Inhibition of caspases inhibits the release of apoptotic bodies: Bcl-2 inhibits the initiation of formation of apoptotic bodies in chemotherapeutic agent-induced apoptosis

During apoptosis, the cell actively dismantles itself and reduces cell size by the formation and pinching off of portions of cytoplasm and nucleus as "apoptotic bodies." We have combined our previously established quantitative assay relating the amount of release of [3H]-membrane lipid to the degree of apoptosis with electron microscopy (EM) at a series of timepoints to study apoptosis of lymphoid cells exposed to vincristine or etoposide. We find that the [3H]-membrane lipid release assay correlates well with EM studies showing the formation and release of apoptotic bodies and cell death, and both processes are regulated in parallel by inducers or inhibitors of apoptosis. Overexpression of Bcl-2 or inhibition of caspases by DEVD inhibited equally well the activation of caspases as indicated by PARP cleavage. They also inhibited [3H]-membrane lipid release and release of apoptotic bodies. EM showed that cells overexpressing Bcl-2 displayed near-normal morphology and viability in response to vincristine or etoposide. In contrast, DEVD did not prevent cell death. Although DEVD inhibited the chromatin condensation, PARP cleavage, release of apoptotic bodies, and release of labeled lipid, DEVD-treated cells showed accumulation of heterogeneous vesicles trapped in the condensed cytoplasm. These results suggest that inhibition of caspases arrested the maturation and release of apoptotic bodies. Our results also imply that Bcl-2 regulates processes in addition to caspase activation.     

Rhizomelic Chondrodysplasia Punctata,a Peroxisomal Biogenesis Disorder Caused by Defects in Pex7p,a Peroxisomal Protein Import Receptor: A Minireview

Rhizomelic chondrodysplasia punctata (RCDP) is a lethal autosomal recessive disease correspondingto complementation group 11 (CG 11), the second most common of the thirteen CGs of peroxisomalbiogenesis disorders (PBDs). RCDP is characterized by proximal limb shortening, severely disturbedendochondrial bone formation, and mental retardation, but there is an absence of the neuronal migrationdefect found in the other PBDs. Plasmalogen biosynthesis and phytanic acid oxidation are deficient, butvery long chain fatty acid (VLCFA) oxidation is normal. At the cellular level, RCDP is unique in thatthe biogenesis of most peroxisomal proteins is normal, but a specific subset of at least four, and maybemore, peroxisomal matrix proteins fail to be imported from the cytosol. In this review, we discuss recentadvances in understanding RCDP, most prominently the cloning of the affected gene, PEX7,and identification of PEX7 mutations in RCDP patients. Human PEX7 wasidentified by virtue of its sequence similarity to its Saccharomyces cerevisiae ortholog, whichhad previously been shown to encode Pex7p, an import receptor for type 2 peroxisomal targetingsequences (PTS2). Normal human PEX7 expression rescues the cellular defects in culturedRCDP cells, and cDNA sequence analysis has identified a variety of PEX7 mutations in RCDP patients,including a deletion of 100 nucleotides, probably due to a splice site mutation, and a prevalent nonsensemutation which results in loss of the carboxyterminal 32 amino acids. Identification of RCDP as a PTS2import disorder explains the observation that several, but not all, peroxisomal matrix proteins aremistargeted in this disease; three of the four proteins deficient in RCDP have now been shown to bePTS2-targeted.     

Evolutionary pressures on apicoplast transit peptides

Malaria parasites (species of the genus Plasmodium) harbor a relict chloroplast (the apicoplast) that is the target of novel antimalarials. Numerous nuclear-encoded proteins are translocated into the apicoplast courtesy of a bipartite N-terminal extension. The first component of the bipartite leader resembles a standard signal peptide present at the N-terminus of secreted proteins that enter the endomembrane system. Analysis of the second portion of the bipartite leaders of P. falciparum, the so-called transit peptide, indicates similarities to plant transit peptides, although the amino acid composition of P. falciparum transit peptides shows a strong bias, which we rationalize by the extraordinarily high AT content of P. falciparum DNA. 786 plastid transit peptides were also examined from several other apicomplexan parasites, as well as from angiosperm plants. In each case, amino acid biases were correlated with nucleotide AT content. A comparison of a spectrum of organisms containing primary and secondary plastids also revealed features unique to secondary plastid transit peptides. These unusual features are explained in the context of secondary plastid trafficking via the endomembrane system.     

The chloroplastic protein translocation channel Toc75 and its paralog OEP80 represent two distinct protein families and are targeted to the chloroplastic outer envelope by different mechanisms

Toc75 is postulated to form the protein translocation channel in the chloroplastic outer envelope membrane. Proteins homologous to Toc75 are present in a wide range of organisms, with the closest homologs occurring in cyanobacteria. Therefore, an endosymbiotic origin of Toc75 has been postulated. Recently, a gene encoding a paralog to Toc75 was identified in Arabidopsis and its product was named atToc75-V. In the present study, we characterized this new Toc75 paralog, and investigated extensively the relationships among Toc75 homologs from higher plants and bacteria in order to gain insights into the evolutionary origin of the chloroplastic protein translocation channel. First, we found that the native molecular weight of atToc75-V is 80 kDa and renamed it (AtOEP80) Arabidopsis thalianaouter envelope protein of 80 kDa. Second, we found that AtOEP80 and Toc75 utilize different mechanisms for their targeting to the chloroplastic envelope. Toc75 is directed with a cleavable bipartite transit peptide partly via the general import pathway, whereas AtOEP80 contains the targeting information within its mature sequence, and its targeting is independent of the general pathway. Third, we undertook phylogenetic analyses of Toc75 homologs from various organisms, and found that Toc75 and OEP80 represent two independent gene families that are most likely derived from cyanobacterial sequences. Our results suggest that Toc75 and OEP80 diverged early in the evolution of plastids from their common ancestor with modern cyanobacteria.     

Phosphoinositide-specific phospholipase C is involved in cytokinin and gravity responses in the moss Physcomitrella patens

The phosphoinositide signalling pathway is important in plant responses to extracellular and intracellular signals. To elucidate the physiological functions of phosphoinositide-specific phopspholipase C, PI-PLC, targeted knockout mutants of PpPLC1, a gene encoding a PI-PLC from the moss Physcomitrella patens, were generated via homologous recombination. Protonemal filaments of the plc1 lines show a dramatic reduction in gametophore formation relative to wild type: this was accompanied by a loss of sensitivity to cytokinin. Moreover, plc1 appeared paler than the wild type, the result of an altered differentiation of chloroplasts and reduced chlorophyll levels compared with wild type filaments. In addition, the protonemal filaments of plc1 have a strongly reduced ability to grow negatively gravitropically in the dark. These effects imply a significant role for PpPLC1 in cytokinin signalling and gravitropism.     

A large-scale<Emphasis Type="Italic"> Agrobacterium</Emphasis>-mediated transformation procedure with a strong positive-negative selection for gene targeting in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

A large-scale transformation procedure handling an adequate number of stable transformants with highly efficient positive-negative selection is a necessary prerequisite to successful gene targeting by homologous recombination, as the integration of a transgene by somatic homologous recombination in higher plants has been reported to be 10^-3 to 10^-5 compared with random integration by non-homologous end joining. We established an efficient and large-scale Agrobacterium-mediated rice transformation protocol that generated around 10³ stable transformants routinely from 150 seeds and a strong positive-negative selection procedure that resulted in survivors at 10^-2 using the gene for diphtheria toxin A fragment as a negative marker. The established transformation procedure provides a basis for efficient gene targeting in rice.Abbreviations AS: Acetosyringone - 5-FU: 5-Fluorouracil - FW: Fresh weight - GT: Gene targeting - HR: Homologous recombination - NHEJ: Non-homologous end joining Communicated by H. Ebinuma     

Wound-healing studies in transgenic and knockout mice

Injury to the skin initiates a cascade of events including inflammation, new tissue formation, and tissue remodeling, that finally lead to at least partial reconstruction of the original tissue. Historically, animal models of repair have taught us much about how this repair process is orchestrated and, over recent years, the use of genetically modified mice has helped define the roles of many key molecules. Aside from conventional knockout technology, many ingenious approaches have been adopted, allowing researchers to circumvent such problems as embryonic lethality, or to affect gene function in a tissue-or temporal-specific manner. Together, these studies provide us with a growing source of information describing, to date, the in vivo function of nearly 100 proteins in the context of wound repair. This article focuses on the studies in which genetically modified mouse models have helped elucidate the roles that many soluble mediators play during wound repair, encompassing the fibroblast growth factor (FGF) and transforming growth factor-β (TGF-β) families and also data on cytokines and chemokines. Finally, we include a table summarizing all of the currently published data in this rapidly growing field. For a regularly updated web archive of studies, we have constructed a Compendium of Published Wound Healing Studies on Genetically Modified Mice which is available at http://icbxs.ethz.ch/members/grose/woundtransgenic/home.html.     

Regulation of AMPA Receptor Activity, Synaptic Targeting and Recycling: Role in Synaptic Plasticity

The alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors for the neurotransmitter glutamate are oligomeric structures responsible for most fast excitatory responses in the central nervous system. The activity of AMPA receptors can be directly regulated by protein phosphorylation, which may also affect the interaction with intracellular proteins and, consequently, their recycling and localization to defined postsynaptic sites. This review focuses on recent advances in understanding the dynamic regulation of AMPA receptors, on a short- and long-term basis, and its implications in synaptic plasticity.     

Expression of an RNase P ribozyme against the mRNA encoding human cytomegalovirus protease inhibits viral capsid protein processing and growth

A sequence-specific ribozyme (M1GS RNA) derived from the catalytic RNA subunit of RNase P from Escherichia coli was used to target the mRNA encoding human cytomegalovirus (HCMV) protease (PR), a viral protein that is responsible for the processing of the viral capsid assembly protein. We showed that the constructed ribozyme cleaved the PR mRNA sequence efficiently in vitro. Moreover, a reduction of about 80% in the expression level of the protease and a reduction of about 100-fold in HCMV growth were observed in cells that expressed the ribozyme stably. In contrast, a reduction of less than 10% in the expression of viral protease and viral growth was observed in cells that either did not express the ribozyme or produced a catalytically inactive ribozyme mutant. Further examination of the antiviral effects of the ribozyme-mediated cleavage of PR mRNA indicates that (1) the proteolytic cleavage of the capsid assembly protein is inhibited significantly, and (2) the packaging of the viral genomic DNA into the CMV capsids is blocked. These observations are consistent with the notion that the protease functions to process the capsid assembly protein and is essential for viral capsid assembly. Moreover, our results indicate that the RNase P ribozyme-mediated cleavage specifically reduces the expression of the protease, but not other viral genes examined. Thus, M1GS ribozyme is highly effective in inhibiting HCMV growth by targeting the PR mRNA and may represent a novel class of general gene-targeting agents for the studies and treatment of infections caused by human viruses, including HCMV.     

AIP is a mitochondrial import mediator that binds to both import receptor Tom20 and preproteins

Most mitochondrial preproteins are maintained in a loosely folded import-competent conformation by cytosolic chaperones, and are imported into mitochondria by translocator complexes containing a preprotein receptor, termed translocase of the outer membrane of mitochondria (Tom) 20. Using two-hybrid screening, we identified arylhydrocarbon receptor-interacting protein (AIP), an FK506-binding protein homologue, interacting with Tom20. The extreme COOH-terminal acidic segment of Tom20 was required for interaction with tetratricopeptide repeats of AIP. An in vitro import assay indicated that AIP prevents preornithine transcarbamylase from the loss of import competency. In cultured cells, overexpression of AIP enhanced preornithine transcarbamylase import, and depletion of AIP by RNA interference impaired the import. An in vitro binding assay revealed that AIP specifically binds to mitochondrial preproteins. Formation of a ternary complex of Tom20, AIP, and preprotein was observed. Hsc70 was also found to bind to AIP. An aggregation suppression assay indicated that AIP has a chaperone-like activity to prevent substrate proteins from aggregation. These results suggest that AIP functions as a cytosolic factor that mediates preprotein import into mitochondria.