelled substrates of the Krebs tricarboxylic acid cycle. Oxygen consumption was measured polarographically with a Clark-type electrode. Products of the reactions were separated by chromatography on Dowex-1 columns. Data are reported for relative respiratory quotients of various substrates, respiratory control ratios, accumulation of ¹⁴C in various tricarboxylic acid cycle intermediates and the effect of malate and several inhibitors on these parameters. The data have been compared with similar experiments on mitochondria from rabbit heart. Mitochondria from rabbit brain differ substantially from heart mitochondria: those from brain have a very low capacity for oxidation of acetate and other short chain fatty acids; they do not form j3-hydroxybutyrate; they produce substantial amounts of α-ketoglutarate and require added dicarboxylic acid to yield a maximum respiratory quotient. Like those from heart, brain mitochondria have a high capacity for pyruvate oxidation and a low K_m for this substrate. The results have been discussed and compared with work reported by other investigators.     

Uptake of adenosine by isolated bovine cortex microvessels

The uptake of adenosine is studied in microvessels isolated from a bovine cortex. The KM value for adenosine uptake is 1.92 microM and the Vmax is 1.93 picomole/mg protein/10 min. This high affinity uptake system is very sensitive to inhibition by dipyridamole and papaverine. The uptake of adenosine by microvessels is also inhibited by CuCl2 and by high concentration (2 mM) of adenine nucleotides. Using a series of four xanthines is observed that the adenosine uptake system is most inhibited by 3-methyl-l-(5'-oxohexyl)-7-propylxanthine and the least by caffeine. Theophylline causes a stimulation of adenosine uptake by microvessels. The results obtained agree with the existence of the nucleoside transport system associated with the blood-brain barrier, as previously observed by in vivo studies and experiments with rat brain capillaries.     

Peptidyl dipeptidase in rabbit brain microvessels.

The activity of peptidyl dipeptidase (peptidyldipeptide hydrolase, EC 3.4.15.1), also known as angiotensin-converting enzyme, was studied in small blood vessel preparations isolated from rabbit brain. The vascular preparation contained arterioles and capillaries and was essentially free of extravascular material. Enzymatic activity was demonstrated in microvessel homogenates using both hippuryl-histidyl-leucine and tritium-labeled angiotensin I as substrates. Activity in the microvessels was dependent on the presence of chloride ion and was sensitive to inhibition by converting enzyme inhibitors previously shown to be effective in both vivo and in vitro. Specific activity in the micro-vessels was approximately 20 times that in homogenates of brain, and was almost 60% of that found in rat lung homogenates. The data were consistent with an endothelial localication for peptidyl dipeptidase in the cerebral vasculature and supports the proposal that this enzyme has a physiological role in extrapulmonary vascular beds.     

Capacity for energy metabolism in microvessels isolated from rat brain

Numerous methods used for the isolation of brain microvessels involve procedures which disturb the structural integrity of the cells and their organelles. In the present study, analysis of the adenylate energy charge and content as well as the incorporation of adenosine derivatives in isolated rat brain microvessels indicated a lesion of the mechanisms of energy production. The results show that experiments on isolated microvessels prepared by a mechanical homogenization exerting shear forces should be interpretated with caution when the rate of energy metabolism is a significant factor in the study.     

Effects of different oxidizing agents on neutral amino acid transport systems in isolated bovine brain microvessels

Using isolated bovine brain microvessels as an in vitro model of the blood-brain barrier (BBB) we have evaluated the role of free radical generating solutions on some amino acid transport systems operating on the endothelial cell membrane. Fe(2+)/ascorbate, phenylhydrazine and CuSO(4) did not affect any of the transport system tested, while exposure of bovine brain microvessels to tert-butylhydroperoxide (t-BHP) caused a reduced capacity to take up small neutral amino acids via the Na(+)-dependent A-system. The presence of glucose during t-BHP treatment did not prevent this inhibition, which was partially counteracted when the isolated microvessels were incubated with 5mM inosine before the oxidative stress. Incubation of the isolated capillaries with 5mM dithiothreitol, after exposure to t-BHP, resulted in a 50% recovery of the alpha-methylaminoisobutyrate (MeAIB) uptake by the A-system. Treatment with t-BHP, which had no effect on the L-system of neutral amino acid transport, caused a significant decrease of the intracellular levels of ATP, of glutathione (GSH), and of gamma-glutamyltranspeptidase (GGT) activity, while no significant modification of hexokinase (HK) or of alkaline phosphatase (ALKP) activities were observed. Oxidative damage of the BBB appears therefore to impair essentially the metabolic pathways which ensure the energy requirement for the endothelial cells, thus inhibiting the energy-dependent amino acid transport system "A".     

On the disposition of phospholipids in freshly isolated myelin sheath preparations from bovine brain

The extent of availability of the four major classes of phospholipids in freshly isolated bovine brain myelin has been studied using phospholipase C (Clostridium perfringens), phospholipase A (bee venom), sphingomyelase (Staphalococcus aureus) and trinitrobenzenesulphonate. The results have been compared with those of a previous study (Gwarsha et al., 1984). Taken together, the data suggest that 47–67% of the phosphatidylcholine, 45–66% of the ethanolamine-containing phosphoglycerides, 52–55% of the spingomyelin and 10–32% of the phosphatidylserine + phosphatidylinositol in the fresh myelin is available to these probes and hence may be located at the external surface of the membrane bilayer.     

Angiotensin-converting enzyme activity in isolated brain microvessels.

The localization of angiotensin-converting enzyme (kininase II; ACE) in bovine cerebral cortex was studied by mechanically isolating microvessels from surrounding brain parenchyma. ACE specific activity, as assayed by generation of L-histidyl-L-leucine from the synthetic substrate hippuryl-L-histidyl-L-leucine, was enriched approximately 30 times in microvessels compared to homogenates of intact cerebral cortical gray matter. The nonapeptide 9a, SQ20,881), the orally active anti-hypertensive drug, 2-D-methyl-3-mercaptopropanoyl-L-proline (SQ14,225), and the vasoactive peptides bradykinin and angiotensin II inhibited this activity in a dose-dependent fashion. Brain microvessel ACE required chloride for optimal activity, was potentiated by cobalt nitrate, and was inhibited by the chelating agents EDTA and o-phenanthroline. Enzymatic generation of histidyl-leucine also was observed with the naturally occurring decapeptide substrate angiotensin I. In addition, microvessels obtained from bovine cerebellar cortex, hippocampus and corpus striatum, as well as from the cerebral cortex of Sprague-Dawley rats, were enriched in ACE activity. The presence of angiotensin-converting enzyme in brain microvessels suggests that cellular components of the blood-brain barrier may participate in the metabolism of peptide hormones such as angiotensin I and bradykinin within the central nervous system.     

The lipid composition of axons from bovine brain

Abstract— Bovine axons derived from myelinated CNS axons were found to have 13.5% lipid. This lipid was composed of 20.1% cholesterol, 20.1% galactolipid, 14.6% ethanolarhine phosphatides (56.4% in the plasmalogen form), 18.3% choline phosphatides (10.0% in the plasmalogen form), 9.3% sphingomyelin, 5.6% phosphatidyl serine and 3.4% phosphatidyl inositol. The bovine axons had 0.33 μg ganglioside NeuNAc/mg dry weight. The axon gangliosides were found to contain the four major types of bovine gangliosides, as well as gangliosides G_M2 and G_D3. The latter two amounted to 20.9 and 15.8 mole per cent respectively, of total gangliosides. On a molar basis, about one half of the gangliosides were monosialogangliosides, with a decreased contribution by gangliosides G_T1 and GD_1b relative to ganglioside distributions which have been reported for most other CNS components. The relationship of the bovine axonal lipid composition to bovine white matter and its constituents, as well as to other CNS and PNS axonal preparations is discussed.     

Lipoprotein lipase and acid lipase activity in rabbit brain microvessels.

A preparation of cerebral microvessels was used to demonstrate the presence of lipoprotein lipase and acid lipase activity in the microvasculature of rabbit brain. Microvessels, consisting predominantly of capillaries, small arterioles, and venules, were islated from rabbit brain. Homogenates were assayed for lipolytic activity using a glycerol-stabilized trioleoylglycerol-phospholipid emulsion as substrate. Lipoprotein lipase activity was characterized with this substrate by previously established criteria including an alkaline pH optimum, increased activity in the presence of heparin and heat-inactivated plasma, and reduced activity in the presence of NaCl and protamine sulfate. A different substrate, containing trioleoylglycerol incorporated into phospholipid vesicles, was used to reveal acid lipase activity that was not affected by heparin, plasma, NaCl, or protamine sulfate. Lipoprotein lipase did not show activity with the vesicle preparation as substrate. Intact microvessels, when incubated in the presence of heparin, release lipoprotein lipase into the incubation solution. In contrast, release of acid lipase activity from intact microvessels was not dependent on heparin. The data show the presence of both lipoprotein lipase and acid lipase in brain microvessels and suggest that lipoproteins are metabolized within the cerebral vasculature.     

Prostaglandin levels in isolated brain microvessels and in normal and norepinephrine-stimulated cat brain homogenates

The levels of PGD₂, PGE₂, PGF_2α and 6-keto-PGF_1α (6KF_1α) produced from endogenous archidonic acid (AA) were quantitated in cat cerebral cortical homogenates and microvessels isolated from cat cerebral cortex using gas chromatography/mass spectrometry (GC/MS). There was a six-fold enrichment of 6KF_1α levels in isolated microvessels, compared to homogenates, suggesting that 6KF_1α is of vascular, rather than neuronal origin. In order to further understand any possible role that norepinephrine (NE)_might have on modulation of PG synthesis, we studied the effects of 0.5 mM NE on PG synthesis from endogenous AA and from ³H-PGG₂, the endoperoxide precursor of PGs. In cat cortical homogenates NE induced a 74% increase in PGD₂ and PGF_2α, a 62% increase in PGE₂, and a 36% increase in 6KF_1α, as measured by GC/MS. NE caused a twofold increase in the conversion of ³H-PGG₂ to ³h-PGG_2α, with a concomitant decrease in ³H-PGE₂ and ³H-6KF_1α formation, and no change in ³H-PGD₂ synthesis. NE had no effect on the total conversiob of ³H-PGG₂ to ³H-PGs, nor on the breakdown of ³H-PGG₂ in the absence of brain tissue. We conclude that NE stimulates extravascular synthesis of PGD₂, PGE₂ and PGF_2α by stimulation of the prostaglandin synthetase complex, in addition to NE's stimulatory effect on the conversion of PGG₂ to PGF_2α, and that the lack of effect of NE on 6KF_1α synthesis reflects either a failure to achieve an adequate concentration at the vascular tissue, or an absence of the mechanism whereby NE stimulates PG synthetase.     

The blood-brain barrier in vitro: Ten years of research on microvessels isolated from the brain

The cerebral microvessels represent a distinctive compartment in the brain with unique physiological, biochemical and morphological properties. The barrier which separates the general circulation from the central nervous system is a complex mechanism that has a relative impermeability to a number of blood-borne substances, but—at the same time—operates with several specific carriers for the various compounds needed in the brain. Morphologically, the presence of tight interendothelial junctions, the paucity of pinocytotic vesicles in the endothelium and the absence of fenestrations are the hallmarks of this barrier.     

Transport of 2-deoxy-d-[3H]glucose in microvessels isolated from bovine cerebral cortex

Microvessels were isolated from a bovine cortex and the transport of glucose was investigated by using 2-deoxy-d-[³H]glucose (2-DG). The apparentK _m for 2-DG transport was 118 M and therefore indicates a significant high affinity for the substrate. The inhibition of 2-DG uptake byd-glucose showed an apparentK _i of 222 M. Other sugars, e.g., 3-methyl-d-glucose andd-fructose, also inhibited the 2-DG uptake by 60.6 and 36.0%, respectively. Phloretin (1×10^–3 M) inhibited the 2-DG transport more than phlorizin (83.7 vs. 53.8%). Ouabain (1 and 5×10^–4 M) did not inhibit the uptake of 2-DG but 2,4-dinitrophenol (1×10^–4 M) did (78.0%). The uptake of 2-DG could not be demonstrated in homogenized microvessels. Adenine nucleotides (conc. 2 mM) had various effects on the 2-DG uptake by microvessels. ATP inhibited the uptake by 20.7%, ADP was virtually without effect, and AMP stimulated the uptake of 2-DG by 8.5%. It was also found that the decrease of adenylate energy charge favors the uptake of 2-DG. All these findings suggest that in cerebral microvessels of a bovine cortex, 2-DG is apparently transported by a specific, carrier-mediated transport system.Dedicated to Prof. Dr. R. Sammet on the occasion of his 60th birthday.     

Chemical characteristics of chalones isolated from bovine spleen.

Isolation of spleen chalones from the postmicrosomal supernatant is described. Two glycoprotein fractions homogeneous on polyacrylamide-gel electrophoresis were obtained. In the biological test on mice, the preparation of 38 000 mol. wt. inhibited mitosis in spleen cells, and the low-molecular fraction (2100 mol. wt.) in thymus cells, showing respectively the properties of chalones B and T.     

Substance P isolated from bovine hypothalamus: amino acid composition

Using the method of Chang and Leeman for isolation the sialogogic undecapeptide from bovine hypothalamus partly purified Substance P was obtained. The final steps of purification were omitted to prevent losing of other peptides possessing biological activity of Substance P. The qualitative and quantitative content of amino acids in the hypothalamic extract was determined and fourteen amino acids were found. Four of them were not present in the sialogogic undecapeptide or neurotensin. It can be concluded that in the hypothalamic tissue apart from sialogogic undecapeptide and neurotensin, there are other peptides related to these two.     

Identification and quantification of blood–brain barrier transporters in isolated rat brain microvessels

The blood–brain barrier (BBB ) maintains brain homeostasis by tightly regulating the exchange of molecules with systemic circulation. It consists primarily of microvascular endothelial cells surrounded by astrocytic endfeet, pericytes, and microglia. Understanding the make‐up of transporters in rat BBB is essential to the translation of pharmacological and toxicological observations into humans. In this study, experimental workflows are presented in which the optimization of (a) isolation of rat brain microvessels (b) enrichment of endothelial cells, and (c) extraction and digestion of proteins were evaluated, followed by identification and quantification of BBB proteins. Optimization of microvessel isolation was indicated by 15‐fold enrichment of endothelial cell marker Glut1 mRNA , whereas markers for other cell types were not enriched. Filter‐aided sample preparation was shown to be superior to in‐solution sample preparation (10251 peptides vs. 7533 peptides). Label‐free proteomics was used to identify nearly 2000 proteins and quantify 1276 proteins in isolated microvessels. A combination of targeted and global proteomics was adopted to measure protein abundance of 6 ATP‐binding cassette and 27 solute carrier transporters. Data analysis using proprietary Progenesis and open access MaxQuant software showed overall agreement; however, Abcb9 and Slc22a8 were quantified only by MaxQuant, whereas Abcc9 and Abcd3 were quantified only by Progenesis. Agreement between targeted and untargeted quantification was demonstrated for Abcb1 (19.7 ± 1.4 vs. 17.8 ± 2.3) and Abcc4 (2.2 ± 0.7 vs. 2.1 ± 0.4), respectively. Rigorous quantification of BBB proteins, as reported in this study, should assist with translational modeling efforts involving brain disposition of xenobiotics.

     

Distribution of parathyroid hormone-sensitive adenylate cyclase in isolated rabbit renal cortex microvessels and glomeruli

The effect of the synthetic amino-terminal fragment of bovine parathyroid hormone, bPTH-(1-34), on the adenylate cyclase of microvessels and glomeruli isolated from rabbit kidney cortex was studied in the presence and absence of guanosine triphosphate (GTP). bPTH-(1-34) stimulated the vascular and glomerular adenylate cyclase in a dose-dependent manner with apparent ED50 values of 11.5 nM and 64 nM respectively, in the absence of GTP. 10(-4)M GTP greatly amplified the vascular response to bPTH-(1-34) while, in the glomeruli, both GTP and bPTH-(1-34) had only additive effects. In the presence of GTP, vascular and glomerular apparent ED50 were 190 nM and 64 nM respectively. [Nle8, Nle18, Tyr34] -bPTH-(3-34) amide, described as a PTH antagonist, inhibited the action of bPTH-(1-34) in the microvessels and to a lesser extent in the glomeruli. PTH is therefore a potent stimulator of adenylate cyclase in rabbit renal microvessels and glomeruli, and may play a role in the regulation of renal blood flow and glomerulo-tubular feedback control.     

Transport of sugars into microvessels isolated from rat brain: a model for the blood-brain barrier.

Abstract— Microvessels (primarily capillaries) were isolated from the brains of rats 25-35 days of age. This preparation was characterized by light, transmission, and scanning electron microscopy. Transmission electron microscopy revealed that the endothelial cell membranes were intact and were impermeable to horseradish peroxidase. However, scanning electron microscopy revealed that damage to the membrane occurred during isolation. The isolated microvessel preparations were metabolically competent as demonstrated by their ability to metabolize [¹⁴C]glucose. Aliquots of microvessel preparation were incubated with radioactive non-metabolizable analogs of D-glucose at various concentrations. The kinetics of accumulation of radioactivity in the capillaries were analyzed according to a model for carrier-mediated diffusion and affinity constants for 3-O-methyl- D-glucose and 2-deoxyglucose were calculated (about 18 mM at 20°C in each case). These affinity constants are somewhat greater than that expected from whole animal experiments reported by other laboratories. This discrepancy is probably accounted for by the presence of a passive diffusion component. However, despite this complication, the primary mechanism for entry of D-glucose analogues at physiological concentrations is compatible with carrier-mediated transport since: the uptake of sugar analogs was shown to be saturable, to exhibit competition for uptake between structurally similar molecules, and to be non-concentrative. In contrast, the uptake of glycerol, mannitol, and L-glucose by isolated microvessels obeyed the kinetics of simple passive diffusion and was not saturable. Our results are compatible with the concept that the capillary is the anatomic locus of the blood-brain barrier and that this structure contains the carrier-mediated transport system for monosaccharide penetration into brain.     

Transforming growth factor beta activates protein kinase C in microvessels isolated from immature rat brain

We investigated the activation of protein kinase C in microvessels isolated from rat brain. We found that unstimulated kinase activity in microvessels from immature animals is soluble while that from adults is particulate. The tumor promoter, phorbol 12-myristate 13-acetate, and the diacylglycerol analog, 1-oleoyl-2-acetyl-sn-glycerol, caused the redistribution of protein kinase C activity to the membrane fraction in microvessels from immature rats. Exposure to transforming growth factor beta resulted in similar redistribution of kinase activity. To our knowledge, this is the first report of an effect of transforming growth factor beta on protein kinase C. The kinase activity in microvessels from adult animals was unaffected by exposure to these agonists. We suggest that protein kinase C activation promotes differentiation of the brain microvasculature. Transforming growth factor beta may mediate this process.