Plasma membrane-localized TMEM16 proteins are indispensable for expression of CFTR.

The cystic fibrosis transmembrane conductance regulator (CFTR) is the secretory chloride channel in epithelial tissues that has a central role in cystic fibrosis (CF) lung and gastrointestinal disease. A recent publication demonstrates a close association between CFTR and TMEM16A, the calcium-activated chloride channel. Thus, no CFTR chloride currents could be detected in airways and large intestine from mice lacking epithelial expression of TMEM16A. Here, we demonstrate that another plasma membrane-localized TMEM16 paralogue, TMEM16F, can compensate for the lack of TMEM16A. Using TMEM16 knockout mice, human lymphocytes, and a number of human cell lines with endogenous protein expression or heterologous expression, we demonstrate that CFTR can only function in the presence of either TMEM16A or TMEM16F. Double knockout of intestinal epithelial TMEM16A/F expression did not produce offsprings, suggesting a lethal phenotype in utero. Plasma membrane-localized TMEM16A or TMEM16F is required for exocytosis and expression of CFTR in the plasma membrane. TMEM16A/F proteins may therefore have an impact on disease severity in CF. KEY MESSAGES: • Cystic fibrosis is caused by the defective Cl- channel cystic fibrosis transmembrane conductance regulator (CFTR). • A close relationship exists between CFTR and the calcium-activated chloride channels TMEM16A/TMEM16F. • In conditional airway and intestinal knockout mice, lymphocytes from Scott disease patients and in overexpressing cells, CFTR is not functional in the absence of TMEM16A and TMEM16F. • TMEM16A and TMEM16F support membrane exocytosis and are essential for plasma membrane insertion of CFTR.

The architecture of the OmpC-MlaA complex sheds light on the maintenance of outer membrane lipid asymmetry in Escherichia coli.

A distinctive feature of the Gram-negative bacterial cell envelope is the asymmetric outer membrane (OM), where lipopolysaccharides and phospholipids (PLs) reside in the outer and inner leaflets, respectively. This unique lipid asymmetry renders the OM impermeable to external insults, including antibiotics and bile salts. In Escherichia coli, the complex comprising osmoporin OmpC and the OM lipoprotein MlaA is believed to maintain lipid asymmetry by removing mislocalized PLs from the outer leaflet of the OM. How this complex performs this function is unknown. Here, we defined the molecular architecture of the OmpC-MlaA complex to gain insights into its role in PL transport. Using in vivo photo-cross-linking and molecular dynamics simulations, we established that MlaA interacts extensively with OmpC and is located entirely within the lipid bilayer. In addition, MlaA forms a hydrophilic channel, likely enabling PL translocation across the OM. We further showed that flexibility in a hairpin loop adjacent to the channel is critical in modulating MlaA activity. Finally, we demonstrated that OmpC plays a functional role in maintaining OM lipid asymmetry together with MlaA. Our work offers glimpses into how the OmpC-MlaA complex transports PLs across the OM and has important implications for future antibacterial drug development.

flippant-An R package for the automated analysis of fluorescence-based scramblase assays.

BACKGROUND: The lipid scrambling activity of protein extracts and purified scramblases is typically measured using a fluorescence-based assay. While the assay has yielded insight into the scramblase activity in crude membrane preparations, functional validation of candidate scramblases, stoichiometry of scramblase complexes as well as ATP-dependence of flippases, data analysis in its context has remained a task involving many manual steps. RESULTS: With the extension package "flippant" to R, a free software environment for statistical computing and graphics, we introduce an integrated solution for the analysis and publication-grade graphical presentation of dithionite scramblase assays and demonstrate its utility in revisiting an originally manual analysis from the publication record, closely reproducing the reported results. CONCLUSIONS: "flippant" allows for quick, reproducible data analysis of scramblase activity assays and provides a platform for review, dissemination and extension of the strategies it employs.

Phospholipid scramblase expression in the pregnant mouse uterus in LPS-induced preterm delivery.

Phospholipid scramblases (PLSCR), stimulated by proinflammatory cytokines, are thought to mediate the loss of lipid asymmetry in cell membranes, allowing for specific reactions in the coagulation cascade. The PLSCR may therefore provide a link between inflammation, coagulation, and, because thrombin is a uterotonic, preterm birth (PTB). To explore the relationship between PLSCR expression and inflammation-related PTB, we utilized reverse transcriptase-polymerase chain reaction and Western blot studies to quantify messenger RNA (mRNA) and protein expression for the 4 PLSCR homologues (PLSCR 1-4). Uteri from day 15 pregnant mice were harvested at several time points after intrauterine lipopolysaccharide (LPS) injection (or normal saline, for controls). Expression of mRNA in all 4 Plscr isoforms was demonstrated. Lipopolysaccharide treatment resulted in increased expression of PLSCR-1 and a decrease in Plscr4 mRNA, thereby demonstrating modulation of PLSCR-1 and PLSCR-4 in LPS-induced PTB. Additionally, protein expression was confirmed for all except PLSCR-4, with increased expression of PLSCR-1 after LPS treatment.

Aminophospholipid translocase and phospholipid scramblase activities in sickle erythrocyte subpopulations.

Phosphatidylserine (PS) externalization may contribute to Sickle Cell Disease (SCD) characteristics including thrombogenesis, endothelial adhesion and shortened red blood cell (RBC) lifespan. Aminophospholipid translocase (APLT) returns externalized PS to the inner membrane, and phospholipid scramblase (PLSCR) equilibrates phospholipids (PL) across the membrane. APLT inhibition and PLSCR activation appear to be important for PS externalization. We examined relationships between APLT, PLSCR and external PS in mature sickle RBC and reticulocytes. Normally-hydrated sickle RBC without external PS had active APLT and inactive PLSCR. PS-exposing sickle RBC had inhibited APLT and active PLSCR. Sickle reticulocytes had active APLT and active PLSCR independent of external PS. Sickle RBC dehydrated in vivo had the highest proportion of PS-exposing RBC and markedly inhibited APLT. Normal and sickle RBC dehydrated in vitro had moderately decreased APLT. Rehydration resulted in significant recovery of APLT in RBC previously dehydrated in vitro, but not in sickle RBC dehydrated in vivo. These findings indicate that (i) PS externalization in mature sickle RBC depends on the balance between APLT and PLSCR activities, (ii) PS externalization in sickle reticulocytes depends primarily on PLSCR activation and (iii) APLT inhibition in sickle RBC dehydrated in vivo is due to dehydration itself and other factors.

PLTP is present in the nucleus, and its nuclear export is CRM1-dependent.

Phospholipid transfer protein (PLTP), one of the key lipid transfer proteins in plasma and cerebrospinal fluid, is nearly ubiquitously expressed in cells and tissues. Functions of secreted PLTP have been extensively studied. However, very little is known about potential intracellular PLTP functions. In the current study, we provide evidence for PLTP localization in the nucleus of cells that constitutively express PLTP (human neuroblastoma cells, SK-N-SH; and human cortical neurons, HCN2) and in cells transfected with human PLTP (Chinese hamster ovary and baby hamster kidney cells). Furthermore, we have shown that incubation of these cells with leptomycin B (LMB), a specific inhibitor of nuclear export mediated by chromosome region maintenance 1 (CRM1), leads to intranuclear accumulation of PLTP, suggesting that PLTP nuclear export is CRM1-dependent. We also provide evidence for entry of secreted PLTP into the cell and its translocation to the nucleus, and show that intranuclear PLTP is active in phospholipid transfer. These findings suggest that PLTP is involved in novel intracellular functions.

Measurement of phosphatidylinositol and phosphatidylcholine binding and transfer activity of the lipid transport protein PITP.

Mammalian cells have evolved proteins that can extract single lipids from membranes and sequester them in their hydrophobic cavity. These proteins, collectively known as lipid transport proteins, play essential roles in many aspects of lipid metabolism, lipid signaling, and membrane traffic. Phosphatidylinositol transfer proteins (alpha and beta) are lipid transport proteins that specifically bind phosphatidylinositol or phosphatidylcholine in their hydrophobic cavity and facilitate their transfer from one membrane compartment to another. In addition, PITPbeta can facilitate sphingomyelin transfer. This chapter describes methods to monitor the transfer and binding activity of PITPs using a variety of assays, including an assay that uses microsomes as a donor and liposomes as an acceptor of PtdIns. For phosphatidylcholine and sphingomyelin transfer, liposomes are used as a donor compartment and mitochondria as an acceptor compartment. A separate method describes the use of permeabilized cells as a source of donor lipids and liposomes as an acceptor membrane. In addition to lipid transfer, methods to identify the lipids that occupy the hydrophobic cavity of PITPs are discussed.

Expression of Atp8b3 in murine testis and its characterization as a testis specific P-type ATPase.

Spermatogenesis is a complex process that produces haploid motile sperms from diploid spermatogonia through dramatic morphological and biochemical changes. P-type ATPases, which support a variety of cellular processes, have been shown to play a role in the functioning of sperm. In this study, we isolated one putative androgen-regulated gene, which is the previously reported sperm-specific aminophospholipid transporter (Atp8b3, previously known as Saplt), and explored its expression pattern in murine testis and its biochemical characteristics as a P-type ATPase. Atp8b3 is exclusively expressed in the testis and its expression is developmentally regulated during testicular development. Immunohistochemistry of the testis reveals that Atp8b3 is expressed only in germ cells, especially haploid spermatids, and the protein is localized in developing acrosomes. As expected, from its primary amino acid sequence, ATP8B3 has an ATPase activity and is phosphorylated by an ATP-producing acylphosphate intermediate, which is a signature property of the P-Type ATPases. Together, ATP8B3 may play a role in acrosome development and/or in sperm function during fertilization.

In vivo vitamin C supplementation increases phosphoinositol transfer protein expression in peripheral blood mononuclear cells from healthy individuals.

Ascorbate can act as both a reducing and oxidising agent in vitro depending on its environment. It can modulate the intracellular redox environment of cells and therefore is predicted to modulate thiol-dependent cell signalling and gene expression pathways. Using proteomic analysis of vitamin C-treated T cells in vitro, we have previously reported changes in expression of five functional protein groups associated with signalling, carbohydrate metabolism, apoptosis, transcription and immune function. The increased expression of the signalling molecule phosphatidylinositol transfer protein (PITP) was also confirmed using Western blotting. Herein, we have compared protein changes elicited by ascorbate in vitro, with the effect of ascorbate on plasma potassium levels, on peripheral blood mononuclear cell (PBMC) apoptosis and PITP expression, in patients supplemented with vitamin C (0-2 g/d) for up to 10 weeks to investigate whether in vitro model systems are predictive of in vivo effects. PITP varied in expression widely between subjects at all time-points analysed but was increased by supplementation with 2 g ascorbate/d after 5 and 10 weeks. No effects on plasma potassium levels were observed in supplemented subjects despite a reduction of K+ channel proteins in ascorbate-treated T cells in vitro. Similarly, no effect of vitamin C supplementation on PBMC apoptosis was observed, whilst ascorbate decreased expression of caspase 3 recruitment domain protein in vitro. These data provide one of the first demonstrations that proteomics may be valuable in developing predictive markers of nutrient effects in vivo and may identify novel pathways for studying mechanisms of action in vivo.

Regulation of PI3K signalling by the phosphatidylinositol transfer protein PITPalpha during axonal extension in hippocampal neurons.

Phosphatidylinositol transfer proteins (PITPs) mediate the transfer of phosphatidylinositol (PtdIns) or phosphatidylcholine (PtdCho) between two membrane compartments, thereby regulating the interface between signalling, phosphoinositide (PI) metabolism and membrane traffic. Here, we show that PITPalpha is enriched in specific areas of the postnatal and adult brain, including the hippocampus and cerebellum. Overexpression of PITPalpha, but not PITPbeta or a PITPalpha mutant deficient in binding PtdIns, enhances laminin-dependent extension of axonal processes in hippocampal neurons, whereas knockdown of PITPalpha protein by siRNA suppresses laminin and BDNF-induced axonal growth. PITPalpha-mediated axonal outgrowth is sensitive to phosphoinositide 3-kinase (PI3K) inhibition and shows dependency on the Akt/GSK-3/CRMP-2 pathway. We conclude that PITPalpha controls the polarized extension of axonal processes through the provision of PtdIns for localized PI3K-dependent signalling.

Increased phospholipid transfer protein activity associated with the impaired cellular cholesterol efflux in type 2 diabetic subjects with coronary artery disease.

Reverse cholesterol transport (RCT) is the pathway, by which the excess of cholesterol is removed from peripheral cells to the liver. An early step of RCT is the efflux of free cholesterol from cell membranes that is mediated by high-density lipoproteins (HDL). Phospholipid transfer protein (PLTP) transfers phospholipids between apolipoprotein-B-containing lipoproteins (i.e., chylomicrons and very low-density lipoproteins) and HDL. PLTP contributes to the HDL maturation and increases the ability of HDL to extract the cellular cholesterol. It is known that RCT is impaired in type 2 diabetic patients, especially when cardiovascular complication is associated with. In this study, we measured the serum capacity that promotes cellular cholesterol efflux and the plasma PLTP activity in type 2 diabetic patients with coronary artery disease (CAD) (n = 35), those without CAD (n = 24), and 35 healthy subjects as a sex- and age-matched control. In patients with CAD, plasma triglyceride level was higher compared to controls (p < 0.01) and HDL-cholesterol was lower (p < 0.01 vs control and the patients without CAD). In diabetic patients with or without CAD, PLTP activity was consistently increased, compared to controls, while cellular cholesterol efflux activity was decreased by 20% (p < 0.001) or 13.5% (p < 0.01), respectively. In conclusion, plasma PLTP activity was increased in type 2 diabetic patients with or without CAD, which could impair cellular cholesterol removal and might accelerate atherosclerosis in diabetic patients.

Nuclear interactions of topoisomerase II alpha and beta with phospholipid scramblase 1.

DNA topoisomerase (topo) II modulates DNA topology and is essential for cell division. There are two isoforms of topo II (alpha and beta) that have limited functional redundancy, although their catalytic mechanisms appear the same. Using their COOH-terminal domains (CTDs) in yeast two-hybrid analysis, we have identified phospholipid scramblase 1 (PLSCR1) as a binding partner of both topo II alpha and beta. Although predominantly a plasma membrane protein involved in phosphatidylserine externalization, PLSCR1 can also be imported into the nucleus where it may have a tumour suppressor function. The interactions of PLSCR1 and topo II were confirmed by pull-down assays with topo II alpha and beta CTD fusion proteins and endogenous PLSCR1, and by co-immunoprecipitation of endogenous PLSCR1 and topo II alpha and beta from HeLa cell nuclear extracts. PLSCR1 also increased the decatenation activity of human topo IIalpha. A conserved basic sequence in the CTD of topo IIalpha was identified as being essential for binding to PLSCR1 and binding of the two proteins could be inhibited by a synthetic peptide corresponding to topo IIalpha amino acids 1430-1441. These studies reveal for the first time a physical and functional interaction between topo II and PLSCR1.

Measuring translocation of fluorescent lipid derivatives across yeast Golgi membranes.

Phospholipid asymmetry is a fundamental feature of the plasma membrane of most eukaryotic cells and its regulation is linked to diverse physiological processes such as apoptosis and blood clotting [P. Williamson, R.A. Schlegel, Biochim. Biophys. Acta 1585 (2002) 53-63; R.F. Zwaal, A.J. Schroit, Blood 89 (1997) 1121-1132]. In addition, the phospholipid translocases (flippases) that are thought to establish asymmetry are also implicated in vesicle-mediated protein transport throughout the secretory and endocytic pathways [T.R. Graham, Trends Cell Biol. 14 (2004) 670-677]. However, the biochemical properties of phospholipid translocases in membranes of the Golgi complex and endosomes have received much less attention than translocases in the plasma membrane. We describe here a method for purifying yeast Golgi membranes and assaying an ATP-dependent phospholipid translocase activity in these membranes using fluorescent lipid analogues. This assay detects ATP-dependent translocation of labeled phosphatidylserine across late Golgi membranes, which requires the activity of a P-type ATPase called Drs2p [P. Natarajan, J. Wang, Z. Hua, T.R. Graham, Proc. Natl. Acad. Sci. USA 101 (2004) 10614-10619].

The negative c-Myc target onzin affects proliferation and apoptosis via its obligate interaction with phospholipid scramblase 1.

Onzin, the product of a negatively c-Myc-regulated target gene, is highly expressed in myeloid cells. As a result of its interaction with and activation of Akt1 and Mdm2, onzin down-regulates p53. The apoptotic sensitivity of several cell lines is thus directly related to onzin levels. We have conducted a search for additional onzin-interacting proteins and identified phospholipid scramblase 1 (PLSCR1), an endofacial membrane protein, which is proposed to mediate the bidirectional movement of plasma membrane phospholipids during proliferation and apoptosis. PLSCR1 interacts with the same cysteine-rich domain of onzin as do Akt1 and Mdm2, whereas the onzin-interacting domain of PLSCR1 centers around, but does not require, a previously identified palmitoylation signal. Depletion of endogenous PLSCR1 in myeloid cells leads to a phenotype that mimics that of onzin overexpression, providing evidence that PLSCR1 is a physiologic regulator of onzin. In contrast, PLSCR1 overexpression in fibroblasts, which normally do not express onzin, affects neither growth nor apoptosis unless onzin is coexpressed, in which case PLSCR1 completely abrogates onzin's positive effects on proliferation and survival. These findings demonstrate a functional interdependence between onzin and PLSCR1. They further suggest a contiguous link between the earliest events mediated by c-Myc and the latest ones, which culminate at the cell surface and lead to phospholipid reshuffling and cell death.

The class I PITP giotto is required for Drosophila cytokinesis.

Phosphatidylinositol transfer proteins (PITPs) are highly conserved polypeptides that bind phosphatidylinositol or phosphatidylcholine monomers, facilitating their transfer from one membrane compartment to another . Although PITPs have been implicated in a variety of cellular functions, including lipid-mediated signaling and membrane trafficking, the precise biological roles of most PITPs remain to be elucidated . Here we show for the first time that a class I PITP is involved in cytokinesis. We found that giotto (gio), a Drosophila gene that encodes a class I PITP, serves an essential function required for both mitotic and meiotic cytokinesis. Neuroblasts and spermatocytes from gio mutants both assemble regular actomyosin rings. However, these rings fail to constrict to completion, leading to cytokinesis failures. Moreover, gio mutations cause an abnormal accumulation of Golgi-derived vesicles at the equator of spermatocyte telophases, suggesting that Gio is implicated in membrane-vesicle fusion. Consistent with these results, we found that Gio is enriched at the cleavage furrow, the ER, and the spindle envelope. We propose that Gio mediates transfer of lipid monomers from the ER to the equatorial membrane, causing a specific local enrichment in phosphatidylinositol. This change in membrane composition would ultimately facilitate vesicle fusion, allowing membrane addition to the furrow and/or targeted delivery of proteins required for cytokinesis.

Mechanism of interaction of PITPalpha with membranes: conformational changes in the C-terminus associated with membrane binding.

Eukaryotic phosphatidylinositol transfer proteins (PITPs) are composed predominantly of small ( approximately 32 kDa) soluble proteins that bind and transfer a single phospholipid, normally phosphatidylinositol or phosphatidycholine. Two forms, PITPalpha and PITPbeta, which share approximately 80% amino acid sequence similarity, are known. Rat PITPalpha was labeled at specific single reactive Cys residues with I-AEDANS and used to examine PITP-membrane interactions. Upon binding to phospholipid vesicles, PITP labeled with AEDANS at the C-terminus, a region postulated to be involved in membrane binding, shows significant decreases in both steady-state and dynamic fluorescence anisotropy. In contrast, PITPs labeled with AEDANS at sites located distal to the C-terminus show increases in both steady-state and dynamic anisotropy. These results suggest that interaction of PITP with membrane surfaces leads to significant alterations in conformation and perhaps melting of the C-terminal helix.