Formation of Mitochondrial Outer Membrane Derived Protrusions and Vesicles in Arabidopsis thaliana

Mitochondria are dynamic organelles that have inner and outer membranes. In plants, the inner membrane has been well studied but relatively little is known about the outer membrane. Here we report that Arabidopsis cells have mitochondrial outer membrane-derived structures, some of which protrude from the main body of mitochondria (mitochondrial outer-membrane protrusions; MOPs), while others form vesicle-like structures without a matrix marker. The latter vesicle-like structures are similar to some mammalian MDVs (mitochondrial-derived vesicles). Live imaging demonstrated that a plant MDV budded off from the tip of a MOP. MDVs were also observed in the drp3a drp3b double mutant, indicating that they could be formed without the mitochondrial fission factors DRP3A and DRP3B. Double staining studies showed that the MDVs were not peroxisomes, endosomes, Golgi apparatus or trans-Golgi network (TGN). The numbers of MDVs and MOPs increased in senescent leaves and after dark treatment. Together, these results suggest that MDVs and MOPs are related to leaf senescence.     

The Taz1p Transacylase Is Imported and Sorted into the Outer Mitochondrial Membrane via a Membrane Anchor Domain

Mutations in the mitochondrial transacylase tafazzin, Taz1p, in Saccharomyces cerevisiae cause Barth syndrome, a disease of defective cardiolipin remodeling. Taz1p is an interfacial membrane protein that localizes to both the outer and inner membranes, lining the intermembrane space. Pathogenic point mutations in Taz1p that alter import and membrane insertion result in accumulation of monolysocardiolipin. In this study, we used yeast as a model to investigate the biogenesis of Taz1p. We show that to achieve this unique topology in mitochondria, Taz1p follows a novel import pathway in which it crosses the outer membrane via the translocase of the outer membrane and then uses the Tim9p-Tim10p complex of the intermembrane space to insert into the mitochondrial outer membrane. Taz1p is then transported to membranes of an intermediate density to reach a location in the inner membrane. Moreover, a pathogenic mutation within the membrane anchor (V224R) alters Taz1p import so that it bypasses the Tim9p-Tim10p complex and interacts with the translocase of the inner membrane, TIM23, to reach the matrix. Critical targeting information for Taz1p resides in the membrane anchor and flanking sequences, which are often mutated in Barth syndrome patients. These studies suggest that altering the mitochondrial import pathway of Taz1p may be important in understanding the molecular basis of Barth syndrome.     

Specific Membrane Lipid Composition Is Important for Plasmodesmata Function in Arabidopsis

Plasmodesmata (PD) are nano-sized membrane-lined channels controlling intercellular communication in plants. Although progress has been made in identifying PD proteins, the role played by major membrane constituents, such as the lipids, in defining specialized membrane domains in PD remains unknown. Through a rigorous isolation of “native” PD membrane fractions and comparative mass spectrometry-based analysis, we demonstrate that lipids are laterally segregated along the plasma membrane (PM) at the PD cell-to-cell junction in Arabidopsis thaliana. Remarkably, our results show that PD membranes display enrichment in sterols and sphingolipids with very long chain saturated fatty acids when compared with the bulk of the PM. Intriguingly, this lipid profile is reminiscent of detergent-insoluble membrane microdomains, although our approach is valuably detergent-free. Modulation of the overall sterol composition of young dividing cells reversibly impaired the PD localization of the glycosylphosphatidylinositol-anchored proteins Plasmodesmata Callose Binding 1 and the β-1,3-glucanase PdBG2 and altered callose-mediated PD permeability. Altogether, this study not only provides a comprehensive analysis of the lipid constituents of PD but also identifies a role for sterols in modulating cell-to-cell connectivity, possibly by establishing and maintaining the positional specificity of callose-modifying glycosylphosphatidylinositol proteins at PD. Our work emphasizes the importance of lipids in defining PD membranes.     

HxcQ Liposecretin Is Self-piloted to the Outer Membrane by Its N-terminal Lipid Anchor

Secretins are an unusual and important class of bacterial outer membrane (OM) proteins. They are involved in the transport of single proteins or macromolecular structures such as pili, needle complexes, and bacteriophages across the OM. Secretins are multimeric ring-shaped structures that form large pores in the OM. The targeting of such macromolecular structures to the OM often requires special assistance, conferred by specific pilotins or pilot proteins. Here, we investigated HxcQ, the OM component of the second Pseudomonas aeruginosa type II secretion system. We found that HxcQ forms high molecular mass structures resistant to heat and SDS, revealing its secretin nature. Interestingly, we showed that HxcQ is a lipoprotein. Construction of a recombinant nonlipidated HxcQ (HxcQnl) revealed that lipidation is essential for HxcQ function. Further phenotypic analysis indicated that HxcQnl accumulates as multimers in the inner membrane of P. aeruginosa, a typical phenotype observed for secretins in the absence of their cognate pilotin. Our observations led us to the conclusion that the lipid anchor of HxcQ plays a pilotin role. The self-piloting of HxcQ to the OM was further confirmed by its correct multimeric OM localization when expressed in the heterologous host Escherichia coli. Altogether, our results reveal an original and unprecedented pathway for secretin transport to the OM.     

拟南芥TAG1 基因对脂类合成调控作用的研究进展

三酰甘油(TAG)是真核生物中能量贮存的最主要形式。植物中贮存的三酰甘油是食用油类和工业用油的主要来源。TAG1基因的表达产物甘油二酯酰基转移酶(DGAT)能够调控三酰甘油的合成。as11是TAG1基因突变获得的脂类代谢相关突变体。该文概述了拟南芥(Arabidopsis thaliana)突变体as11的生物学特征及TAG1基因对脂类合成调控的最新进展。     

拟南芥TAG1基因对脂类合成调控作用的研究进展

三酰甘油（TAG）是真核生物中能量贮存的最主要形式。植物中贮存的三酰甘油是食用油类和工业用油的主要来源。TAG1基因的表达产物甘油二酯酰基转移酶（DGAT）能够调控三酰甘油的合成。as11是TAG1基因突变获得的脂类代谢相关突变体。该文概述了拟南芥（Arabidopsis thaliana）突变体as11的生物学特征及TAG1基因对脂类合成调控的最新进展。     

磷缺失引起小麦叶片中脂含量的变化与脂的合成和磷脂酰甘油的降解有关

对生长在不同磷营养水平条件下小麦(Triticum aestivum var.Zhongyou 9507)叶片中光合膜脂含量变化的原因进行了研究.通过对生长在不同磷营养水平条件下9 d龄和16 d龄小麦叶片中光合膜脂含量的分析,发现在磷缺失培养条件下,小麦光合膜脂的相对含量发生了很大变化,这种变化与小麦叶龄密切相关.在16d龄小麦植株中,第一片叶为老叶,第二片叶为较老叶,而第三片叶为新叶,PG和MGDG在叶片中的相对含量从新叶到老叶逐渐下降,而DGDG和SQDG含量逐渐上升;在磷缺失条件下,16 d龄小麦第一叶片中PG的含量(2.5%)远远低于其在9 d龄第一叶片中的含量(5.5%).以上结果说明,磷缺失引起小麦叶片中脂含量的变化不仅与脂合成有关,而且与PG的降解有关;新生叶片中PG含量减少的主要原因是由于磷供应不足,从而影响了PG的合成;而PG的降解则是老叶中PG含量下降的主要原因.     

Reconstitution of the Mitochondrial ATP-Dependent Potassium Channel into Bilayer Lipid Membrane1

Electrical properties and regulation of the mitochondrialATP-dependent potassium channel were studied. The channel protein wassolubilized from the mitochondrial membrane using an ethanol/water mixture.Reconstituted into a bilayer lipid membrane BLM), the protein formed aslightly voltage-dependent channel with a conductance of 10 pS in 100 mM KCl.Often, several channels worked simultaneously (clusters) when many channelswere incorporated into the BLM. The elementary channel and the clusters wereboth highly potassium selective. At concentrations of 1 to 10 M, ATPfavors channel opening, while channels become closed at 1–3 mM ATP. GDP(0.5 mM) reactivated the ATP-closed channels without affecting the untreatedchannels. The sulfhydryl-reducing agent ditiothreitol increased the openprobability at concentrations of 1 to 3 mM, but damaged the selectivity ofthe channel.     

磷缺失引起小麦叶片中脂含量的变化与脂的合成和磷脂酰甘油的降解有关(英文)

对生长在不同磷营养水平条件下小麦(Triticum aestivum var.Zhongyou 9507)叶片中光合膜脂含量变化的原因进行了研究。通过对生长在不同磷营养水平条件下9 d龄和16 d龄小麦叶片中光合膜脂含量的分析,发现在磷缺失培养条件下,小麦光合膜脂的相对含量发生了很大变化,这种变化与小麦叶龄密切相关。在16 d龄小麦植株中,第一片叶为老叶,第二片叶为较老叶,而第三片叶为新叶,PG和MGDG在叶片中的相对含量从新叶到老叶逐渐下降,而DGDG和SQDG含量逐渐上升;在磷缺失条件下,16 d龄小麦第一叶片中PG的含量(2.5％)远远低于其在9 d龄第一叶片中的含量(5.5％)。以上结果说明,磷缺失引起小麦叶片中脂含量的变化不仅与脂合成有关,而且与PG的降解有关;新生叶片中PG含量减少的主要原因是由于磷供应不足,从而影响了PG的合成;而PG的降解则是老叶中PG含量下降的主要原因。     

Arabidopsis ASA1 Is Important for Jasmonate-Mediated Regulation of Auxin Biosynthesis and Transport during Lateral Root Formation

Plant roots show an impressive degree of plasticity in adapting their branching patterns to ever-changing growth conditions. An important mechanism underlying this adaptation ability is the interaction between hormonal and developmental signals. Here, we analyze the interaction of jasmonate with auxin to regulate lateral root (LR) formation through characterization of an Arabidopsis thaliana mutant, jasmonate-induced defective lateral root1 (jdl1/asa1-1). We demonstrate that, whereas exogenous jasmonate promotes LR formation in wild-type plants, it represses LR formation in jdl1/asa1-1. JDL1 encodes the auxin biosynthetic gene ANTHRANILATE SYNTHASE α1 (ASA1), which is required for jasmonate-induced auxin biosynthesis. Jasmonate elevates local auxin accumulation in the basal meristem of wild-type roots but reduces local auxin accumulation in the basal meristem of mutant roots, suggesting that, in addition to activating ASA1-dependent auxin biosynthesis, jasmonate also affects auxin transport. Indeed, jasmonate modifies the expression of auxin transport genes in an ASA1-dependent manner. We further provide evidence showing that the action mechanism of jasmonate to regulate LR formation through ASA1 differs from that of ethylene. Our results highlight the importance of ASA1 in jasmonate-induced auxin biosynthesis and reveal a role for jasmonate in the attenuation of auxin transport in the root and the fine-tuning of local auxin distribution in the root basal meristem.     

Interactions of Mitochondrial Presequence Peptides with the Mitochondrial Outer Membrane Preprotein Translocase TOM

TOM protein-conducting channels serve as the main entry sites into mitochondria for virtually all mitochondrial proteins. When incorporated into lipid bilayers, they form large, relatively nonspecific ion channels that are blocked by peptides derived from mitochondrial precursor proteins. Using single-channel electrical recordings, we analyzed the interactions of mitochondrial presequence peptides with single TOM pores. The largest conductance state of the translocon represents the likely protein-conducting conformation of the channel. The frequency (but not the duration) of the polypeptide-induced blockage is strongly modulated by the substrate concentration. Structural differences between substrates are reflected in characteristic blockage frequencies and duration of blockage. To our knowledge, this study provides first quantitative data regarding the kinetics of polypeptide interaction with the mitochondrial TOM machinery.     

Role of Phosphatidylethanolamine in the Biogenesis of Mitochondrial Outer Membrane Proteins

The mitochondrial outer membrane contains proteinaceous machineries for the import and assembly of proteins, including TOM (translocase of the outer membrane) and SAM (sorting and assembly machinery). It has been shown that the dimeric phospholipid cardiolipin is required for the stability of TOM and SAM complexes and thus for the efficient import and assembly of β-barrel proteins and some α-helical proteins of the outer membrane. Here, we report that mitochondria deficient in phosphatidylethanolamine (PE), the second non-bilayer-forming phospholipid, are impaired in the biogenesis of β-barrel proteins, but not of α-helical outer membrane proteins. The stability of TOM and SAM complexes is not disturbed by the lack of PE. By dissecting the import steps of β-barrel proteins, we show that an early import stage involving translocation through the TOM complex is affected. In PE-depleted mitochondria, the TOM complex binds precursor proteins with reduced efficiency. We conclude that PE is required for the proper function of the TOM complex.     

Preprotein Translocase of the Outer Mitochondrial Membrane: Molecular Dissection and Assembly of the General Import Pore Complex

The preprotein translocase of the outer mitochondrial membrane (Tom) is a multisubunit machinery containing receptors and a general import pore (GIP). We have analyzed the molecular architecture of the Tom machinery. The receptor Tom22 stably associates with Tom40, the main component of the GIP, in a complex with a molecular weight of ~400,000 (~400K), while the other receptors, Tom20 and Tom70, are more loosely associated with this GIP complex and can be found in distinct subcomplexes. A yeast mutant lacking both Tom20 and Tom70 can still form the GIP complex when sufficient amounts of Tom22 are synthesized. Besides the essential proteins Tom22 and Tom40, the GIP complex contains three small subunits, Tom5, Tom6, and Tom7. In mutant mitochondria lacking Tom6, the interaction between Tom22 and Tom40 is destabilized, leading to the dissociation of Tom22 and the generation of a subcomplex of ~100K containing Tom40, Tom7, and Tom5. Tom6 is required to promote but not to maintain a stable association between Tom22 and Tom40. The following conclusions are suggested. (i) The GIP complex, containing Tom40, Tom22, and three small Tom proteins, forms the central unit of the outer membrane import machinery. (ii) Tom20 and Tom70 are not essential for the generation of the GIP complex. (iii) Tom6 functions as an assembly factor for Tom22, promoting its stable association with Tom40.     

An Outer Mitochondrial Translocase,Tom22, Is Crucial for Inner Mitochondrial Steroidogenic Regulation in Adrenal and Gonadal Tissues

After cholesterol is transported into the mitochondria of steroidogenic tissues, the first steroid, pregnenolone, is synthesized in adrenal and gonadal tissues to initiate steroid synthesis by catalyzing the conversion of pregnenolone to progesterone, which is mediated by the inner mitochondrial enzyme 3β-hydroxysteroid dehydrogenase 2 (3βHSD2). We report that the mitochondrial translocase Tom22 is essential for metabolic conversion, as its knockdown by small interfering RNA (siRNA) completely ablated progesterone conversion in both steroidogenic mouse Leydig MA-10 and human adrenal NCI cells. Tom22 forms a 500-kDa complex with mitochondrial proteins associated with 3βHSD2. Although the absence of Tom22 did not inhibit mitochondrial import of cytochrome P450scc (cytochrome P450 side chain cleavage enzyme) and aldosterone synthase, it did inhibit 3βHSD2 expression. Electron microscopy showed that Tom22 is localized at the outer mitochondrial membrane (OMM), while 3βHSD2 is localized at the inner mitochondrial space (IMS), where it interacts through a specific region with Tom22 with its C-terminal amino acids and a small amino acid segment of Tom22 exposed to the IMS. Therefore, Tom22 is a critical regulator of steroidogenesis, and thus, it is essential for mammalian survival.