Evolution of mitochondrial protein biogenesis

Mitochondria and the nucleus are key features that distinguish eukaryotic cells from prokaryotic cells. Mitochondria originated from a bacterium that was endosymbiotically taken up by another cell more than a billion years ago. Subsequently, most mitochondrial genes were transferred and integrated into the host cell's genome, making the evolution of pathways for specific import of mitochondrial proteins necessary. The mitochondrial protein translocation machineries are composed of numerous subunits. Interestingly, many of these subunits are at least in part derived from bacterial proteins, although only few of them functioned in bacterial protein translocation. We propose that the primitive α-proteobacterium, which was once taken up by the eukaryote ancestor cell, contained a number of components that were utilized for the generation of mitochondrial import machineries. Many bacterial components of seemingly unrelated pathways were integrated to form the modern cooperative mitochondria-specific protein translocation system.     

IRREGULAR TRICHOME BRANCH 2 (ITB2) encodes a putative aminophospholipid translocase that regulates trichome branch elongation in Arabidopsis

The P4 ATPase family in Arabidopsis consists of 12 members that encode putative aminophospholipid translocases (ALA1–12). Until recently, no mutations in these genes have been shown to cause a visible phenotype, although reduced expression of ALA1 in transgenic plants expressing an antisense construct has been shown to result in reduced plant size when plants were grown under cold conditions. During a genetic screen for mutations that affect trichome shape, we isolated several alleles of the irregular trichome branch 2 ( itb2 ) mutation. Subsequent positional cloning of this locus showed that ITB2 encoded ALA3 . Phenotypic and genetic analyses of multiple itb2 alleles, including the T-DNA insertion alleles, showed that the loss of ITB2 / ALA3 function leads to aberrant trichome expansion, reduced primary root growth and longer root hairs. We also found that itb2 / ala3 mutant pollen does not grow as well as wild-type pollen, leading to severe segregation distortion. Our results suggest that aminophospholipid translocases play an important role in the polar growth of plant cells, which is consistent with the proposed role of ALA3 in membrane trafficking. Furthermore, itb2 / ala3 mutants provide a convenient visible phenotype for further genetic analysis of the ALA family in Arabidopsis.     

The mitochondrial TOM complex modulates bax-induced apoptosis in Drosophila

Bax is a pro-apoptotic member of the Bcl-2 family proteins involved in the release of apoptogenic factors from mitochondria to the cytosol. Recently, it has been shown both in mammals and yeast that Bax insertion in the mitochondrial outer membrane involves at least two distinct mechanisms, one of which uses the TOM complex. Here, we show that in Drosophila, heterozygous loss of function mutations of Tom22 or Tom70, two receptors of the TOM complex, attenuates bax-induced phenotypes in vivo. These results argue that the TOM complex may be used as a mitochondrial Bax receptor in Drosophila.     

Switch from inhibition to activation of the mitochondrial permeability transition during hematoporphyrin-mediated photooxidative stress.: Unmasking pore-regulating external thiols

We have studied the mitochondrial permeability transition pore (PTP) under oxidizing conditions with mitochondria-bound hematoporphyrin, which generates reactive oxygen species (mainly singlet oxygen, ¹O₂) upon UV/visible light-irradiation and promotes the photooxidative modification of vicinal targets. We have characterized the PTP-modulating properties of two major critical sites endowed with different degrees of photosensitivity: (i) the most photovulnerable site comprises critical histidines, whose photomodification by vicinal hematoporphyrin causes a drop in reactivity of matrix-exposed (internal), PTP-regulating cysteines thus stabilizing the pore in a closed conformation; (ii) the most photoresistant site coincides with the binding domains of (external) cysteines sensitive to membrane-impermeant reagents, which are easily unmasked when oxidation of internal cysteines is prevented. Photooxidation of external cysteines promoted by vicinal hematoporphyrin reactivates the PTP after the block caused by histidine photodegradation. Thus, hematoporphyrin-mediated photooxidative stress can either inhibit or activate the mitochondrial permeability transition depending on the site of hematoporphyrin localization and on the nature of the substrate; and selective photomodification of different hematoporphyrin-containing pore domains can be achieved by fine regulation of the sensitizer/light doses. These findings shed new light on PTP modulation by oxidative stress.     

The flavonoid quercetin induces changes in mitochondrial permeability by inhibiting adenine nucleotide translocase

This study shows the effects of the flavonoid quercetin on diverse mitochondrial functions, among them membrane permeability. Our findings indicate that the addition of 50 μM quercetin did not produce reactive oxygen derived species; however, it inhibited the oxidative stress induced after the addition of Fe²/H₂O₂ by about 38%. At this concentration, quercetin also promoted a fast calcium release, inhibited oxidative phosphorylation, stimulated oxygen consumption, and decreased membrane potential. In addition 50 μM quercetin inhibited the adenine nucleotide translocase (ANT) by 46%. These effects induced the opening of the permeability transition pore and release of cytochrome c, by its interaction with a component of the non-specific pore complex, fixed to the carrier in the conformation c, as carboxyatractyloside does. Quercetin-induced permeability transition pore opening was inhibited by 0.5 μM cyclosporin A, but, interestingly, the release of cytochrome c was not inhibited by the immunosuppressor, as quercetin was found to disrupt the outer membrane.     

GD3-7-aldehyde is an apoptosis inducer and interacts with adenine nucleotide translocase

We prepared GD3-7-aldehyde (GD3-7) and determined its apoptotic potential. GD3-7 proved to be more efficient to induce pro-apoptotic mitochondrial alterations than GD3 when tested on mouse liver mitochondria. GD3-7-induced mitochondrial swelling and depolarization was blocked by cyclosporin A (CsA) supporting a critical role of the permeability transition pore complex (PTPC) during GD3-7-mediated apoptosis. In contrast to GD3, GD3-7 was able to induce channel formation in proteoliposomes containing adenine nucleotide translocase (ANT). This suggests that ANT is the molecular target of GD3-7. Using a specific antiserum, GD3-7 was detected in the lipid extract of the myeloid tumor cell line HL-60 after apoptosis induction, but not in living cells. Therefore, GD3-7 might be a novel mediator of PTPC-dependent apoptosis in cancer cells.     

Two Modular Forms of the Mitochondrial Sorting and Assembly Machinery Are Involved in Biogenesis of α-Helical Outer Membrane Proteins

The mitochondrial outer membrane contains two translocase machineries for precursor proteins—the translocase of the outer membrane (TOM complex) and the sorting and assembly machinery (SAM complex). The TOM complex functions as the main mitochondrial entry gate for nuclear-encoded proteins, whereas the SAM complex was identified according to its function in the biogenesis of β-barrel proteins of the outer membrane. The SAM complex is required for the assembly of precursors of the TOM complex, including not only the β-barrel protein Tom40 but also a subset of α-helical subunits. While the interaction of β-barrel proteins with the SAM complex has been studied in detail, little is known about the interaction between the SAM complex and α-helical precursor proteins. We report that the SAM is not static but that the SAM core complex can associate with different partner proteins to form two large SAM complexes with different functions in the biogenesis of α-helical Tom proteins. We found that a subcomplex of TOM, Tom5-Tom40, associates with the SAM core complex to form a new large SAM complex. This SAM-Tom5/Tom40 complex binds the α-helical precursor of Tom6 after the precursor has been inserted into the outer membrane in an Mim1 (mitochondrial import protein 1)-dependent manner. The second large SAM complex, SAM-Mdm10 (mitochondrial distribution and morphology protein), binds the α-helical precursor of Tom22 and promotes its membrane integration. We suggest that the modular composition of the SAM complex provides a flexible platform to integrate the sorting pathways of different precursor proteins and to promote their assembly into oligomeric complexes.     

分枝杆菌分泌系统

分泌系统对于具有特殊细胞被膜结构的分枝杆菌,尤其是致病性分枝杆菌的存活和毒力非常重要.不少重要的致病因子或存活因子都通过特定的分泌系统进入环境,包括宿主体内.本文从分泌系统的基因、结构组成、分泌底物、转运机制及其与致病菌毒力的关系等几个方面介绍了分枝杆菌(mycobacteria)通用型分泌系统(general secretion pathway,SecA1)、替代型分泌系统(accessory Sec system,SecA2)、双精氨酸分泌系统(twin-arginine translocation,Tat)和Ⅶ型分泌系统(typeⅦsecretion systems,T7S system or ESX)4种分泌系统,并重点分析了Tat分泌系统.这些知识有利于从分泌系统及其底物的角度揭示结核分枝杆菌等胞内致病菌存活和逃避宿主免疫的机理,将为研发新的结核病控制措施提供依据.