Subunit stoichiometry of tobacco ribulose 1.5-bisphosphate carboxylase

The delta- and epsilon-subunits of bovine F1-ATPase interact to form a heterodimeric subcomplex

The delta-subunit of bovine F1-ATPase was expressed from a bacterial vector at fairly high level in Escherichia coli, but the yield of bovine epsilon-subunit was rather low under similar conditions. However, co-expression of the proteins from a dicistronic operon delta-epsilon in the same expression vector, produced both of them in good yield in a soluble form in the bacterial cytoplasm, and by chromatography it was found that the delta- and epsilon-subunits were associated in a stable complex. The amino groups in the complex were labelled exhaustively by chemical reaction under denaturing conditions with ethyl-[1-14C]acetimidate. The alpha-amino groups of the proteins were unmodified, but complete reaction of all epsilon-amino groups in both proteins was demonstrated by determination of the molecular masses of the modified proteins by electrospray MS. The modified subunits were separated by denaturing gel electrophoresis, and from measurements of the ratio of incorporated radioactivities and the lysine contents of the proteins, it was calculated that the subcomplex contains equimolar amounts of the two proteins. As the apparent molecular mass of the complex determined by gel filtration was 29 kDa, it appears that the complex contains one copy of each protein. It is likely that the delta- and epsilon subunits are associated in a similar manner in the bovine F1-ATPase complex, and that, like a bacterial homologue of the delta-subunit, they interact with the gamma- and beta-subunits.

Calculation of subunit stoichiometry of large, multisubunit proteins from amino acid compositions

The subunit stoichiometry of a large, multisubunit protein can be determined from the molar amino acid compositions (i amino acids) of the protein and its subunits. The number of copies of the subunits (1, 2, ... j) is calculated by solving all possible combinations of simultaneous equations in j unknowns (i!/j!(i - j)!). Calculations carried out using the published amino acid compositions determined by analysis and the compositions calculated from the sequences for two proteins of known stoichiometry provided the following results: Escherichia coli aspartate transcarbamoylase (R6C6, Mr = 307.5 kDa), R = 5.6 to 6.6 and C = 5.8 to 6.3, and spinach ribulose-bisphosphate carboxylase (L8S8, Mr = 535 kDa), L = 7.3 to 9.1 and S = 5.6 to 10.6. Calculations were also carried out with the amino acid compositions of two much larger proteins, the E. coli pyruvate dehydrogenase complex, Mr = 5280 kDa, subunits E1 (99.5 kDa), E2 (66 kDa), and E3 (50.6 kDa), and the extracellular hemoglobin of Lumbricus terrestris, Mr = 3760 kDa, subunits M (17 kDa), D1 (31 kDa), D2 (37 kDa), and T (51 kDa); the results for PDHase were E1 = 20 to 24, E2 = 18 to 31, E3 = 21 to 33 and those for Lumbricus hemoglobin were M = 34 to 46, D1 = 13 to 19, D2 = 13 to 18, and T = 34 to 36. Although the sample standard deviations of the mean values are generally high, the proposed method works surprisingly well for the two smaller proteins and provides physically reasonable results for the two larger proteins.

Histones H1 and H5: one or two molecules per nucleosome?

We have determined histone stoichiometries in nuclei from several sources by a direct chemical method, with the particular aim of quantitating histone H1 and, in chicken erythrocytes, H5, and of distinguishing between one and two molecules per nucleosome. The four histones H3, H4, H2A and H2B are found in equimolar amounts, as expected for the core histone octamer. The molar ratio of H1 in lymphocyte and glial nuclei is 1.0 per octamer, and in liver nuclei from three species 0.8 per octamer. These results suggest that each nucleosome has one H1 molecule; nucleosomes could acquire two molecules of H1 only at the expense of others containing none. The stoichiometry of H5 in chicken erythrocyte nuclei is similar to that of H1 in other nuclei, being about 0.9 molecules per nucleosome; the H1 also present in these nuclei amounts to 0.4 molecules per nucleosome.