Symmetry-resolved C and O K-shell photoabsorption spectra of free CO molecules

cDNA encoding for carnitine acetyltransferase (CAT) of yeast S. cerevisiae was isolated by screening a yeast cDNA lambda gt11 library with antibody. The whole coding sequence was obtained from the cDNA and from a YEP 13 DNA clone identified using the cDNA as probe. The coding sequence consists of 670 residues, which amounts to a molecular mass of 77,300 kDa. This cDNA was used successfully to disrupt the gene for the mitochondrial isoenzyme of CAT, which was shown by measuring the enzyme activity and by immunoblot. The acetylcarnitine content of these cells decreased significantly. A search in the PIR protein data base revealed that besides the known carnitine acyltransferases, choline acyltransferases are highly homologous to yeast CAT. The mitochondrial CAT-deficient (CAT-) cells were able to grow on different fermentable and nonfermentable carbon sources, even on acetate at the same rate as the parental strain. In contrast to these, 13C NMR studies revealed significant differences between parental and CAT- cells. In CAT-cells [3-13C]pyruvate was converted mainly to lactate and acetate, whereas in the parental cells alanine and tricarboxylic acid cycle intermediates were found as the main products of pyruvate metabolism beside acetate. These results suggest diminished flux through the pyruvate dehydrogenase complex in the absence of mitochondrial CAT in yeast cells.     

Multielectron excitations in the L-subshell photoabsorption of xenon

We have previously shown that the gas-vesicle protein GvpC is present on the outer surface of the gas vesicle, can be reversibly removed and rebound to the surface, and increases the critical collapse pressure of the gas vesicle. The GvpC molecule, which contains five partially conserved repeats of 33 amino acids (33-RR) sandwiched between 18 N-terminal and 10 C-terminal amino acids, is present in a ratio of 1:25 with the GvpA molecule, which forms the ribs of the gas vesicle. By using recombinant techniques we have now made modified versions of GvpC that contain only the first two, three or four of the 33-amino-acid repeats. All of these proteins bind to and strengthen gas vesicles that have been stripped of their native GvpC. Recombinant proteins containing three or four repeats bind in amounts that give the same ratio of 33-RR:GvpA (i.e. 1:5) as the native protein, and they restore much of the strength of the gas vesicle; the protein containing only two repeats binds at a lower ratio (1:7.7), however, and restores less of the strength. Ancestral proteins with only two, three or four of the 33-amino-acid repeats would have been functional in strengthening the gas vesicle but the progressive increase in number of repeats would have provided strength with increased efficiency.