Thyroid hormones selectively modulate human alcohol dehydrogenase isozyme catalyzed ethanol oxidation

Thyroid hormones are potent, instantaneous, and reversible inhibitors of ethanol oxidation catalyzed by isozymes of class I and II human alcohol dehydrogenase (ADH). None of the thyroid hormones inhibits class III ADH. At pH 7.40 the apparent Ki values vary between 55 and 110 microM for triiodothyronine, 35 and greater than 200 microM for thyroxine, and 10 and 23 microM for triiodothyroacetic acid. The inhibition is of a mixed type toward both NAD+ and ethanol. The binding of the thyroid hormone triiodothyronine to beta 1 gamma 1 ADH is mutually exclusive with 1,10-phenanthroline, 4-methylpyrazole, and testosterone, identifying a binding site(s) for the thyroid hormones, which overlap(s) both the 1,10-phenanthroline site near the active site zinc atom and the testosterone binding site, the latter being a regulatory site on the gamma-subunit-containing isozymes and distinct from their catalytic site. The inhibition by thyroid hormones may have implications for regulation of ADH catalysis of ethanol and alcohols in the intermediary metabolism of dopamine, norepinephrine, and serotonin and in steroid metabolism. In concert with other hormonal regulators, e.g., testosterone, the rate of ADH catalysis is capable of being fine tuned in accord with both substrate and modulator concentrations.     

Constraints on amino acid substitutions in the N-terminal helix of cytochrome c explored by random mutagenesis.

The interaction of the N- and C-terminal helices is a hallmark of the cytochrome c family. Oligodeoxyribonucleotide-directed random mutagenesis within the gene encoding the C102T protein variant of Saccharomyces cerevisiae iso-1-cytochrome c was used to generate a library of mutations at the evolutionary invariant residues Gly-6 and Phe-10 in the N-terminal helix. Transformation of this library (contained on a low-copy-number yeast shuttle phagemid) into a yeast strain lacking a functional cytochrome c, followed by selection for cytochrome c function, reveals that 4-10% of the 400 possible amino acid substitutions are compatible with function. DNA sequence analysis of phagemids isolated from transformants exhibiting the functional phenotype elucidates the requirements for a stable helical interface. Basic residues are not tolerated at position 6 or 10. There is a broad volume constraint for amino acids at position 6. The amino acid substitutions observed to be compatible with function at Phe-10 show that the hydrophobic effect alone is sufficient to promote helical association. There are severe constraints that limit the combinations consistent with function, but the number of functionally consistent combinations observed exemplifies the plasticity of proteins.     

Visualizing the Live Drosophila Glial-neuromuscular Junction with Fluorescent Dyes

Our project identified GFP labeled glial structures at the developing larval fly neuromuscular synapse. To look at development of live glial-nerve-muscle synapses, we developed a larval tissue preparation that had features of live intact larvae, but also had good optical properties. This new preparation also allowed for access of perfusates to the synapse. We used fly larvae, immersed them in artificial hemolymph, and relaxed their normal rhythmic body contractions by chilling them. Next we dissected off the posterior segments of each animal and with a blunt insect pin pushed the mouth parts backward through the body cavity. This everted the larval body wall, like turning a sock inside-out. We completed the dissection with ultra-fine dissection scissors and thus exposed the visceral side of the body wall muscles. The glial structures at the NMJ expressed membrane targeted GFP under the control of glial specific promoters. The post-synaptic membrane, the SSR (Subsynaptic Reticula) in muscle expressed synaptically targeted dsRed. We needed to acutely label the motor neuron terminals, the third part of the synapse. To do this we applied primary antibodies to HRP, conjugated to a far-red emitting flurophore. To test for dye diffusion properties into the perisynaptic space between the motor neuron terminals and the SSR, we applied a solution of large Dextran molecules conjugated to far-red emitting flurophore and collected images.