Purification of brain tubulin-tyrosine ligase by biochemical and immunological methods

Tubulin-tyrosine ligase (TTL), the enzyme responsible for the reversible addition of a tyrosine residue at the carboxyl end of alpha-tubulin, has been purified from porcine brain using a purification scheme based on standard biochemical procedures. The enzyme preparation was nearly homogeneous (purity greater than 95%), was free of tubulin, and could be stored in the presence of glycerol for several months without loss in activity. To develop a more convenient purification of TTL, we have isolated mouse hybridoma cells secreting antibodies to TTL. These monoclonal antibodies recognize TTL not only in brain tissue but also in the liver of various mammals. Monoclonal antibodies isolated from ascites fluid allowed a rapid purification of TTL from a crude brain extract. TTL stayed bound to the immunoaffinity column in 1.5 M NaCl and was eluted with 3 M MgCl2. Highly active TTL was recovered nearly quantitatively at greater than 95% purity and could be stabilized in the presence of glycerol. Glycerol gradient centrifugation, SDS gel electrophoresis and immunoblots identified TTL as a monomeric protein with an apparent polypeptide molecular weight of about 40,000. A one to one complex of TTL with alpha beta-tubulin was observed by gradient centrifugation.     

[14C]acetylcholine synthesis and [14C]carbon dioxide production from [U-14C]glucose by tissue prisms from human neocortex.

1. [14C]Acetylcholine synthesis and 14CO2 production from [U-14C]glucose has been measured in tissue prism preparations from human neocortex. 2. Electron micrographs of prisms from human and rat neocortex show that both contain intact synaptic endings with evenly-distributed vesicles and normal-appearing mitochondria, but only poorly preserved cell body structure. 3. Synthesis of [14C]acetylcholine in prisms from rat neocortex is similar to estimates for turnover in vivo. Synthesis in prisms from human neocortex is 18% of that in rat tissue and 64% of that in tissue from baboon neocortex for incubations performed in 31 mM-K+. 4. Investigations of prisms prepared from rat brains stored at 37 degrees C after death revealed that synthesis of [14C]acetylcholine in the presence of 31 mM-K+ was greatly decreased within 30 min of post-mortem incubation, whereas synthesis at 5 mM-K+ and production of 14CO2 at both K+ concentrations were only significantly affected after longer periods. Changes were similar in neocortex and striatum. Thus human autopsy material is unlikely to be suitable for use with this system. 5. Investigations using animal models suggest that [14C]acetylcholine synthesis and 14CO2 production are not affected by surgical or anaesthetic procedures. 6. Neither [14C]acetylcholine synthesis nor 14CO2 production in human prisms was significantly changed with age between 15 and 68 years. 7. Samples from patients with the dementing condition Alzheimer's disease showed a significant decrease in [14C]acetylcholine synthesis to 47% of normal samples and a significant increase of 39% in production of 14CO2.     

Biosynthesis of [14C]zearalenone from [1-14C]acetate by Fusarium roseum 'Gibbosum'.

Addition of [1-14C]acetate or [1,2-14C]acetate to actively growing cultures of Fusarium roseum 'Gibbosum' on rice yielded zearalenone with a specific activity ranging between 1.63 and 46.5 microCi/mmol.     

Convenient preparative synthesis of [14C]trehalose from [14C]glucose by intact Escherichia coli cells.

At high osmolarity, Escherichia coli synthesizes trehalose intracellularly, irrespective of the nature of the carbon source. Synthesis proceeds via the transfer of UDP-glucose to glucose 6-phosphate, yielding trehalose 6-phosphate, followed by its dephosphorylation to trehalose (H.M. Giaeyer, B.O. Styrvold, I. Kaasen, and A.R. Strøm, J. Bacteriol. 170:2841-2849, 1988). This reaction was exploited to preparatively synthesize [14C]trehalose from exogenous [14C]glucose by using intact bacteria of a mutant (DF214) that could not metabolize glucose. The total yield of radiochemically pure trehalose from glucose was routinely more than 50%.     

Bioconversion of alpha-[14C]zearalenol and beta-[14C]zearalenol into [14C]zearalenone by Fusarium roseum 'Gibbosum'.

Cultures of Fusarium roseium 'Gibbosum' on rice were treated with [14C]zearalenone, alpha[14C]zearalenol, or beta-[14C]zearalenol to determine whether a precursor-product relationship exists among these closely related fungal metabolites. Culture extracts were purified by silica gel column chromatography and fractionated by high-pressure liquid chromatography, and the level of radioactivity was determined. Within 7 days, the beta-[14C]zearalenol was converted to zearalenone, and no residual beta-[14C]zearalenol was detectable. Most of the alpha-[14C]zearalenol added was also converted into zearalenone with 14 days. In cultures treated with [14C]zearalenone, no radioactivity was noted in any other components.     

Formation of ketone bodies from [14C]palmitate and [14C]glycerol by tissues from ketotic sheep

Labelled ketone bodies were produced readily from [U-(14)C]palmitate, [2-(14)C]palmitate and [1-(14)C]glycerol by sheep rumen-epithelial and liver tissues in vitro. On a tissue-nitrogen basis, both tissues had similar capacities for ketogenesis. Palmitate was a ketogenic substrate in both rumen-epithelial tissue and liver, and more of its (14)C appeared in ketone bodies than in the (14)CO(2) liberated. Glycerol was actively metabolized to ketone bodies, but more readily underwent complete oxidation to carbon dioxide; this complete oxidation was most pronounced in rumen-epithelial tissue from ketotic ewes. These experiments with labelled compounds confirm earlier observations that rumen-epithelial tissue, like liver, actively forms ketone bodies from long-chain fatty acids and show further that normal rumen-epithelial tissue can convert palmitate into ketone bodies as readily as into carbon dioxide. Free glycerol, which is metabolized only by liver tissue in non-ruminants, is also metabolized by rumen epithelium. The rumen epithelium thus has unique metabolic capacity among extrahepatic tissues.     

Convenient preparative synthesis of [14C]trehalose from [14C]glucose by intact Escherichia coli cells

At high osmolarity, Escherichia coli synthesizes trehalose intracellularly, irrespective of the nature of the carbon source. Synthesis proceeds via the transfer of UDP-glucose to glucose 6-phosphate, yielding trehalose 6-phosphate, followed by its dephosphorylation to trehalose (H.M. Giaeyer, B.O. Styrvold, I. Kaasen, and A.R. Str?m, J. Bacteriol. 170:2841-2849, 1988). This reaction was exploited to preparatively synthesize [14C]trehalose from exogenous [14C]glucose by using intact bacteria of a mutant (DF214) that could not metabolize glucose. The total yield of radiochemically pure trehalose from glucose was routinely more than 50%.     

Bioconversion of alpha-[14C]zearalenol and beta-[14C]zearalenol into [14C]zearalenone by Fusarium roseum 'Gibbosum'

Cultures of Fusarium roseium 'Gibbosum' on rice were treated with [14C]zearalenone, alpha[14C]zearalenol, or beta-[14C]zearalenol to determine whether a precursor-product relationship exists among these closely related fungal metabolites. Culture extracts were purified by silica gel column chromatography and fractionated by high-pressure liquid chromatography, and the level of radioactivity was determined. Within 7 days, the beta-[14C]zearalenol was converted to zearalenone, and no residual beta-[14C]zearalenol was detectable. Most of the alpha-[14C]zearalenol added was also converted into zearalenone with 14 days. In cultures treated with [14C]zearalenone, no radioactivity was noted in any other components.     

A lipid-linked oligosaccharide intermediate in glycoprotein synthesis. Characterization of [Man-14C]glycoproteins labeled from [Man-14C]oligosaccharide-lipid and GDP-[14C]Man.

Endogenous proteins of cell-free preparations of hen oviduct labeled from GDP-[14C]Man or from [Man-14C]oligosaccharide-lipid have been compared by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Under the conditions tested, a polypeptide chain of molecular weight about 25,000 was the principle acceptor for the oligosaccharide moiety of exogenous [Man-14C]oligosaccharide-lipid. The product labeled by [Man-14C]oligosaccharide-lipid appeared identical with one of three glycoproteins formed when GDP-[14C]Man was incubated with a crude membrane fraction. These three proteins (apparent molecular weight of 75,000, 55,000, and 25,000) accounted for nearly two-thirds of the [14C]mannose-labeled glycoprotein products using GDP-[14C]Man and either the crude membrane fraction or a total oviduct homogenate. Thus, all of the mannose acceptor proteins present in the oviduct homogenate appear to be membrane-bound. Analyses of the [Man-14C]glycoproteins labeled from GDP-[14C]Man in membrane fractions from hen kidney, liver, brain, and oviduct indicated that a labeled polypeptide of apparent molecular weight 25,000 was the only major protein product common to the four preparations.     

Relationship between synaptosomal uptake and release of [14C]gaba, [14C]diaminobutyric acid and [14C]beta-alanine.

[¹⁴C]GABA is taken up by rat brain synaptosomes via a high affinity, Na⁺-dependent process. Subsequent addition of depolarizing levels of potassium (56.2 MM) or veratridine (100 μM) stimulates the release of synaptosomal [¹⁴C]GABA by a process which is sensitive to the external concentration of divalent cations such as Ca²⁺, Mg²⁺, and Mn²⁺. However, the relatively smaller amount of [¹⁴C]GABA taken up by synaptosomes in the absence of Na⁺ is not released from synaptosomes by Ca²⁺ -dependent, K ⁺-stimulation. [¹⁴C]DABA, a competitive inhibitor of synaptosomal uptake of GABA (Iversen & Johnson , 1971) is also taken up by synaptosomal fractions via a Na ⁺ -dependent process; and is subsequently released by Ca²⁺ -dependent, K⁺-stimulation. On the other hand, [¹⁴C]β-alanine, a purported blocker of glial uptake systems for GABA (Schon & Kelly , 1974) is a poor competitor of GABA uptake into synaptosomes. Comparatively small amounts of [¹⁴C] β-alanine are taken up by synaptosomes and no significant amount is released by Ca²⁺ -dependent, K⁺-stimulation. These data suggest that entry of [¹⁴C]GABA into a releasable pool requires external Na⁺ ions and maximal evoked release of [¹⁴C]GABA from the synaptosomal pool requires external Ca²⁺ ions. The GABA analogue, DABA, is apparently successful in entering the same or similar synaptosomal pool. The GABA analogue, β-alanine, is not. None of the compounds or conditions studied were found to simultaneously affect both uptake and release processes. Compounds which stimulated release (veratridine) or inhibited release (magnesium) were found to have minimal effect on synaptosomal uptake. Likewise compounds (DABA) or conditions (Na⁺-free medium) which inhibited uptake, had little effect on release.     

Thermophilic Anaerobic Biodegradation of [14C]Lignin, [14C]Cellulose, and [14C]Lignocellulose Preparations

Thermophilic (55°C) anaerobic enrichment cultures were incubated with [¹⁴C-lignin]lignocellulose, [¹⁴C-polysaccharide]lignocellulose, and kraft [¹⁴C]lignin prepared from slash pine, Pinus elliottii, and ¹⁴C-labeled preparations of synthetic lignin and purified cellulose. Significant but low percentages (2 to 4%) of synthetic and natural pine lignin were recovered as labeled methane and carbon dioxide during 60-day incubations, whereas much greater percentages (13 to 23%) of kraft lignin were recovered as gaseous end products. Percentages of label recovered from lignin-labeled substrates as dissolved degradation products were approximately equal to percentages recovered as gaseous end products. High-pressure liquid chromatographic analyses of CuO oxidation products of sound and degraded pine lignin indicated that no substantial chemical modifications of the remaining lignin polymer, such as demethoxylation and dearomatization, occurred during biodegradation. The polysaccharide components of pine lignocellulose and purified cellulose were relatively rapidly mineralized to methane and carbon dioxide; 31 to 37% of the pine polysaccharides and 56 to 63% of the purified cellulose were recovered as labeled gaseous end products. An additional 10 to 20% of the polysaccharide substrates was recovered as dissolved degradation products. Overall, these results indicate that elevated temperatures can greatly enhance rates of anaerobic degradation of lignin and lignified substrates to methane and low-molecular-weight aromatic compounds.     

Release of [3H]serotonin from brain slices

1. Labelled serotonin ([³H]5-HT) accumulated by slices of rat brain either in vivo or in vitro is released by depolarizing procedures such as electrical stimulation or high external potassium concentrations. Electrical stimulation predominantly affects the liberation of the unchanged amine, rather than of its principal metabolite, 5-HIAA. 2. Release of [³H]5-HT does not appear to be calcium-dependent. 3. Amount of release parallels the density of serotonin-containing nerve terminals in each of several cerebral regions tested. Release from several extracerebral tissues was similar to that obtained from cerebral tissues having relatively little endogenous 5-HT. 4. Electrically induced release of [³H]5-HT is markedly inhibited by desipramine, chlorpromazine, LSD, lithium and ouabain.     

Intramolecular labelling of sucrose made by leaves from [14C)carbon dioxide or [3-14C]serine.

Pea leaves were illuminated in air containing 150 or 1000p.p.m. of 14CO2 for various times. Alternatively, segments of wheat leaves were supplied with [3-14C]serine for 40 min in the light in air with 145, 326 or 944p.p.m. of 12CO2. Sucrose was extracted from the leaf material, hydrolysed with invertase, and 14C in the pairs of carbon atoms C-3+C-4, C-2+C-5 and C-1+C-6 in the glucose moiety was measured. The results obtained after metabolism of 14CO2 were consistent with the operation of the photosynthetic carbon-reduction cycle; the effects of CO2 concentration on distribution of 14C in the carbon chain of glucose after metabolism of [3-14C]serine is more easily explained by metabolism through the glycollate pathway than by the carbon-reduction cycle.