Metal catalyzed oxidation of alpha-synuclein--a role for oligomerization in pathology?

A number of studies have demonstrated a role for transition metals and oxidative stress in the etiology of Parkinson's disease (PD). Genetic and biochemical evidence also clearly links the protein alpha-synuclein (alphaSyn) to PD and a number of associated diseases. In these "synucleinopathies", alphaSyn is deposited, often in oligomerized forms, as cytoplasmic inclusions known as Lewy bodies and Lewy neurites. alphaSyn cross-linking/oligomerization can occur via a number of processes, most stimulated by metal catalyzed oxidation (MCO). In PD, the increased sensitivity of midbrain neurons expressing high levels of oxidizable catecholamines may provide one clue to account for degeneration of these neurons. In other regions of the nervous system that develop Lewy body pathology, the mode of alphaSyn oligomerization is less clear. Thus, the relationship between alphaSyn and MCO, either direct or indirect, represents a particular concern for possible treatment of these various diseases.

Dynamics and retention of misfolded proteins in native ER membranes.

When co-translationally inserted into endoplasmic reticulum (ER) membranes, newly synthesized proteins encounter the lumenal environment of the ER, which contains chaperone proteins that facilitate the folding reactions necessary for protein oligomerization, maturation and export from the ER. Here we show, using a temperature-sensitive variant of vesicular stomatitis virus G protein tagged with green fluorescent protein (VSVG-GFP), and fluorescence recovery after photobleaching (FRAP), the dynamics of association of folded and misfolded VSVG complexes with ER chaperones. We also investigate the potential mechanisms underlying protein retention in the ER. Misfolded VSVG-GFP complexes at 40 degrees C are highly mobile in ER membranes and do not reside in post-ER compartments, indicating that they are not retained in the ER by immobilization or retrieval mechanisms. These complexes are immobilized in ATP-depleted or tunicamycin-treated cells, in which VSVG-chaperone interactions are no longer dynamic. These results provide insight into the mechanisms of protein retention in the ER and the dynamics of protein-folding complexes in native ER membranes.

Phospholipase A2 antagonists inhibit constitutive retrograde membrane traffic to the endoplasmic reticulum.

Eukaryotic cells contain a variety of cytoplasmic Ca(2+)-dependent and Ca(2+)-independent phospholipase A2s (PLA2s; EC 2.3.1.2.3). However, the physiological roles for many of these ubiquitously-expressed enzymes is unclear or not known. Recently, pharmacological studies have suggested a role for Ca(2+)-independent PLA2 (iPLA2) enzymes in governing intracellular membrane trafficking events in general and regulating brefeldin A (BFA)-stimulated membrane tubulation and Golgi-to-endoplasmic reticulum (ER) retrograde membrane trafficking, in particular. Here, we extend these studies to show that membrane-permeant iPLA2 antagonists potently inhibit the normal, constitutive retrograde membrane trafficking from the trans-Golgi network (TGN), Golgi complex, and the ERGIC-53-positive ER-Golgi-intermediate compartment (ERGIC), which occurs in the absence of BFA. Taken together, these results suggest that iPLA2 enzymes play a general role in regulating, or directly mediating, multiple mammalian membrane trafficking events.

Golgi membranes are absorbed into and reemerge from the ER during mitosis.

Quantitative imaging and photobleaching were used to measure ER/Golgi recycling of GFP-tagged Golgi proteins in interphase cells and to monitor the dissolution and reformation of the Golgi during mitosis. In interphase, recycling occurred every 1.5 hr, and blocking ER egress trapped cycling Golgi enzymes in the ER with loss of Golgi structure. In mitosis, when ER export stops, Golgi proteins redistributed into the ER as shown by quantitative imaging in vivo and immuno-EM. Comparison of the mobilities of Golgi proteins and lipids ruled out the persistence of a separate mitotic Golgi vesicle population and supported the idea that all Golgi components are absorbed into the ER. Moreover, reassembly of the Golgi complex after mitosis failed to occur when ER export was blocked. These results demonstrate that in mitosis the Golgi disperses and reforms through the intermediary of the ER, exploiting constitutive recycling pathways. They thus define a novel paradigm for Golgi genesis and inheritance.

Brain-derived neurotrophic factor mediates estradiol-induced dendritic spine formation in hippocampal neurons.

Dendritic spines are of major importance in information processing and memory formation in central neurons. Estradiol has been shown to induce an increase of dendritic spine density on hippocampal neurons in vivo and in vitro. The neurotrophin brain-derived neurotrophic factor (BDNF) recently has been implicated in neuronal maturation, plasticity, and regulation of GABAergic interneurons. We now demonstrate that estradiol down-regulates BDNF in cultured hippocampal neurons to 40% of control values within 24 hr of exposure. This, in turn, decreases inhibition and increases excitatory tone in pyramidal neurons, leading to a 2-fold increase in dendritic spine density. Exogenous BDNF blocks the effects of estradiol on spine formation, and BDNF depletion with a selective antisense oligonucleotide mimics the effects of estradiol. Addition of BDNF antibodies also increases spine density, and diazepam, which facilitates GABAergic neurotransmission, blocks estradiol-induced spine formation. These observations demonstrate a functional link between estradiol, BDNF as a potent regulator of GABAergic interneurons, and activity-dependent formation of dendritic spines in hippocampal neurons.

Building a secretory apparatus: role of ARF1/COPI in Golgi biogenesis and maintenance.

The secretory apparatus within all eukaryotic cells comprises a dynamic membrane system with bidirectional membrane transport pathways and overlapping compartmental boundaries. Membrane traffic and organelle biogenesis/maintenance are fundamentally linked within this system, with perturbations in membrane traffic quickly leading to changes in organelle structure and identity. Dissection of the molecular basis of these properties in yeast and mammalian cells has revealed a crucial role for the cytoplasmic protein complex ARF1/COPI, which undergoes regulated assembly and disassembly with membranes. ARF1/COPI appears to be involved in the formation and maintenance of the Golgi complex, which is the receiving and delivery station for all secretory traffic. ARF1-GTP, through assembly of COPI to membranes and, possibly, through activation of PLD, is likely to promote the formation and maturation of pre-Golgi intermediates into Golgi elements, whereas ARF-GDP causes COPI dissociation and stimulates the formation of retrograde transport structures that recycle Golgi membrane back to the ER. These processes are appear to underlie the coupling of organelle biogenesis and membrane trafficking within cells, allowing the size and shape of secretory organelles to be altered in response to changing cellular needs. Future work needs to address how the activation and localization of ARF1/COPI to membranes as well as other related factors are temporally and spatially regulated, and by what mechanism they transform membrane shape and dynamics to facilitate protein transport and compartmental functioning.

Estradiol increases dendritic spine density by reducing GABA neurotransmission in hippocampal neurons.

We have previously shown that estradiol causes a twofold rise in dendritic spine density in cultured rat hippocampal neurons, as it does in vivo. More recently, estrogen receptors have been localized to aspiny inhibitory hippocampal interneurons, indicating that their effect on spiny pyramidal neurons may be indirect. We therefore examined the possibility that estradiol affects spine density by regulating inhibition in cultured hippocampal interneurons. Immunocytochemically, estrogen receptors were found to be co-localized with glutamate decarboxylase (GAD)-positive neurons (approximately 21% of total neurons in the culture). Exposure of cultures to estradiol for 1 d caused a marked decrease (up to 80%) in the GAD content of the interneurons, measured both by immunohistochemistry and Western blotting. Also, the number of GAD-positive neurons in the cultures decreased to 12% of the total cell population. Moreover, GABAergic miniature IPSCs were reduced in both size and frequency by estradiol, whereas miniature EPSCs increased in frequency. We then mimicked the proposed effects of estradiol by blocking GABA synthesis with mercaptopropionic acid (MA). Cultures treated with MA expressed a dose-dependent decrease in GABA immunostaining that mimicked that seen with estradiol. MA-treated cultures displayed a significant 50% increase in dendritic spine density over controls, similar to that produced by estradiol. These results indicate that estradiol decreases GABAergic inhibition in the hippocampus, which appears to effectively increase the excitatory drive on pyramidal cells, and thus may provide a mechanism for formation of new dendritic spines.

Retrograde transport of Golgi-localized proteins to the ER.

The ER is uniquely enriched in chaperones and folding enzymes that facilitate folding and unfolding reactions and ensure that only correctly folded and assembled proteins leave this compartment. Here we address the extent to which proteins that leave the ER and localize to distal sites in the secretory pathway are able to return to the ER folding environment during their lifetime. Retrieval of proteins back to the ER was studied using an assay based on the capacity of the ER to retain misfolded proteins. The lumenal domain of the temperature-sensitive viral glycoprotein VSVGtsO45 was fused to Golgi or plasma membrane targeting domains. At the nonpermissive temperature, newly synthesized fusion proteins misfolded and were retained in the ER, indicating the VSVGtsO45 ectodomain was sufficient for their retention within the ER. At the permissive temperature, the fusion proteins were correctly delivered to the Golgi complex or plasma membrane, indicating the lumenal epitope of VSVGtsO45 also did not interfere with proper targeting of these molecules. Strikingly, Golgi-localized fusion proteins, but not VSVGtsO45 itself, were found to redistribute back to the ER upon a shift to the nonpermissive temperature, where they misfolded and were retained. This occurred over a time period of 15 min-2 h depending on the chimera, and did not require new protein synthesis. Significantly, recycling did not appear to be induced by misfolding of the chimeras within the Golgi complex. This suggested these proteins normally cycle between the Golgi and ER, and while passing through the ER at 40 degrees C become misfolded and retained. The attachment of the thermosensitive VSVGtsO45 lumenal domain to proteins promises to be a useful tool for studying the molecular mechanisms and specificity of retrograde traffic to the ER.

ER-to-Golgi transport visualized in living cells.

Newly synthesized proteins that leave the endoplasmic reticulum (ER) are funnelled through the Golgi complex before being sorted for transport to their different final destinations. Traditional approaches have elucidated the biochemical requirements for such transport and have established a role for transport intermediates. New techniques for tagging proteins fluorescently have made it possible to follow the complete life history of single transport intermediates in living cells, including their formation, path and velocity en route to the Golgi complex. We have now visualized ER-to-Golgi transport using the viral glycoprotein ts045 VSVG tagged with green fluorescent protein (VSVG-GFP). Upon export from the ER, VSVG-GFP became concentrated in many differently shaped, rapidly forming pre-Golgi structures, which translocated inwards towards the Golgi complex along microtubules by using the microtubule minus-end-directed motor complex of dynein/dynactin. No loss of fluorescent material from pre-Golgi structures occurred during their translocation to the Golgi complex and they frequently stretched into tubular shapes. Together, our results indicate that these pre-Golgi carrier structures moving unidirectionally along microtubule tracks are responsible for transporting VSVG-GFP through the cytoplasm to the Golgi complex. This contrasts with the traditional focus on small vesicles as the primary vehicles for ER-to-Golgi transport.

Saccharomyces cerevisiae genes required in the absence of the CIN8-encoded spindle motor act in functionally diverse mitotic pathways.

Kinesin-related Cin8p is the most important spindle-pole-separating motor in Saccharomyces cerevisiae but is not essential for cell viability. We identified 20 genes whose products are specifically required by cell deficient for Cin8p. All are associated with mitotic roles and represent at least four different functional pathways. These include genes whose products act in two spindle motor pathways that overlap in function with Cin8p, the kinesin-related Kip1p pathway and the cytoplasmic dynein pathway. In addition, genes required for mitotic spindle checkpoint function and for normal microtubule stability were recovered. Mutant alleles of eight genes caused phenotypes similar to dyn1 (encodes the dynein heavy chain), including a spindle-positioning defect. We provide evidence that the products of these genes function in concept with dynein. Among the dynein pathway gene products, we found homologues of the cytoplasmic dynein intermediate chain, the p150Glued subunit of the dynactin complex, and human LIS-1, required for normal brain development. These findings illustrate the complex cellular interactions exhibited by Cin8p, a member of a conserved spindle motor family.

Diffusional mobility of Golgi proteins in membranes of living cells.

The mechanism by which Golgi membrane proteins are retained within the Golgi complex in the midst of a continuous flow of protein and lipid is not yet understood. The diffusional mobilities of mammalian Golgi membrane proteins fused with green fluorescent protein from Aequorea victoria were measured in living HeLa cells with the fluorescence photobleaching recovery technique. The diffusion coefficients ranged from 3 x 10(-9) square centimeters per second to 5 x 10(-9) square centimeters per second, with greater than 90 percent of the chimeric proteins mobile. Extensive lateral diffusion of the chimeric proteins occurred between Golgi stacks. Thus, the chimeras diffuse rapidly and freely in Golgi membranes, which suggests that Golgi targeting and retention of these molecules does not depend on protein immobilization.

Golgi dispersal during microtubule disruption: regeneration of Golgi stacks at peripheral endoplasmic reticulum exit sites.

Microtubule disruption has dramatic effects on the normal centrosomal localization of the Golgi complex, with Golgi elements remaining as competent functional units but undergoing a reversible "fragmentation" and dispersal throughout the cytoplasm. In this study we have analyzed this process using digital fluorescence image processing microscopy combined with biochemical and ultrastructural approaches. After microtubule depolymerization, Golgi membrane components were found to redistribute to a distinct number of peripheral sites that were not randomly distributed, but corresponded to sites of protein exit from the ER. Whereas Golgi enzymes redistributed gradually over several hours to these peripheral sites, ERGIC-53 (a protein which constitutively cycles between the ER and Golgi) redistributed rapidly (within 15 minutes) to these sites after first moving through the ER. Prior to this redistribution, Golgi enzyme processing of proteins exported from the ER was inhibited and only returned to normal levels after Golgi enzymes redistributed to peripheral ER exit sites where Golgi stacks were regenerated. Experiments examining the effects of microtubule disruption on the membrane pathways connecting the ER and Golgi suggested their potential role in the dispersal process. Whereas clustering of peripheral pre-Golgi elements into the centrosomal region failed to occur after microtubule disruption, Golgi-to-ER membrane recycling was only slightly inhibited. Moreover, conditions that impeded Golgi-to-ER recycling completely blocked Golgi fragmentation. Based on these findings we propose that a slow but constitutive flux of Golgi resident proteins through the same ER/Golgi cycling pathways as ERGIC-53 underlies Golgi Dispersal upon microtubule depolymerization. Both ERGIC-53 and Golgi proteins would accumulate at peripheral ER exit sites due to failure of membranes at these sites to cluster into the centrosomal region. Regeneration of Golgi stacks at these peripheral sites would re-establish secretory flow from the ER into the Golgi complex and result in Golgi dispersal.

Organization of organelles and membrane traffic by microtubules.

Organelles of the central membrane system of higher eukaryotes have been shown to utilize microtubules both for maintenance of their characteristic spatial distributions and for efficient transport of their protein and lipid to diverse sites within the cell. Recent work addressing the mechanisms that underlie this organization provides new insights regarding the roles of microtubules and microtubule motors in influencing organelle dynamics and specific membrane traffic routes through the cytoplasm.

Kinesin is the motor for microtubule-mediated Golgi-to-ER membrane traffic.

The distribution and dynamics of both the ER and Golgi complex in animal cells are known to be dependent on microtubules; in many cell types the ER extends toward the plus ends of microtubules at the cell periphery and the Golgi clusters at the minus ends of microtubules near the centrosome. In this study we provide evidence that the microtubule motor, kinesin, is present on membranes cycling between the ER and Golgi and powers peripherally directed movements of membrane within this system. Immunolocalization of kinesin at both the light and electron microscopy levels in NRK cells using the H1 monoclonal antibody to kinesin heavy chain, revealed kinesin to be associated with all membranes of the ER/Golgi system. At steady-state at 37 degrees C, however, kinesin was most concentrated on peripherally distributed, pre-Golgi structures containing beta COP and vesicular stomatitis virus glycoprotein newly released from the ER. Upon temperature reduction or nocodazole treatment, kinesin's distribution shifted onto the Golgi, while with brefeldin A (BFA)-treatment, kinesin could be found in both Golgi-derived tubules and in the ER. This suggested that kinesin associates with membranes that constitutively cycle between the ER and Golgi. Kinesin's role on these membranes was examined by microinjecting kinesin antibody. Golgi-to-ER but not ER-to-Golgi membrane transport was found to be inhibited by the microinjected anti-kinesin, suggesting kinesin powers the microtubule plus end-directed recycling of membrane to the ER, and remains inactive on pre-Golgi intermediates that move toward the Golgi complex.

Vaccinia virus expresses a novel profilin with a higher affinity for polyphosphoinositides than actin.

We expressed in Escherichia coli the vaccinia virus gene for a protein similar to vertebrate profilins, purified the recombinant viral profilin, and characterized its interactions with actin and polyphosphoinositides. Compared with cellular profilins, this viral profilin has a low affinity (Kd > or = 35 microM) for human platelet actin monomers, a weak effect on the exchange of the nucleotide bound to the actin, and no detectable affinity for poly(L-proline). Vaccinia profilin binds to phosphatidylinositol 4,5-bisphosphate and phosphatidylinositol 4-monophosphate in micelles and large unilamellar vesicles, but not to phosphatidylserine or phosphatidylcholine. Kinetic analysis by surface plasmon resonance showed that both vaccinia and amoeba profilins bind slowly to polyphosphoinositides, with association rate constants in the range of (1-4) x 10(4) M-1 s-1. The higher affinity of vaccinia profilin for polyphosphoinositides (Kd = 0.2-8.5 microM) than for actin or poly(L-proline) and the concentration of vaccinia profilin expressed in infected HeLa cells (approximately 20 microM) suggest that vaccinia profilin binds preferentially to PIP and PIP2 in vivo. Consequently, vaccinia profilin is more likely to influence phosphoinositide metabolism than actin assembly. Expression of 7-105 microM vaccinia profilin in a Saccharomyces cerevisiae profilin null mutant did not rescue the null phenotype, so that the affinity of vaccinia profilin for phosphoinositides alone is insufficient for normal profilin function in yeast.

Identification and expression of rpo19, a vaccinia virus gene encoding a 19-kilodalton DNA-dependent RNA polymerase subunit.

The vaccinia virus DNA-dependent RNA polymerase subunit gene rpo19 was identified, and its expression was examined at RNA and protein levels. Antibody to the multisubunit RNA polymerase purified from virions reacted with a polypeptide with an apparent Mr of 21,000 that was synthesized in reticulocyte lysates programmed with (i) mRNA from infected cells that was isolated by hybridization to DNA subclones of the viral genomic HindIII A fragment and (ii) mRNA made in vitro by transcription of the viral open reading frame A6R. Polyclonal antiserum, raised to a recombinant protein product of the A6R open reading frame which could encode an 18,996-Da protein with an acidic N terminus, reacted with Mr-21,000 and -22,000 polypeptides that cosedimented with purified RNA polymerase. Internal sequencing of the two polypeptides confirmed that both were encoded by A6R, and the gene was named rpo19 to indicate the predicted molecular mass of the polypeptide in kilodaltons. Immunoblotting and metabolic labeling of infected cell proteins indicated that synthesis of the Mr-21,000 polypeptide started early and continued throughout virus infection, whereas the Mr-22,000 form appeared late following DNA replication. RNA analyses suggested that the rpo19 mRNA was expressed from a dual early/late promoter and that the protein-coding region of the mRNA was directly preceded by a short 5' poly(A) leader, apparently initiated within the TAAATG motif at the beginning of the open reading frame.

Sequence analysis, expression, and deletion of a vaccinia virus gene encoding a homolog of profilin, a eukaryotic actin-binding protein.

A 4,500-bp BamHI fragment, located within the HindIII A segment of the vaccinia virus genome, was found to contain eight potential coding regions for polypeptides of 78 to 346 amino acids. The open reading frames with 133, 346, and 125 codons were homologous to profilin (an actin-binding protein), 3-beta-hydroxysteroid dehydrogenase, and Cu-Zn superoxide dismutase, respectively. Sequence alignments indicated that the vaccinia virus and mammalian profilins were more closely related to each other than to known profilins of other eukaryotes. The expression and possible role of the profilin homolog in the virus replicative cycle were therefore investigated. Antibody raised to Escherichia coli expressed vaccinia virus profilin was used to demonstrate the synthesis of the 15-kDa polypeptide at late times after vaccinia virus infection of mammalian cells. The protein accumulated in the cytoplasm, but only trace amounts remained associated with highly purified virions. The isolation of vaccinia virus mutants (in strains WR and IHD-J), with nearly the entire profilin gene replaced by the E. coli gpt gene, indicated that the protein is not essential for infectivity. The characteristic vaccinia virus-induced changes in actin fibers, seen by fluorescence microscopy, occurred in cells infected with the mutant. Moreover, the virus-encoded profilin homolog was not required for actin-associated events, including intracellular virus movement to the periphery of the cell, formation of specialized microvilli, or release of mature virions, as shown by electron microscopy and yields of infectious intra- and extracellular virus.

Identification, sequence, and expression of the gene encoding the second-largest subunit of the vaccinia virus DNA-dependent RNA polymerase.

The gene, rpo 132, encoding the second-largest subunit of the vaccinia virus DNA-dependent RNA polymerase was identified and sequenced. Two complementary approaches, involving antiserum to purified vaccinia virus RNA polymerase, were used to locate the rpo 132 gene. One method involved the screening of a lambda gt11 library of vaccinia virus genome fragments and the other was based on the immunoprecipitation and polyacrylamide gel electrophoresis of the in vitro translation products of mRNA that hybridized to immobilized vaccinia virus DNA. The deduced open reading frame of the rpo 132 gene predicted a polypeptide of 1164 amino acid residues with sequence similarities to the second-largest RNA polymerase subunits of eubacteria, archaebacteria, and eukaryotes as well as to other poxviruses. Transcriptional analyses indicated that rpo 132 has both early and late RNA start sites and is expressed throughout infection.