The biogenesis of the photosynthetic thylakoid membranes inside plant chloroplasts requires enzymes at the plastid envelope and the endoplasmic reticulum (ER). Extensive lipid trafficking is required for thylakoid lipid biosynthesis. Here the trigalactosyldiacylglycerol2 (tgd2) mutant of Arabidopsis is described. To the extent tested, tgd2 showed a complex lipid phenotype identical to the previously described tgd1 mutant. The aberrant accumulation of oligogalactolipids and triacylglycerols and the reduction of molecular species of galactolipids derived from the ER are consistent with a disruption of the import of ER-derived lipids into the plastid. The TGD1 protein is a permease-like component of an ABC transporter located in the chloroplast inner envelope membrane. The TGD2 gene encodes a phosphatidic acid-binding protein with a predicted mycobacterial cell entry domain. It is tethered to the inner chloroplast envelope membrane facing the outer envelope membrane. Presumed bacterial orthologs of TGD1 and TGD2 in Gram-negative bacteria are typically organized in transcriptional units, suggesting their involvement in a common biological process. Expression of the tgd2-1 mutant cDNA caused a dominantnegative effect replicating the tgd2 mutant phenotype. This result is interpreted as the interference of the mutant protein with its native protein complex. It is proposed that TGD2 represents the substrate-binding or regulatory component of a phosphatidic acid͞lipid transport complex in the chloroplast inner envelope membrane.Arabidopsis ͉ membrane transporter ͉ glycerolipids ͉ ABC transporter ͉ substrate-binding protein A s plant leaves expand the demand on the lipid biosynthetic machinery is high because leaf cells contain one of the most extensive membrane systems found in nature, the photosynthetic thylakoid membrane of chloroplasts. The most abundant thylakoid lipids include nonphosphorous galactolipids. Galactolipid biosynthesis involves the formation of phosphatidic acid (PA) in the plastid and at the endoplasmic reticulum (ER) in many plants (1, 2), including Arabidopsis. Fatty acids derived from de novo synthesis in the plastid are assembled into PA in the plastid or at the ER. In Arabidopsis, diacylglycerols derived from the plastid pathway or the ER pathway are present in galactolipids in approximately equal proportion (3). The Arabidopsis lipid galactosyltransferases MGD1 and DGD1, which successively galactosylate diacylglycerol, are associated with the inner and the outer chloroplast envelope membranes, respectively (4). The topology of the galactolipid biosynthetic machinery and the involvement of the ER pathway require extensive subcellular lipid trafficking, most of which is mechanistically not understood.To date, two mutants of Arabidopsis have been described that affect lipid trafficking from the ER to the plastid. The act1(ats1) mutant is deficient in the plastidic glycerol 3-phopshate acyltransferase, and most of the galactolipids in this mutant are derived from the ER pathway (5). In contrast, gala...
Plants are sessile and cannot move to appropriate hiding places or feeding grounds to escape adverse conditions. As a consequence, they evolved mechanisms to detect changes in their environment, communicate these to different organs, and adjust development accordingly. These adaptations include two long-distance transport systems which are essential in plants: the xylem and the phloem. The phloem serves as a major trafficking pathway for assimilates, viruses, RNA, plant hormones, metabolites, and proteins with functions ranging from synthesis to metabolism to signaling. The study of signaling compounds within the phloem is essential for our understanding of plant communication of environmental cues. Determining the nature of signals and the mechanisms by which they are communicated through the phloem will lead to a more complete understanding of plant development and plant responses to stress. In our analysis of Arabidopsis phloem exudates, we had identified several lipid-binding proteins as well as fatty acids and lipids. The latter are not typically expected in the aqueous environment of sieve elements. Hence, lipid transport in the phloem has been given little attention until now. Long-distance transport of hydrophobic compounds in an aqueous system is not without precedence in biological systems: a variety of lipids is found in human blood and is often bound to proteins. Some lipid–protein complexes are transported to other tissues for storage, use, modification, or degradation; others serve as messengers and modulate transcription factor activity. By simple analogy it raises the possibility that lipids and the respective lipid-binding proteins in the phloem serve similar functions in plants and play an important role in stress and developmental signaling. Here, we introduce the lipid-binding proteins and the lipids we found in the phloem and discuss the possibility that they may play an important role in developmental and stress signaling.
Many recent studies highlight the importance of lipids in membrane proteins, including in the formation of well-ordered crystals. To examine the effect of changes in one lipid, cardiolipin, on the lipid profile and the production, function and crystallization of an intrinsic membrane protein, cytochrome c oxidase, the cardiolipin synthase (cls) gene of Rhodobacter sphaeroides was mutated, causing > 90% reduction in cardiolipin content in vivo and selective changes in the abundances of other lipids. Under these conditions, a fully native cytochrome c oxidase (CcO) was produced, as indicated by its activity, spectral properties and crystal characteristics. Analysis by MALDI tandem mass spectrometry (MS/MS) revealed that the cardiolipin level in CcO crystals, as in the membranes, was greatly decreased. Lipid species present in the crystals were directly analyzed for the first time using MS/MS, documenting their identities and fatty acid chain composition. The fatty acid content of cardiolipin in R. sphaeroides CcO (predominantly 18:1) differs from that in mammalian CcO (18:2). In contrast to the cardiolipin-dependence of mammalian CcO activity, major depletion of cardiolipin in R. sphaeroides did not impact any aspect of CcO structure or behavior, suggesting a greater tolerance of interchange of CL by other lipids in this bacterial system.
A specific requirement for lipids, particularly cardiolipin (CL), in cytochrome c oxidase (CcO) has been reported in many previous studies using mainly in vitro lipid removal approaches in mammalian systems. Our accompanying paper shows that CcO produced in markedly CL-depleted Rhodobacter sphaeroides displays wild type properties in all respects, likely enabled by quantitative substitution by other negatively charged lipids. To further examine the structural basis for the lipid requirements of R. sphaeroides CcO and the extent of interchangeability between lipids, a metabolic approach was employed to enhance the alteration of the lipid profiles of the CcO-expressing strains of R. sphaeroides in vivo using a phosphate-limiting growth medium in addition to the CL-deficient mutation. Strikingly, the purified CcO produced under these conditions still maintained wild type function and characteristics, in spite of even greater depletion of cardiolipin compared to the CL-deficient mutant alone (undetectable by MS) and drastically altered profiles of all the phospholipids and non-phospholipids. The lipids in the membrane and in the purified CcO were identified and quantified by ESI and MALDI mass spectrometry and tandem mass spectrometry. Comparison between the molecular structures of those lipids that showed major changes provide new insight into the structural rationale for the flexible lipid requirements of CcO from R. sphaeroides, and reveal a more comprehensive interchangeability network between different phospholipids and non-phospholipids.
Global climate changes inversely affect our ability to grow the food required for an increasing world population. To combat future crop loss due to abiotic stress, we need to understand the signals responsible for changes in plant development and the resulting adaptations, especially the signaling molecules traveling long-distance through the plant phloem. Using a proteomics approach, we had identified several putative lipid-binding proteins in the phloem exudates. Simultaneously, we identified several complex lipids as well as jasmonates. These findings prompted us to propose that phloem (phospho-) lipids could act as long-distance developmental signals in response to abiotic stress, and that they are released, sensed, and moved by phloem lipid-binding proteins (Benning et al., 2012). Indeed, the proteins we identified include lipases that could release a signaling lipid into the phloem, putative receptor components, and proteins that could mediate lipid-movement. To test this possible protein-based lipid-signaling pathway, three of the proteins, which could potentially act in a relay, are characterized here: (I) a putative GDSL-motif lipase (II) a PIG-P-like protein, with a possible receptor-like function; (III) and PLAFP (phloem lipid-associated family protein), a predicted lipid-binding protein of unknown function. Here we show that all three proteins bind lipids, in particular phosphatidic acid (PtdOH), which is known to participate in intracellular stress signaling. Genes encoding these proteins are expressed in the vasculature, a prerequisite for phloem transport. Cellular localization studies show that the proteins are not retained in the endoplasmic reticulum but surround the cell in a spotted pattern that has been previously observed with receptors and plasmodesmatal proteins. Abiotic signals that induce the production of PtdOH also regulate the expression of GDSL-lipase and PLAFP, albeit in opposite patterns. Our findings suggest that while all three proteins are indeed lipid-binding and act in the vasculature possibly in a function related to long-distance signaling, the three proteins do not act in the same but rather in distinct pathways. It also points toward PLAFP as a prime candidate to investigate long-distance lipid signaling in the plant drought response.
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