Trafficking of phosphatidylinositol by phosphatidylinositol transfer proteins

PtdIns is synthesized at the endoplasmic reticulum and its intracellular distribution to other organelles can be facilitated by lipid transfer proteins [PITPs (phosphatidylinositol transfer proteins)]. In this review, I summarize the current understanding of how PITPs are regulated by phosphorylation, how can they dock to membranes to exchange their lipid cargo and how cells use PITPs in signal transduction and membrane delivery. Mammalian PITPs, PITPalpha and PITPbeta, are paralogous genes that are 94% similar in sequence. Their structural design demonstrates that they can sequester PtdIns or PtdCho (phosphatidylcholine) in their hydrophobic cavity. To deliver the lipid cargo to a membrane, PITP has to undergo a conformational change at the membrane interface. PITPs have a higher affinity for PtdIns than PtdCho, which is explained by hydrogen-bond contacts between the inositol ring of PtdIns and the side-chains of four amino acid residues, Thr59, Lys61, Glu86 and Asn90, in PITPs. Regardless of species, these residues are conserved in all known PITPs. PITP transfer activity is regulated by a conserved serine residue (Ser166) that is phosphorylated by protein kinase C. Ser166 is only accessible for phosphorylation when a conformational change occurs in PITPs while docking at the membrane interface during lipid transfer, thereby coupling regulation of activity with lipid transfer function. Biological roles of PITPs include their ability to couple phospholipase C signalling to neurite outgrowth, cell division and stem cell growth.     

Copper reduction by copper binding proteins and its relation to neurodegenerative diseases

Increasing evidence supports an important role for metals in neurobiology. In fact, copper binding proteins that form bioinorganic complexes are able to display oxidant or anti-oxidant properties, which would impact on neuronal function or in the triggering of neurodegenerative process. Two proteins related to neurodegenerative diseases have been described as copper binding proteins: the amyloid precursor protein (APP), a protein related to Alzheimer's disease, and the Prion protein (PrP), related to Creutzfeldt-Jakob disease. We used different synthetic peptides from APP and PrP sequences in order to evaluate the ability to reduce copper. We observed that APP_135–156, amyloid--peptide (A_1–40), and PrP_59–91 all have copper reducing ability, with the APP_135–156 peptide being more potent than the other fragments. Moreover, we identify His, Cys and Trp residues as key amino acids involved in the copper reduction of A, APP and PrP, respectively. We postulated, that in a cellular context, the interaction of these proteins with copper could be necessary to reduce copper on plasma membrane, possibly presenting Cu(I) to the copper transporter, driving the delivery of this metal to antioxidant enzymes. Moreover, protein-metal complexes could be the catalytic centers for the formation of reactive oxygen species involved in the oxidative damage present both in Alzheimer's and Prion disease.     

Metabolism of ubiquinone in relation to thyroxine status

1. Under conditions of thyrotoxicosis induced by feeding rats with iodinated casein, ubiquinone concentration was found to increase in the liver by increased synthesis and by partly decreased catabolism leading to its accumulation. The increased ubiquinone was found primarily in the mitochondrial and supernatant fractions. 2. Supplementing the diet with thyroxine, at less than toxic doses, also increased the synthesis and the concentration of ubiquinone in the liver. 3. In the condition of hypothyroidism obtained by feeding rats with thiouracil the concentration and the synthesis of ubiquinone in the liver showed a small decrease. 4. Synthesis of ubiquinone in liver slices was partially inhibited by addition of thyroxine in vitro. Therefore the activation effect on ubiquinone synthesis of excess of thyroxine in the intact animals appears to be by an indirect mechanism.     

Mammalian diseases of phosphatidylinositol transfer proteins and their homologs

Inositol and phosphoinositide signaling pathways represent major regulatory systems in eukaryotes. The physiological importance of these pathways is amply demonstrated by the variety of diseases that involve derangements in individual steps in inositide and phosphoinositide production and degradation. These diseases include numerous cancers, lipodystrophies and neurological syndromes. Phosphatidylinositol transfer proteins (PITPs) are emerging as fascinating regulators of phosphoinositide metabolism. Recent advances identify PITPs (and PITP-like proteins) to be coincidence detectors, which spatially and temporally coordinate the activities of diverse aspects of the cellular lipid metabolome with phosphoinositide signaling. These insights are providing new ideas regarding mechanisms of inherited mammalian diseases associated with derangements in the activities of PITPs and PITP-like proteins.     

The silkmoth chorion: Morphogenesis of surface structures and its relation to synthesis of specific proteins

The morphogenesis of four spatially differentiated surface regions of the silkmoth eggshell (chorion) has been documented and correlated with differing patterns of chorion protein synthesis within the corresponding secretory cells. During the first half of choriogenesis the polygonal pattern of ridges which cover the entire chorion appears. Regional differences in the morphology of developing ridges are not accompanied by significant protein differences, and thus presumably reflect differences in secretory cell behavior and shape. During the second half of choriogenesis expanding domes of the chorion located immediately beneath three-cell junctions of the overlying secretory surface become prominent surface features exclusively in the aeropyle crown region. Domes are composed of a thin lamellar skin and an inner buttressing “filler.” Continued filler deposition appears to cause a ripping of the lamellar skin, transforming the dome into a multiple-pronged crown that overflows with filler. Continued synthesis of lamellar chorion components elongates and strengthens the crowns until they can stand alone without the support of filler. In the aeropyle crown region, synthesis of regionally specific proteins begins in the second half of choriogenesis and accelerates until the final stages, in parallel with dome/crown formation. The more numerous proteins which are common to all regions are synthesized at approximately equal rates within all regions, and their synthesis decelerates toward the end of choriogenesis. Fifteen of the proteins (excluding filler) which are found predominantly in the aeropyle crown region may be necessary but not sufficient for crown formation, since they also occur in the stripe region (1); presumably the secretory cell surfaces mold the same components differently in the two regions. Filler appears to play an important scaffolding role in crown formation. A group of eight aeropyle crown region-specific chorion proteins which compose filler have been identified on two-dimensional gels and shown to be restricted to one of five previously described classes of chorion proteins.     

Morphogenesis of silkmoth chorion: Initial framework formation and its relation to synthesis of specific proteins

Morphogenesis of the silkmoth eggshell is described at the ultrastructural level. Four zones are each assembled in a distinct manner and during a distinct developmental period: the innermost vitelline membrane and the adjacent trabecular layer appear consecutively, followed by a thin sieve layer, and a thick, lamellate chorion. Once formed, the sieve layer remains attached to microvilli, and thus all components which assemble into lamellae must pass through the sieve layer. Initially, lamellogenesis (and sieve layer formation) occurs in patches overlying trabeculae. Lamellae quickly fuse and new ones are added, presumably by apposition. Distinct types of lamellae seen in the mature chorion are already distinguishable in early lamellogenesis. The final lamellar number is attained before the developing chorion is one-half its final thickness or one-fifth its final dry weight. The early lamellae constitute a framework which is subsequently modified through expansion and densification. Proteins which may represent components of various parts of the eggshell have been identified on the basis of their timing of synthesis, relative amino acid compositions, and spatial distributions within the chorion.     

Emerging perspectives on multidomain phosphatidylinositol transfer proteins

The phosphatidylinositol transfer protein domain (PITP_d) is an evolutionarily conserved protein that is able to transfer phosphatidylinositol between membranes in vitro and in vivo. However some animal genomes also include genes that encode proteins where the PITP_d is found in cis with a number of additional domains and recent large scale genome sequencing efforts indicate that this type of multidomain architecture is widespread in the animal kingdom. In Drosophila photoreceptors, the multidomain phosphatidylinositol transfer protein RDGB is required to regulate phosphoinositide turnover during G-protein activated phospholipase C signalling. Recent studies in flies and mammalian cell culture models have begun to elucidate functions for the non-PITP_d of RDGB and its vertebrate orthologs. We review emerging evidence on the genomics, functional and cell biological perspectives of these multi-domain PITP_d containing proteins.