[Electrophoretic analysis of the membrane proteins of spinach chloroplasts]

Additives for immobilized pH gradient two-dimensional separation of particulate material: comparison between commercial and new synthetic detergents

We describe the synthesis of two detergents, L and A15, whose performances as solubilizing agents and as additives in the first-dimension step of a two-dimensional separation are compared with those of some commercial compounds, i.e., Nonidet P-40, 3-[(3-cholamidopropyl)dimethylammonio]propanesulfonate(Chaps), and sulfobetaine, on three membrane protein preparations: rat RBC ghosts, beef kidney microvilli, and spinach thylakoids. L is 3-]3-dodecylamidoprophylcbdimethylammonio propane-1-sulfonate; owing to the substitution of a dodecylamido for the dodecyl residue of SB 3-12, the concentration of urea compatible with 2% detergent increases from 4.5 M for the parent molecule up to 7 M. With all three biological samples on which the panel of different detergents has been tested in parallel, L + urea scores as the most effective solubilization medium. On red blood cells a notable qualitative difference is observed with the selective extraction by L as well as by N-dodecyl-N,N-dimethylammonio-3-propanesulfonate of a major protein (pI = ca. 5.5, Mr = ca. 100,000). A15 is derived from a tertiary amine, with one alkylic substituent (either C11 or C13) and two poly(ethylene oxide) tails (totaling 15 ethoxy residues), which is reacted with propane sultone. Approximately 30% of the product corresponds to the N-adduct and is a truly zwitterionic detergent, while 60% is an O-derivative and still contains a titratable amino group (with a pK of 7.2). A15 can thus be used for isoelectric focusing on immobilized pH gradients, as in this work, but would not be compatible with carrier ampholyte isoelectric focusing.(ABSTRACT TRUNCATED AT 250 WORDS)

Origin and developmental changes of envelope proteins and translocator activities from plastids of Secale cereale L

To determine the sites of synthesis of chloroplast-envelope proteins, we have analysed several enzyme and translocator functions ascribed to the envelope membranes, and investigated the envelope polypeptide composition of plastids isolated from 70S ribosome-deficient leaves of rye (Secale cereale L.) generated by growing the plants at a temperature of 32°C. Since the ribosomedeficient plastids are also achlorophyllous in light-grown leaves, not only were chloroplasts from mature, green leaves used for comparison, but also those from yellowing, aged leaves as well as etioplasts from dark-grown leaves raised at a temperature of 22° C. A majority of the plastidenvelope polypeptides appeared to be of cytoplasmic origin. The envelopes of ribosome-deficient plastids possessed ATPase (EC 3.6.1.3) activity; this was not, however, dependent on divalent cations, in contrast to the Mn(2+)- or Mg(2+)-dependent ATPase which is associated with chloroplast envelopes. Adenylate kinase (EC 2.7.4.3) was present in the stromal fraction of ribosome-deficient plastids and the stromal form of this enzyme is, therefore, of cytoplasmic origin. In contrast to previous findings, adenylate kinase was not, however, specifically associated with the chloroplast-envelope membranes, either in rye or in spinach. Measurements of the uptake of L-[(14)C]-malate into ribosome-deficient plastids indicated the presence and cytoplasmic origin of the dicarboxylate translocator. Malate uptake into rye etioplasts was, however, low. The phosphate translocator was assayed by the uptake of 3-phospho-[(14)C]glycerate. While rapid 3-phosphoglycerate uptake was observed for rye chloroplasts and etioplasts, it was hardly detectable for ribosome-deficient, plastids and rather low for chloroplasts from aged leaves. A polypeptide of M r approx. 30000 ascribed to the phosphate translocator was greatly reduced in the envelope patterns of ribosome-deficient plastids and of chloroplasts from aged leaves.

Galactolipid formation in chloroplast envelopes. II. Isolation-induced changes in galactolipid composition

Spinach envelopes were isolated at pH 8.5, which is inhibitory to interlipid galactosyl transfer, and at pH 7.2, which is close to values used in most recent work on chloroplast envelopes. Peptide patterns were identical, but galactolipid compositions differed markedly. These changes are such as could be explained by interlipid galactosyl transfer during isolation at pH 7.2, i.e. a strong decrease in monogalactolipid and a corresponding increase in tri- and tetragalactolipids and diacylglycerol. Digalactolipid was little affected. It was further observed that the interlipid galactosyl transfer was restricted to lipids rich in hexadecatrienoic acid. Arguments are presented that the lipid composition of envelopes in vivo is better represented by the results obtained at high pH. The results will be discussed in relation to previous data on galactolipid composition and biosynthesis in envelopes.