LysoPC acyltransferase/PC transacylase activities in plant plasma membrane and plasma membrane-associated endoplasmic reticulum.

BACKGROUND: The phospholipids of the plant plasma membrane are synthesized in the endoplasmic reticulum (ER). The majority of these lipids reach the plasma membrane independently of the secretory vesicular pathway. Phospholipid delivery to the mitochondria and chloroplasts of plant cells also bypasses the secretory pathway and here it has been proposed that lysophospholipids are transported at contact sites between specific regions of the ER and the respective organelle, followed by lysophospholipid acylation in the target organelle. To test the hypothesis that a corresponding mechanism operates to transport phospholipids to the plasma membrane outside the secretory pathway, we investigated whether lysolipid acylation occurs also in the plant plasma membrane and whether this membrane, like the chloroplasts and mitochondria, is in close contact with the ER. RESULTS: The plant plasma membrane readily incorporated the acyl chain of acyl-CoA into phospholipids. Oleic acid was preferred over palmitic acid as substrate and acyl incorporation occurred predominantly into phosphatidylcholine (PC). Phospholipase A2 stimulated the reaction, as did exogenous lysoPC when administered in above critical micellar concentrations. AgNO3 was inhibitory. The lysophospholipid acylation reaction was higher in a membrane fraction that could be washed off the isolated plasma membranes after repeated freezing and thawing cycles in a medium with lowered pH. This fraction exhibited several ER-like characteristics. When plasma membranes isolated from transgenic Arabidopsis expressing green fluorescent protein in the ER lumen were observed by confocal microscopy, membranes of ER origin were associated with the isolated plasma membranes. CONCLUSION: We conclude that a lysoPC acylation activity is associated with plant plasma membranes and cannot exclude a PC transacylase activity. It is highly plausible that the enzyme(s) resides in a fraction of the ER, closely associated with the plasma membrane, or in both. We suggest that this fraction might be the equivalent of the mitochondria associated membrane of ER origin that delivers phospholipids to the mitochondria, and to the recently isolated ER-derived membrane fraction that is in close contact with chloroplasts. The in situ function of the lysoPC acylation/PC transacylase activity is unknown, but involvement in lipid delivery from the ER to the plasma membrane is suggested.

The involvement of cytosolic lipases in converting phosphatidyl choline to substrate for galactolipid synthesis in the chloroplast envelope.

Here we report that cytosolic phospholipases are involved in the utilization of phosphatidylcholine (PC) as substrate for chloroplast-localized synthesis of monogalactosyldiacylglycerol (MGDG). Isolated chloroplasts were pre-incubated with lysoPC and [14C]18:0-CoA to form [14C]PC. When soluble plant proteins (cytosol) and UDP-galactose were added, [14C] MGDG was formed. An inhibitor of phospholipase D markedly lowered the formation of [14C]MGDG, whereas thermolysin pretreatment of the chloroplasts was without effect. The cytosolic activity resided in the >100-kDa fraction. In a second approach, [14C]PC-containing lipid mixtures were incubated with cytosol. Degradation of [14C]PC to [14C]diacylglycerol was highest when the lipid composition of the mixture mimicked that of the outer chloroplast envelope. We also investigated whether PC of extraplastidic origin could function as substrate for MGDG synthesis. Isolated chloroplasts were incubated with enriched endoplasmic reticulum containing radiolabelled acyl lipids. In the presence of cytosol and UDP-galactose, there was a time-dependent transfer of [14C]PC from this fraction to chloroplasts, where [14C]MGDG was formed. We conclude that chloroplasts recruit cytosolic phospholipase D and phosphatidic acid phosphatase to convert PC to diacylglycerol. Apparently, these lipases do not interact with chloroplast surface proteins, but rather with outer membrane lipids, either for association to the envelope or for substrate presentation.

Detection and characterization of GTP-binding proteins in the chloroplast envelope of spinach (Spinacia oleracea).

Proteins binding guanosine triphosphate (GTP) have emerged as important regulators in several cellular processes in plants. To investigate any role of such proteins in chloroplast functions, we subjected envelope, stroma and thylakoid fractions isolated from spinach chloroplasts to two different GTP-binding assays. With both methods, we detected GTP-specific binding only in the envelope fraction. Two chloroplast envelope proteins with the apparent molecular weights of 30.5 and 33.5 kDa, respectively, bound [alpha-32P]GTP after SDS-PAGE followed by electroblotting onto a PVDF-membrane and renaturation. Both proteins were intrinsic proteins located in the outer chloroplast envelope. Also, when the fractions were incubated with [alpha-32P]GTP, followed by periodate oxidation and borohydride reduction to cross-link GTP to proteins, two proteins in the envelope fraction, of apparent molecular weights of 28 and 39 kDa, appeared to specifically bind GTP. When agents that stimulate heterotrimeric G-proteins, cholera toxin or the mastoparan analogue mas7, were added to isolated chloroplast envelope, the binding of radiolabelled GTP to the 39 kDa protein, a protein of the inner chloroplast envelope, was stimulated, whereas GTP-binding of the 28 kDa protein, a protein of the outer envelope, was unchanged. Mas7 also stimulated synthesis of monogalactosyl diacylglycerol in isolated chloroplast envelope. The occurrence and regulation of GTP-binding proteins in the chloroplast envelope suggests that GTP-binding proteins could be involved in communication with the extraplastidic compartment during chloroplast biogenesis and development.