Transfer properties of the bovine brain phospholipid transfer protein. Specificity towards phosphatidylcholine analogs and the inhibitory effect of sphingomyelin

Both isoforms of mammalian phosphatidylinositol transfer protein are capable of binding and transporting sphingomyelin

The structurally related mammalian alpha and beta isoforms of phosphatidylinositol (PtdIns) transfer protein (PITP) bind reversibly a single phospholipid molecule, preferably PtdIns or phosphatidylcholine (PtdCho), and transport that lipid between membrane surfaces. PITPbeta, but not PITPalpha, is reported extensively in the scientific literature to exhibit the additional capacity to bind and transport sphingomyelin (CerPCho). We undertook a detailed investigation of the lipid binding and transfer specificity of the soluble mammalian PITP isoforms. We employed a variety of donor and acceptor membrane lipid compositions to determine the sensitivity of recombinant rat PITPalpha and PITPbeta isoforms toward PtdIns, PtdCho, CerPCho, and phosphatidate (PtdOH). Results indicated often striking differences in protein-phospholipid and protein-membrane interactions. We demonstrated unequivocally that both isoforms were capable of binding and transferring CerPCho; we confirmed that the beta isoform was the more active. The order of transfer specific activity was similar for both isoforms: PtdIns>PtdCho>CerPCho>>PtdOH. Independently, we verified the binding of CerPCho to both isoforms by showing an increase in holoprotein isoelectric point following the exchange of protein-bound phosphatidylglycerol for membrane-associated CerPCho. We conclude that PITPalpha and PITPbeta are able to bind and transport glycero- and sphingophospholipids.

Binding of phospholipids to the phosphatidylinositol transfer protein from bovine brain as studied by steady-state and time-resolved fluorescence spectroscopy

The phosphatidylinositol transfer protein isolated from brain, liver, heart and platelets was found to be present in two subforms which could be distinguished on the basis of the isoelectric points. In this study we have demonstrated that the two subforms isolated from bovine brain are due to the presence of either phosphatidylinositol or phosphatidylcholine in the lipid binding site of the protein. The transfer protein accommodates one phosphatidylinositol molecule in the binding site. The binding site for the sn-2 fatty acyl chain was investigated by incorporating in the transfer protein either phosphatidylinositol or phosphatidylcholine carrying a parinaroyl-chain attached at the sn-2 position. Time-resolved fluorescence spectroscopy revealed that the sn-2 fatty acyl chains for both phospholipids in the lipid-protein complex were completely immobilized (i.e., rotational correlation times of 17.4 ns for phosphatidylcholine and 16.3 ns for phosphatidylinositol). The similarity in correlation times suggests that the sn-2 fatty acyl chains of both phospholipids are accommodated in the same hydrophobic binding site of the protein.

Phospholipid transfer proteins: mechanism of action

Phospholipid transfer proteins are generally localized in the cytosolic fraction of cells and are capable of catalyzing the flux of phospholipid molecules among membranes. Artificial membranes also participate in protein-catalyzed phospholipid movements. In this review the major phospholipid transfer proteins are discussed with respect to their phospholipid substrate specificity and the contributions of membrane physical properties to this process. The phenomenon of net transfer of phospholipids is described. The use of various kinetic approaches to the study of these catalysts is reviewed. A detailed consideration of the distinct phospholipid binding and membrane interaction domains of one phospholipid transfer protein is presented. Finally, some recent applications of phospholipid transfer proteins to the examination of membrane structure and function and further directions for the continued research activity with this class of proteins are summarized.

Phosphatidylinositol transfer proteins: structure, catalytic activity, and physiological function

Among the diverse lipid transfer proteins which are found in tissues and biological fluids are those which exhibit a specificity toward phosphatidylinositol and phosphatidylcholine, with a preference for the former. Phosphatidylinositol transfer proteins (PI-TPs) have been purified from several eukaryotic sources; those present in bovine brain and heart have been extensively studied. This review examines the tissue distribution of PI-TPs and the means by which transfer activity is measured using natural and artificial membranes. The interaction of these proteins with lipid monolayers and bilayers is discussed in terms of phospholipid fatty acyl and polar head group compositions. The inhibition of transfer activity by sulfhydryl agents and amphiphilic amines is summarized. The metabolism of the phosphoinositides is considered and a role for PI-TPs is proposed.

Lipids of nervous tissue: composition and metabolism

As indicated in the Introduction, the many significant developments in the recent past in our knowledge of the lipids of the nervous system have been collated in this article. That there is a sustained interest in this field is evident from the rather long bibliography which is itself selective. Obviously, it is not possible to summarize a review in which the chemistry, distribution and metabolism of a great variety of lipids have been discussed. However, from the progress of research, some general conclusions may be drawn. The period of discovery of new lipids in the nervous system appears to be over. All the major lipid components have been discovered and a great deal is now known about their structure and metabolism. Analytical data on the lipid composition of the CNS are available for a number of species and such data on the major areas of the brain are also at hand but information on the various subregions is meagre. Such investigations may yet provide clues to the role of lipids in brain function. Compared to CNS, information on PNS is less adequate. Further research on PNS would be worthwhile as it is amenable for experimental manipulation and complex mechanisms such as myelination can be investigated in this tissue. There are reports correlating lipid constituents with the increased complexity in the organization of the nervous system during evolution. This line of investigation may prove useful. The basic aim of research on the lipids of the nervous tissue is to unravel their functional significance. Most of the hydrophobic moieties of the nervous tissue lipids are comprised of very long chain, highly unsaturated and in some cases hydroxylated residues, and recent studies have shown that each lipid class contains characteristic molecular species. Their contribution to the properties of neural membranes such as excitability remains to be elucidated. Similarly, a large proportion of the phospholipid molecules in the myelin membrane are ethanolamine plasmalogens and their importance in this membrane is not known. It is firmly established that phosphatidylinositol and possibly polyphosphoinositides are involved with events at the synapse during impulse propagation, but their precise role in molecular terms is not clear. Gangliosides, with their structural complexity and amphipathic nature, have been implicated in a number of biological events which include cellular recognition and acting as adjuncts at receptor sites. More recently, growth promoting and neuritogenic functions have been ascribed to gangliosides. These interesting properties of gangliosides wIll undoubtedly attract greater attention in the future.(ABSTRACT TRUNCATED AT 400 WORDS)

Phospholipid exchange activity in developing rat brain

Phospholipid exchange activity has been determined in the supernatant fraction of rat brain from birth through to maturity by measuring the protein-catalysed transfer of total and individual 32P-labelled phospholipids from microsomal membranes to mitochondria, and the transfer of [14C]phosphatidylcholine from liposomes to mitochondria. Transfer activity has also been compared in brain and liver supernatant. Overall phospholipid exchange activity in the brain increased only slightly with age. The activity at birth was 75% of the adult value. However, the transfer of individual phospholipids showed markedly different trends during postnatal brain development. The transfer of phosphatidylinositol (PI) and ethanolamine phospholipids increased postnatally to a maximum at 9 days of age, with lowest values in adult brain. Phosphatidylcholine (PC) transfer increased from 9 days to reach maximum values in the mature brain. The transfer of sphingomyelin was highest immediately after birth. PI transfer activity was higher in brain than liver, while PC and ethanolamine phospholipid transfer activity was higher in liver. The heterogeneity of phospholipid exchange proteins in central nervous system tissue is reflected in the developmental changes in exchange activity towards individual phospholipids. The various exchange proteins appear to have separate induction mechanisms. The presence of exchange-protein activity from birth in the rat indicates the functional importance of phospholipid transport during cell acquisition and membrane proliferation. Activity is not primarily associated with membrane formation such as the formation of the myelin sheath, and therefore is more likely to be involved in the process of phospholipid turnover.

Phosphatidylinositol transfer protein from bovine brain. Substrate specificity and membrane binding properties

A recently developed fluorimetric transfer assay (Somerharju, P., Brockerhoff, H. and Wirtz, K.W.A. (1981) Biochim. Biophys. Acta 649, 521-528) has been applied to study the substrate specificity and membrane binding of the phosphatidylinositol-transfer protein from bovine brain. The substrate specificity was investigated by measuring the rate of transfer, either directly or indirectly, for a series of phosphatidylinositol analogues which included phosphatidic acid, phosphatidylglycerol as well as three lipids obtained from yeast phosphatidylinositol by partial periodate oxidation and subsequent borohydride reduction. Phosphatidylglycerol and the oxidation products of phosphatidylinositol were transferred at about one tenth of the rate observed for phosphatidylinositol while phosphatidic acid was not transferred. It is concluded that an intact inositol moiety favours the formation of the putative transfer protein-phosphatidylinositol complex. In addition to phosphatidylinositol, the transfer protein also transfers phosphatidylcholine. In order to obtain information on the possible occurrence of two sites of interaction, vesicles consisting of either pure 1-acyl-2-parinaroylphosphatidylinositol or 1-acyl-2-parinaroylphosphatidylcholine were titrated with the protein. Binding of labeled phospholipid to the protein was represented by an increase of lipid fluorescence and found to be much more efficient for phosphatidylinositol than for phosphatidylcholine. This is interpreted to indicate that the protein contains an endogenous phosphatidylinositol molecule which can be easily replaced by exogenous phosphatidylinositol but not by phosphatidylcholine, a lipid with a lower affinity for this protein. Thus the binding sites for the two phospholipids are mutually exclusive, i.e. phosphatidylinositol and phosphatidylcholine cannot be bound to the protein simultaneously. Finally, the effect of acidic phospholipids on the transfer protein activity was studied either by varying the content of phosphatidic acid in the acceptor vesicles or by adding vesicles of pure acidic phospholipids to the normal assay system. The latter vesicles consisted of either phosphatidic acid, phosphatidylglycerol, phosphatidylserine, phosphatidylinositol or cardiolipin. In both instances the transfer protein activity was inhibited, obviously through the enhanced association of the protein with the negatively charged vesicles. These findings strongly suggest that relatively nonspecific ionic forces rather than specific protein-phospholipid headgroup interactions contribute to the association of the phosphatidylinositol-transfer protein with membranes.

Intracellular phospholipid movement and the role of phospholipid transfer proteins in animal cells

The mechanism of the intracellular movement of phospholipids from their site of synthesis in the endoplasmic reticulum to mitochondria and other cell membranes is a major unsolved problem of cell biology. Phospholipid transfer proteins of varying specificity found in the soluble supernatant fractions of many tissues catalyze the transfer of phospholipids from microsomes to mitochondria in vitro. They are postulated to play a similar role in vivo, but evidence for their function in living cells is lacking. We have now used an analogue of choline, N-propyl-N,N-dimethylethanolamine [PDME, (2-hydroxyethyl)dimethylpropylammonium hydroxide], to devise a test for the function of the transfer proteins in living cells. The rates of translocation of newly synthesized phosphatidylcholine and the analogue phosphatidyl-PDME in living cells were compared with the rates of transfer in vitro catalyzed by soluble transfer proteins extracted from the same cells. Labeled PDME, choline, and ethanolamine were found to be rapidly incorporated into the lipids of isolated rat hepatocytes and of baby hamster kidney (BHK-21) cells in culture. The translocation of newly synthesized phosphatidylcholine and phosphatidyl-PDME was very rapid in both types of cells with a half-time for equilibration of a few minutes, while the translocation of phosphatidylethanolamine was much slower, with a half-time 20-80 fold longer than those of the other two phospholipids. We then compared these relative rates of movement with the activities of the phospholipid transfer proteins of the respective cells. Partially purified phosphatidylcholine transfer protein from rat liver transfers phosphatidylcholine and phosphatidyl-PDME at identical rates but transfers phosphatidylethanolamine at a rate too low to be detected. This result is consistent with an essential function of this transfer protein in vivo. In contrast, partially purified phosphatidylcholine phospholipid transfer protein from BHK cells transfers phosphatidylcholine rapidly, while no transfer of phosphatidyl-PDME and phosphatidylethanolamine was detected. We further found that the specific phosphatidylcholine transfer protein of BHK cells accounts for nearly all of the transfer activity detected in the crude soluble fraction. The rapid translocation of phosphatidyl-PDME in vivo in BHK cells is therefore inconsistent with the postulate that soluble phospholipid transfer proteins are responsible for the rapid movement of phospholipids from microsomes to mitochondria in living cells.

Transfer properties of the bovine brain phospholipid transfer protein. Effect of charged phospholipids and of phosphatidylcholine fatty acid composition

The monolayer technique has been used to study the transfer of [14C]phosphatidylinositol from the monolayer to phosphatidylcholine vesicles. An equivalent transfer rate was found for egg phosphatidylcholine, dioleoylphosphatidylcholine, dielaidoylphosphatidylcholine and dipalmitoylphosphatidylcholine. A reduced transfer rate was found for a shorter-chain derivative, dimyristoylphosphatidylcholine, and for species with two polyunsaturated fatty acid chains such as dilinoleoylphosphatidylcholine, diheptadecadienoylphosphatidylcholine, dilinolenoylphosphatidylcholine and diether and dialkyl derivatives. No activity was found for 1,3-dipalmitoylphosphatidylcholine. The presence of up to 5 mol% phosphatidylinositol in egg phosphatidylcholine vesicles had no effect on the transfer rate. Introduction of more than 5 mol% phosphatidylinositol or phosphatidic acid into the phosphatidylcholine vesicles gradually decreased the rate of phosphatidylinositol transfer from the monolayer. 20 mol% acidic phospholipid was nearly completely inhibitory. Transfer experiments between separate monolayers of phosphatidylcholine and phosphatidylinositol showed that the protein-bound phosphatidylcholine is readily exchanged for phosphatidylinositol, but the protein-bound phosphatidylinositol exchange for phosphatidylcholine occurs at a 20-times lower rate. The release of phosphatidylinositol is dependent on the lipid composition and the concentration of charged lipid in the acceptor membrane, but also on the ratio between donor and acceptor membranes. The main transfer protein from bovine brain which transfers phosphatidylinositol and phosphatidylcholine transfers also phosphatidylglycerol, but not phosphatidylserine or phosphatidic acid. The absence of significant changes in the surface pressure indicate that the phosphatidylinositol and phosphatidylcholine transfer is not accompanied by net mass transfer.