Analysis of Biogenic Amines in Bovine Retina by Gas Chromatography-Negative Ion Chemical Ionisation Mass Spectrometry

Biogenic amines in bovine retina have been identified and quantified by an extraction-derivatisation procedure involving their reaction with 3,5-di(trifluoromethyl)benzoyl chloride (DTFMBCl) in the aqueous phase followed by extraction into an organic solvent, hydrolysis of phenolic esters, and conversion of free hydroxyl groups to trimethylsilyl ethers. Subsequent analysis of these DTFMB-trimethylsilyl derivatives by gas chromatography-negative ion chemical ionisation mass spectrometry revealed that the molecular ion carried most (greater than 60%) of the ion current, which made the method highly specific and gave a potential limit of detection below the picogram level. This method establishes unequivocally that the principal amines in bovine retina are p-tyramine, dopamine, and 5-hydroxytryptamine.     

Der Brennstoff des Lebens

Ohne ZusammenfassungAberdeen (Schottland), 1929.Ins Deutsche übertragen und ergänzt von Dr.A. Gottschalk-Stettin.     

Loading Drosophila nerve terminals with calcium indicators

Calcium plays many roles in the nervous system but none more impressive than as the trigger for neurotransmitter release, and none more profound than as the messenger essential for the synaptic plasticity that supports learning and memory. To further elucidate the molecular underpinnings of Ca(2+)-dependent synaptic mechanisms, a model system is required that is both genetically malleable and physiologically accessible. Drosophila melanogaster provides such a model. In this system, genetically-encoded fluorescent indicators are available to detect Ca(2+) changes in nerve terminals. However, these indicators have limited sensitivity to Ca(2+) and often show a non-linear response. Synthetic fluorescent indicators are better suited for measuring the rapid Ca(2+) changes associated with nerve activity. Here we demonstrate a technique for loading dextran-conjugated synthetic Ca(2+) indicators into live nerve terminals in Drosophila larvae. Particular emphasis is placed on those aspects of the protocol most critical to the technique's success, such as how to avoid static electricity discharges along the isolated nerves, maintaining the health of the preparation during extended loading periods, and ensuring axon survival by providing Ca(2+) to promote sealing of severed axon endings. Low affinity dextran-conjugated Ca(2+)-indicators, such as fluo-4 and rhod, are available which show a high signal-to-noise ratio while minimally disrupting presynaptic Ca(2+) dynamics. Dextran-conjugation helps prevent Ca(2+) indicators being sequestered into organelles such as mitochondria. The loading technique can be applied equally to larvae, embryos and adults.