Lipid Transport between the Endoplasmic Reticulum and Mitochondria

Mitochondria are partially autonomous organelles that depend on the import of certain proteins and lipids to maintain cell survival and membrane formation. Although phosphatidylglycerol, cardiolipin, and phosphatidylethanolamine are synthesized by mitochondrial enzymes, phosphatidylcholine, phosphatidylinositol, phosphatidylserine, and sterols need to be imported from other organelles. The origin of most lipids imported into mitochondria is the endoplasmic reticulum, which requires interaction of these two subcellular compartments. Recently, protein complexes that are involved in membrane contact between endoplasmic reticulum and mitochondria were identified, but their role in lipid transport is still unclear. In the present review, we describe components involved in lipid translocation between the endoplasmic reticulum and mitochondria and discuss functional as well as regulatory aspects that are important for lipid homeostasis.Biological membranes are major structural components of all cell types. They protect the cell from external influences, organize the interior in distinct compartments and allow balanced flux of components. Besides their specific proteome, organelles exhibit unique lipid compositions, which influence their shape, physical properties, and function. Major lipid classes found in biological membranes are phospholipids, sterols, and sphingolipids.The major “lipid factory” within the cell is the endoplasmic reticulum (ER). It is able to synthesize the bulk of structural phospholipids, sterols, and storage lipids such as triacylglycerols and steryl esters (van Meer et al. 2008). Furthermore, initial steps of ceramide synthesis occur in the ER providing precursors for the formation of complex sphingolipids in other organelles (Futerman 2006). Besides the export of ceramides, the ER supplies a large portion of lipids to other organelles, which cannot produce their own lipids or have a limited capacity to do so. Organelle interaction and transport of lipids require specific carrier proteins, membrane contact sites, tethering complexes, and/or vesicle flux. These processes are highly important for the maintenance of cell structure and survival but are still a matter of dispute. Most prominent organelle interaction partners are the ER and mitochondria. A subfraction of the ER named mitochondria-associated membrane (MAM) (Vance 1990) was described to be involved in lipid translocation to mitochondria. MAM is part of the ER network, which was shown to be in contact or close proximity to the outer mitochondrial membrane (OMM). Contact sites between MAM and mitochondria were assumed to facilitate exchange of components between the two compartments. Interestingly, MAM harbor a number of lipid synthesizing enzymes (Gaigg et al. 1994). Recently, molecular components governing membrane contact between the two organelles were identified (Dolman et al. 2005; Csordás et al. 2006; de Brito and Scorrano 2008; Kornmann et al. 2009; Friedman et al. 2010; Lavieu et al. 2010), although the specific role of these components in lipid translocation is not yet clear.     

From Endoplasmic Reticulum to Mitochondria: Absence of the Arabidopsis ATP Antiporter Endoplasmic Reticulum Adenylate Transporter1 Perturbs Photorespiration

The carrier Endoplasmic Reticulum Adenylate Transporter1 (ER-ANT1) resides in the endoplasmic reticulum (ER) membrane and acts as an ATP/ADP antiporter. Mutant plants lacking ER-ANT1 exhibit a dwarf phenotype and their seeds contain reduced protein and lipid contents. In this study, we describe a further surprising metabolic peculiarity of the er-ant1 mutants. Interestingly, Gly levels in leaves are immensely enhanced (26×) when compared with that of wild-type plants. Gly accumulation is caused by significantly decreased mitochondrial glycine decarboxylase (GDC) activity. Reduced GDC activity in mutant plants was attributed to oxidative posttranslational protein modification induced by elevated levels of reactive oxygen species (ROS). GDC activity is crucial for photorespiration; accordingly, morphological and physiological defects in er-ant1 plants were nearly completely abolished by application of high environmental CO₂ concentrations. The latter observation demonstrates that the absence of ER-ANT1 activity mainly affects photorespiration (maybe solely GDC), whereas basic cellular metabolism remains largely unchanged. Since ER-ANT1 homologs are restricted to higher plants, it is tempting to speculate that this carrier fulfils a plant-specific function directly or indirectly controlling cellular ROS production. The observation that ER-ANT1 activity is associated with cellular ROS levels reveals an unexpected and critical physiological connection between the ER and other organelles in plants.     

Mechanisms and Functions of Vinculin Interactions with Phospholipids at Cell Adhesion Sites

The cytoskeletal protein vinculin is a major regulator of cell adhesion and attaches to the cell surface by binding to specific phospholipids. Structural, biochemical, and biological studies provided much insight into how vinculin binds to membranes, what components it recognizes, and how lipid binding is regulated. Here we discuss the roles and mechanisms of phospholipids in regulating the structure and function of vinculin and of its muscle-specific metavinculin splice variant. A full appreciation of these processes is necessary for understanding how vinculin regulates cell motility, migration, and wound healing, and for understanding of its role in cancer and cardiovascular diseases.     

Comparative Model Analysis of Calcium Exchange between the Cytosol and Stores of Mitochondria or Endoplasmic Reticulum

The objects of the study were single-compartment mathematical models corresponding to a fragment of the dendrite of a cerebellar Purkinje neuron containing the mitochondria (model 1) or a cistern of the endoplasmic reticulum, ER, (model 2) as the calcium stores. We investigated the dependence of the intracellular Ca²⁺ dynamics on geometrical sizes of calcium exchanging parts of the intracellular space and the difference between the kinetic characteristics of storing in two types of stores occupying different portions of the compartment volume. The plasma membrane of the compartment bore the ion channels, particularly those conducting excitatory synaptic current, and the calcium pump typical of this neuron type. The model equations took into account Ca²⁺ exchange between the cytosol, extracellular medium, organelle stores, non-organelle endogenous buffers, and an exogenous buffer (fluorescent dye), and also the diffusion of Са²⁺ into adjacent regions of the dendrite. In model 1, the mitochondria exchanged Са²⁺ with the cytosol via the uniporter and sodium/calcium exchanger; mitochondrial processes, such as the tricarboxylic acid cycle and aerobic cellular respiration, were also taken into account. In model 2, the ER membrane contained the calcium pump, channels of passive leak, and channels of calcium-induced and inositol-3-phosphate-dependent release of Са²⁺. Increases in the portion of the stores in the total volume of the compartment from 1 to 36% led to a proportional increase in the peak values of the cytosolic calcium concentration ([Ca²⁺] _i ); the concentration of Са²⁺ in the mitochondria ([Ca²⁺]_mit) or ER ([Ca²⁺]_ER) increased correspondingly. During generation of bell-shaped cytosolic calcium signals of equal intensity and duration, the ER (due to a greater rate of storing, as compared with that in the mitochondria) was able to uptake several times more Са²⁺ (four times at 36% filling of the volume by the organelles). It is suggested that the revealed different kinetic characteristics of Са²⁺ storing by different organelles are determined by the rates of binding to transport molecules present in the store membrane and, therefore, are defined by concentrations (surface densities) of these molecules and their saturation at certain levels of [Ca²⁺]i. It has been shown that the occupancy of the intracellular volume by organelle stores of any type is a structural factor, which is able to essentially modulate the values of Ca²⁺ concentration.     

An Association between Mitochondria and the Endoplasmic Reticulum in Cells of the Pseudobranch Gland of a Teleost

An elaborate and apparently unique specialization of the endoplasmic reticulum having the form of tubules and a precise orientation with respect to the mitochondria has been described for the specific cell of the pseudobranch gland. The tubules also are concentrated near the vascular border of the cell where they show continuity with the plasma membrane and open directly against the basement membrane. On the other side of the basement membrane, the endothelial cells of the sinusoid show openings or discontinuities characteristically associated with secretory cells. The pseudobranch gland is presumed to have carbonic anhydrase as one of its primary products, if not its only one, and the elaborate ultrastructure is thought to be associated with the special problems of secreting this enzyme.     

Cer1p Functions as a Molecular Chaperone in the Endoplasmic Reticulum of Saccharomyces cerevisiae

Cer1p/Lhs1p/Ssi1p is a novel Hsp70-related protein that is important for the translocation of a subset of proteins into the yeast Saccharomyces cerevisiae endoplasmic reticulum. Cer1p has very limited amino acid identity to the hsp70 chaperone family in the N-terminal ATPase domain but lacks homology to the highly conserved hsp70 peptide binding domain. The role of Cer1p in protein folding and translocation was assessed. Deletion of CER1 slowed the folding of reduced pro-carboxypeptidase Y (pro-CPY) approximately twofold in yeast. In wild-type yeast under reducing conditions, pro-CPY can be found in a complex with Cer1p, while partially purified Cer1p is able to bind directly to peptides. Together, this suggests that Cer1p has a chaperoning activity required for proper refolding of denatured pro-CPY which is mediated by direct interaction with the unfolded polypeptide. Cer1p peptide binding and oligomerization could be disrupted by addition of ATP, confirming that Cer1p possesses a functional ATP binding site, much like Kar2p and other members of the hsp70 family. Interestingly, replacing the signal sequence of a CER1-dependent protein with that of a CER1-independent protein did not relieve the requirement of CER1 for import. This result suggests that an interaction with the mature portion of the protein also is important for the translocation role of Cer1p. The CER1 RNA levels increase at lower temperatures. In addition, the effects of deletion on folding and translocation are more severe at lower temperatures. Therefore, these results suggest that Cer1p provides an additional chaperoning activity in processes known to require Kar2p. However, there appears to be a greater requirement for Cer1p chaperone activity at lower temperatures.     

Molecular Mechanisms Leading to Neuroprotection/Ischemic Tolerance: Effect of Preconditioning on the Stress Reaction of Endoplasmic Reticulum

Ischemic tolerance can be developed by prior ischemic non-injurious stimulus preconditioning. The molecular mechanisms underlying ischemic tolerance are not yet fully understood. The purpose of this study is to evaluate the effect of preconditioning/preischemia on ischemic brain injury. We examined the endoplasmic reticulum stress response (unfolded protein response (UPR)) by measuring the mRNA and protein levels of specific genes such as ATF6, GRP78, and XBP1 after 15 min 4-VO ischemia and different times of reperfusion (1, 3, and 24 h). The data from the group of naïve ischemic rats were compared with data from the group of preconditioned animals. The results of the experiments showed significant changes in the gene expression at the mRNA level in the all ischemic/reperfusion phases. The influence of preischemia on protein level of XBP was significant in later ischemic times and at 3 h, the reperfusion reached 230% of the controls. The protein levels of GRP78 in preischemic animals showed a significant increase in ischemic and reperfusion times. They exceeded to 50% levels of corresponding naïve ischemic/reperfusion groups. Preconditioning also induced remarkable changes in the levels of ATF6 protein in the ischemic phase (about 170%). The levels of ATF6 remained elevated in earlier reperfusion times (37 and 62%, respectively) and persisted significantly elevated after 24 h of reperfusion. This data suggest that preconditioning paradigm (preischemia) underlies its neuroprotective effect by the attenuation of ER stress response after acute ischemic/reperfusion insult.     

Endoplasmic Reticulum Stress and the Making of a Professional Secretory Cell

ABSTRACT

Homeostasis of the protein folding machinery in the endoplasmic reticulum (ER) is maintained via several parallel unfolded protein response pathways that are remarkably conserved from yeast to man. Together, these pathways are integrated into a complex circuitry that can be modulated in various ways, not only to cope with various stress conditions, but also to fine-tune the capacity of the ER folding machinery when precursor cells differentiate into professional secretory cells.     

Interactions between Newly Synthesized Glycoproteins, Calnexin and a Network of Resident Chaperones in the Endoplasmic Reticulum

Calnexin is a membrane-bound lectin and a molecular chaperone that binds newly synthesized glycoproteins in the endoplasmic reticulum (ER). To analyze the oligomeric properties of calnexin and calnexin-substrate complexes, sucrose velocity gradient centrifugation and chemical cross-linking were used. After CHAPS solubilization of Chinese Hamster Ovary cells, the unoccupied calnexin behaved as a monomer sedimenting at 3.5 S_20,W. For calnexin-substrate complexes the S-values ranged between 3.5–8 S_20,W, the size increasing with the molecular weight of the substrate. Influenza hemagglutinin, a well-characterized substrate associated with calnexin in complexes that sedimented at 5–5.5 S_20,W. The majority of stable complexes extracted from cells, appeared to contain a single calnexin and a single substrate molecule, with about one third of the calnexin in the cell being unoccupied or present in weak associations. However, when chemical cross-linking was performed in intact cells, the calnexin-substrate complexes and calnexin itself was found to be part of a much larger heterogeneous protein network that included other ER proteins. Pulse-chase analysis of influenza-infected cells combined with chemical cross-linking showed that HA was part of large, heterogeneous, cross-linked entities during the early phases of folding, but no longer after homotrimer assembly. The network of weakly associated resident ER chaperones which included BiP, GRP94, calreticulin, calnexin, and other proteins, may serve as a matrix that binds early folding and assembly intermediates and restricts their exit from the ER.     

Detection of Transient In Vivo Interactions between Substrate and Transporter during Protein Translocation into the Endoplasmic Reticulum

The split-ubiquitin technique was used to detect transient protein interactions in living cells. N_ub, the N-terminal half of ubiquitin (Ub), was fused to Sec62p, a component of the protein translocation machinery in the endoplasmic reticulum of Saccharomyces cerevisiae. C_ub, the C-terminal half of Ub, was fused to the C terminus of a signal sequence. The reconstitution of a quasi-native Ub structure from the two halves of Ub, and the resulting cleavage by Ub-specific proteases at the C terminus of C_ub, serve as a gauge of proximity between the two test proteins linked to N_ub and C_ub. Using this assay, we show that Sec62p is spatially close to the signal sequence of the prepro-α-factor in vivo. This proximity is confined to the nascent polypeptide chain immediately following the signal sequence. In addition, the extent of proximity depends on the nature of the signal sequence. C_ub fusions that bore the signal sequence of invertase resulted in a much lower Ub reconstitution with N_ub-Sec62p than otherwise identical test proteins bearing the signal sequence of prepro-α-factor. An inactive derivative of Sec62p failed to interact with signal sequences in this assay. These in vivo findings are consistent with Sec62p being part of a signal sequence-binding complex.     

A Highly Conserved Motif at the COOH Terminus Dictates Endoplasmic Reticulum Exit and Cell Surface Expression of NKCC2

Mutations in the apically located Na⁺-K⁺-2Cl⁻ co-transporter, NKCC2, lead to type I Bartter syndrome, a life-threatening kidney disorder, yet the mechanisms underlying the regulation of mutated NKCC2 proteins in renal cells have not been investigated. Here, we identified a trihydrophobic motif in the distal COOH terminus of NKCC2 that was required for endoplasmic reticulum (ER) exit and surface expression of the co-transporter. Indeed, microscopic confocal imaging showed that a naturally occurring mutation depriving NKCC2 of its distal COOH-terminal region results in the absence of cell surface expression. Biotinylation assays revealed that lack of cell surface expression was associated with abolition of mature complex-glycosylated NKCC2. Pulse-chase analysis demonstrated that the absence of mature protein was not caused by reduced synthesis or increased rates of degradation of mutant co-transporters. Co-immunolocalization experiments revealed that these mutants co-localized with the ER marker protein-disulfide isomerase, demonstrating that they are retained in the ER. Cell treatment with proteasome or lysosome inhibitors failed to restore the loss of complex-glycosylated NKCC2, further eliminating the possibility that mutant co-transporters were processed by the Golgi apparatus. Serial truncation of the NKCC2 COOH terminus, followed by site-directed mutagenesis, identified hydrophobic residues ¹⁰⁸¹LLV¹⁰⁸³ as an ER exit signal necessary for maturation of NKCC2. Mutation of ¹⁰⁸¹LLV¹⁰⁸³ to AAA within the context of the full-length protein prevented NKCC2 ER exit independently of the expression system. This trihydrophobic motif is highly conserved in the COOH-terminal tails of all members of the cation-chloride co-transporter family, and thus may function as a common motif mediating their transport from the ER to the cell surface. Taken together, these data are consistent with a model whereby naturally occurring premature terminations that interfere with the LLV motif compromise co-transporter surface delivery through defective trafficking.The Na-K-2Cl co-transporter, NKCC2, provides the major route for sodium/chloride transport across the apical plasma membrane of the thick ascending limb (TAL)³ of the kidney (1). This co-transporter is critical for salt reabsorption, acid-base regulation, and divalent mineral cation metabolism (2). The prominent importance of NKCC2 in renal functions is evidenced by the effect of loop diuretics, which as pharmacologic inhibitors of NKCC2, are extensively used in the treatment of edematous states (2). Even more impressive, inactivating mutations of the NKCC2 gene in humans causes Bartter syndrome type 1 (BS1), a life-threatening renal tubular disorder for which the diagnosis is usually made in the antenatal-neonatal period, due to the presence of polyhydramnios, premature delivery, salt loss, hypokalemia, metabolic alkalosis, hypercalciuria, and nephrocalcinosis (3). Without appropriate treatment, patients with BS1 will not survive the early neonatal period (4). In congruence with the severity of the symptoms and the uniformity of the clinical picture, functional analysis of diverse NKCC2 mutants consistently revealed a loss of function effect of the tested mutations (5, 6). However, regulatory characterizations of mutants NKCC2 were limited to Xenopus laevis oocytes. Indeed, studies aimed at understanding the post-translational regulation of NKCC2 have been hampered by the difficulty of expressing the co-transporter protein in mammalian cells (7, 8). As a consequence, our knowledge of the molecular mechanisms underlying membrane trafficking of mutated NKCC2 proteins in mammalian cells is nil. Increasing our understanding of the molecular determinants underlying NKCC2 expression in renal cells is essential for elucidating the pathophysiology of BS1 and for improving the available treatments (9, 10). Undeniably, only analysis of the expression such NKCC2 of mutants in renal cells would definitively establish their cellular fate.NKCC2 belongs to the superfamily of electroneutral cation-coupled chloride (CCC) co-transporters (SLC12A) (1). The cation-chloride co-transporters (CCCs) family comprises two principal branches of homologous membrane proteins. One branch includes the Na⁺-dependent chloride co-transporters composed of the Na⁺-K⁺-2Cl⁻ co-transporters (NKCC1 and NKCC2) and the Na⁺-Cl⁻ co-transporter (NCC). The second branch includes the Na⁺-independent K⁺-Cl⁻ co-transporters composed of at least four different isoforms: KCC1 KCC2, KCC3, and KCC4 (11). Within the families, the CCCs share 25–75% amino acid identity. All of these co-transporters exhibit similar hydropathy profiles with 12 transmembrane-spanning domains, an amino terminus of variable length, and a long cytoplasmic carboxyl terminus. Because the COOH-terminal domain of NKCC2 is the predominant cytoplasmic region, it is likely to be a major factor in the trafficking of the NKCC2 protein. Moreover, there have been several reports demonstrating that COOH-terminal residues are important for correct protein targeting (12–14). Occasionally, COOH-terminal mutations are known to cause genetic disorders (15–17). Although studies of other ion transporters support the importance of the COOH-terminal signals in protein stability, maturation, surface delivery, and ER export (18–22), little is known about the role of COOH-terminal signals in the biogenesis of NKCC2.We were recently able to express NKCC2 protein in mammalian cells (23), providing therefore a powerful tool to study and understand the molecular mechanisms underlying the co-transporter expression and regulation in renal cells. This allowed us, in this study, to take the advantage of the existence of natural mutants altering the COOH-terminal tail of the co-transporter to investigate the role of the COOH terminus in the biogenesis of NKCC2 and to explore possible mechanisms implicated in BS1. The results demonstrate the importance of the COOH terminus in normal maturation of the NKCC2 protein. Indeed, we identified a motif of three hydrophobic residues, ¹⁰⁸¹LLV¹⁰⁸³, highly conserved in the COOH-terminal tails of all members of the CCC family, that controls the rate of ER export and thus of surface expression of NKCC2. Loss of the motif disrupts glycosylation and plasma membrane localization of NKCC2. Therefore, we propose abnormal trafficking as a common BS1 mechanism associated with mutations depriving NKCC2 of its COOH terminus.     

Roles of the Mitochondria and Endoplasmic Reticulum in Calcium Elevation during Osmotic Shock in Adrenocortical Cells

Steroid hormones participate in various metabolic processes, and dysfunction of the adrenocortical system leads to numerous pathologies in humans. One of the factors that can influence the secretory properties of adrenocorticocytes is changes in the cell volume observed during osmotic shock. In our study, we tested the hypothesis that osmotic stress modifies intracellular Ca²⁺ signalling and in such a way can influence the secretion of steroids by adrenocorticocytes. The effects of hyperosmotic stress on the cytosolic Ca²⁺ concentration ([Ca]_i) in cultured adrenocortical cells from the zona fasciculata of the rat adrenals were investigated using the indicator fura-2 technique. Our experiments have shown that exposure of the cells to a hyperosmotic solution caused a decrease in the cell volume, as well as a reversible rise in the [Ca]_i. Calcium-free media partly eliminated [Ca]_i responses. Pretreatment of the cells with thapsigargin or CCCP (blockers of internal calcium stores) significantly decreased the magnitude of responses induced by osmotic stress. These findings indicate that osmotic shock causes an increase in the [Ca]_i in adrenocortical cells, mostly due to depletion of the intracellular stores, and may in such a way stimulate steroidogenesis.     

Translocation of Bax and Bid to Mitochondria, Endoplasmic Reticulum and Nuclear Envelope: Possible Control Points in Apoptosis

The cross-talk between endoplasmic reticulum (ER) and mitochondria was investigated during apoptosis in a breast cancer cell line (MCF-7) in culture. The effect of camptothecin, an inducer of apoptosis and a specific inhibitor of topoisomerase I, was investigated by morphological, immunocytochemical and histochemical techniques for electron microscopy. Our ultrastructural morphological data demonstrate alterations in ER configuration and communication with neighbouring mitochondria early after stimulation by camptothecin. Immunoelectron studies have demonstrated that Bax and Bid translocate from cytoplasm to mitochondria where they initiate mitochondrial dysfunction and cytochrome c release. Bax and Bid were also localized in ER and nuclear envelope. Since ER and mitochondria function as intracellular Ca2+ storage, we hypothesize that Bax and Bid are involved in the emptying of ER Ca2+ pool, triggers secondary changes in mitochondrial Ca2+ levels that contribute to cytochrome c release and cell death.     

Intracellular Sorting Signals for Sequential Trafficking of Human Cytomegalovirus UL37 Proteins to the Endoplasmic Reticulum and Mitochondria

Human cytomegalovirus UL37 antiapoptotic proteins, including the predominant UL37 exon 1 protein (pUL37x1), traffic sequentially from the endoplasmic reticulum (ER) through the mitochondrion-associated membrane compartment to the mitochondrial outer membrane (OMM), where they inactivate the proapoptotic activity of Bax. We found that widespread mitochondrial distribution occurs within 1 h of pUL37x1 synthesis. The pUL37x1 mitochondrial targeting signal (MTS) spans its first antiapoptotic domain (residues 5 to 34) and consists of a weak hydrophobicity leader (MTSα) and proximal downstream residues (MTSβ). This MTS arrangement of a hydrophobic leader and downstream proximal basic residues is similar to that of the translocase of the OMM 20, Tom20. We examined whether the UL37 MTS functions analogously to Tom20 leader. Surprisingly, lowered hydropathy of the UL37x1 MTSα, predicted to block ER translocation, still allowed dual targeting of mutant to the ER and OMM. However, increased hydropathy of the MTS leader caused exclusion of the UL37x1 high-hydropathy mutant from mitochondrial import. Conversely, UL37 MTSα replacement with the Tom20 leader did not retarget pUL37x1 exclusively to the OMM; rather, the UL37x1-Tom20 chimera retained dual trafficking. Moreover, replacement of the UL37 MTSβ basic residues did not reduce OMM import. Ablation of the MTSα posttranslational modification site or of the downstream MTS proline-rich domain (PRD) increased mitochondrial import. Our results suggest that pUL37x1 sequential ER to mitochondrial trafficking requires a weakly hydrophobic leader and is regulated by MTSβ sequences. Thus, HCMV pUL37x1 uses a mitochondrial importation pathway that is genetically distinguishable from that of known OMM proteins.During infection of permissive cells, the human cytomegalovirus (HCMV) UL37 immediate-early locus encodes multiple UL37 isoforms (4, 11, 16, 22, 24, 25) (Fig. ​(Fig.1A).1A). The predominant isoform, the UL37 exon 1 protein (pUL37x1), or the viral mitochondrial inhibitor of apoptosis (vMIA), is an essential HCMV gene product required for its growth in humans (17) and in cell culture (14, 20, 36, 47). pUL37x1 induces calcium efflux from the endoplasmic reticulum (ER) (40), regulates viral early gene expression (6, 12), disrupts the F-actin cytoskeleton (35, 40), binds and inactivates Bax at the mitochondrial outer membrane (OMM) (5, 32-34), and inhibits mitochondrial serine protease at late times of infection (27).Open in a separate windowFIG. 1.(A) HCMV UL37 isoforms. UL37 proteins share N-terminal UL37x1 MTS, including a moderately hydrophobic MTSα leader (aa 1 to 22, cylinder), MTSβ proximal basic residues (aa 23 to 29, ++++), downstream acidic (aa 81 to 108, —) and basic (aa 134 to 151, +++) domains. The unique C-terminal sequences encoded by UL37 exon 3 contain an N-glycosylation domain (aa 206 to 391, branches) as well as two additional TM domains (aa 178 to 196 and aa 433 to 459, cylinders). The fusion proteins carrying the full length (pUL37x1 wt_1-163) or MTS (wt_1-36-YFP) with C-terminal fluorophores are represented below. The two UL37x1 antiapoptotic domains are also shown (17). (B) Kinetics of pUL37x1 mitochondrial importation. HFFs were cotransfected with plasmids encoding pUL37x1 wt_1-163-YFP and DsRed1-mito (Clontech). After 2 h, anisomycin (70 μM) was added to the medium. After 12 h, the cells were either fixed with 100% methanol (0 min) or washed with 1× PBS and overlaid with fresh, anisomycin-free medium. The cells were incubated for the indicated times before methanol fixation and confocal imaging. The images were obtained by using comparable settings of aperture and laser power. (C) Colocalization of newly synthesized pUL37x1 with a mitochondrial marker. HFFs transiently transfected with pUL37x1 wt_1-163-YFP (green) were treated with anisomycin-containing medium as in panel B for 12 h. Inhibitor-containing medium was removed, and the cells were washed and overlaid with fresh, anisomycin-free medium for 45 min. At that time, 50 nM MitoTracker Red CMXRos (red, Invitrogen) was added to the medium, followed by incubation for 15 min at 37°C, prior to methanol fixation. The cells were then imaged by confocal microscopy. The panels on the left and center are grayscale. The panel on the right is the color merge of both channels. The small insets are enlargements of the indicated region of interest in the cell. (D) UL37x1 MTS is sufficient for mitochondrial import. HFFs were transiently transfected with expression vectors for wt_1-36-YFP and treated with MitoTracker Red (top row) as described above or for wt_1-163-YFP and DsRed1-mito (bottom). Cells were harvested 24 h later and imaged by confocal microscopy. The left and center panels are grayscale. The panels on the right show merged images of both channels.To accomplish their multiple functions in the cell, HCMV UL37 proteins sequentially traffic from the ER to mitochondria (4, 9, 17, 24-26, 45). The amino-terminal UL37x1 antiapoptotic domain serves as a mitochondrial targeting sequence (MTS) (16, 17, 24, 26). UL37 proteins first translocate into the ER, traffic through the mitochondria-associated membrane (MAM) subcompartment of the ER, and then to the OMM (9, 11, 24-26, 45). The MAM is a lipid-rich subdomain of the ER, which directly contacts mitochondria, allowing for the transfer of lipids from the ER to the OMM and the inner mitochondrial membrane (41), and functionally provides microdomains for efficient coupling of ER to mitochondria calcium transfer (37, 42).The HCMV UL37x1 bipartite MTS includes a weakly hydrophobic leader (MTSα, amino acids [aa] 1 to 22) that is required for ER translocation and mitochondrial import, as well as downstream sequences (MTSβ, aa 23 to 34) that are additionally required for its OMM importation (24) (Fig. ​(Fig.2A).2A). The HCMV UL37 MTS is conserved in the homologous primate CMV UL37x1 genes (28).Open in a separate windowFIG. 2.(A) Conservation of UL37x1 MTS among the primate cytomegaloviruses. The sequences of HCMV, chimpanzee CMV (CCMV), rhesus monkey CMV (RhCMV), and African green monkey (AgmCMV) are shown (top). The boxed areas enclose MTSα, the predicted alpha-helical domain, based upon HMMTOP analysis, within each leader. The MTSβ spans downstream residues 23 to 36. The boldfacing and filled circles indicate identity among primate CMV UL37x1 genes. The HCMV UL37x1 hydrophobic leader was mutated to lowered hydrophobicity by replacement of nonconserved residues V4G, L8G, and L14G while maintaining the same length of the TM in the LH mutant (bottom). The predicted hydrophobicity scores (grand average of hydropathicity, GRAVY, Kyte-Doolittle scale) were calculated for the boxed residues of the wt and LH mutant using ProtParam application on the ExPASy Proteomics Server. (B) Colocalization of UL37x1 LH_1-36-YFP with MitoTracker. HFFs transiently transfected with a vector expressing pUL37x1 LH_1-36-YFP for 24 h were treated with 50 nM MitoTracker as described above and imaged by confocal microscopy. Shown on the left and middle panels are the grayscale images, while the panel on the right is the overlay both channels. The small insets are enlargements of the indicated regions of interest. (C) ER translocation and mitochondrial import of pUL37x1 LH_1-36-YFP and LH_1-163-YFP. HeLa cells were transfected with expression vectors of wt_1-36-YFP, LH_1-36-YFP, or YFP vector alone (top) or wt_1-163-YFP, LH_1-163-YFP, or YFP vector alone (bottom). ER and mitochondrial fractions were isolated as described previously (8, 9). (Top) 10 μg (wt_1-36-YFP and YFP vector alone) or 40 μg (LH_1-36-YFP) of each fraction was analyzed by Westerns with anti-GFP (1:200) antibody. (Bottom) 20 μg of each fraction was analyzed by Western analysis with anti-UL37x1 (DC35, 1:2,500) or Grp75 (1:1,000) antibodies.In contrast, most signal-anchored proteins of the OMM are synthesized in the cytosol as precursors with NH₂-terminal sequences that directly target them to mitochondria (31). Signal-anchored OMM proteins, such as the translocase of the OMM subunits, Tom20 and Tom70 (43, 46), are similar in topology to pUL37x1 and the NH₂-terminal cleavage product, pUL37_NH2, of the UL37 glycoprotein (gpUL37) (26). Tom20 and Tom70 are anchored to the OMM by short NH₂-terminal transmembrane (TM) domains with the bulk of the polypeptides exposed to the cytosol in a type I orientation (21). The important structural elements of their signal anchor sequences are (i) moderate hydrophobicity of the TM domain and (ii) positively charged amino acids in its flanking domain (21, 43). Tom20 is targeted from the cytosol to the OMM by a moderately hydrophobic NH₂-terminal leader (score = 1.826) with a minimal requirement for a net basic charge within one to five residues downstream of the leader (21). The juxtaposed basic residues release the Tom20 hydrophobic leader from the ER-targeting signal recognition particle (SRP) and allow for its direct targeting to the OMM. This arrangement of the Tom20 intracellular sorting signals (20, 41) is similar to that of the MTS of pUL37x1 (22), whose leader, while lower in hydropathy (score = 1.289), is nonetheless ER translocated rather than imported from the cytosol directly into the OMM (24, 26).Our studies were undertaken to define the sequence requirements for pUL37x1 sequential targeting to the ER and to the OMM and to determine whether these signals are distinct from those of other OMM proteins. We examined the potential role of conventional OMM targeting signals (leader hydrophobicity and proximal basic residues) as well as sequences conserved in the homologues of primate CMVs. Unpredictably, UL37x1 MTSβ (aa 23 to 36) did not act analogously to the Tom20 mitochondrial targeting leader. Rather, HCMV UL37x1 sequences retargeted the Tom20 hydrophobic leader to sequential ER to OMM import. Moreover, mutation of conventional mitochondrial targeting basic residues did not markedly alter pUL37x1 mitochondrial import. Similarly, UL37x1 lowered hydrophobicity MTSα mutants dually trafficked to the ER and mitochondria. Conversely, pUL37x1 trafficking was altered by increased hydropathy, which effectively blocked mitochondrial import. From these studies, we conclude that weak hydrophobicity of the pUL37x1 MTSα and downstream residues play a role in directing translocation but involve more complex interplay than previously appreciated. Importantly, two previously unrecognized MTS signals, the consensus MTSα posttranslational modification (PTM) site (²¹SY) and a downstream MTSβ proline-rich domain (PRD, aa 33 to 36), regulated pUL37x1 mitochondrial import.(These studies were performed by C.D.W. in partial fulfillment of his doctoral studies in the Biochemistry and Molecular Genetics Program at George Washington Institute of Biomedical Sciences.)     

Overexpression of Tau Protein Inhibits Kinesin-dependent Trafficking of Vesicles,Mitochondria, and Endoplasmic Reticulum: Implications for Alzheimer's Disease

The neuronal microtubule-associated protein tau plays an important role in establishing cell polarity by stabilizing axonal microtubules that serve as tracks for motor-protein–driven transport processes. To investigate the role of tau in intracellular transport, we studied the effects of tau expression in stably transfected CHO cells and differentiated neuroblastoma N2a cells. Tau causes a change in cell shape, retards cell growth, and dramatically alters the distribution of various organelles, known to be transported via microtubule-dependent motor proteins. Mitochondria fail to be transported to peripheral cell compartments and cluster in the vicinity of the microtubule-organizing center. The endoplasmic reticulum becomes less dense and no longer extends to the cell periphery. In differentiated N2a cells, the overexpression of tau leads to the disappearance of mitochondria from the neurites. These effects are caused by tau''s binding to microtubules and slowing down intracellular transport by preferential impairment of plus-end–directed transport mediated by kinesin-like motor proteins. Since in Alzheimer''s disease tau protein is elevated and mislocalized, these observations point to a possible cause for the gradual degeneration of neurons.     

A New Look at Rho GTPases in the Cell Cycle: Their Role in Kinetochore-Microtubule Attachment

Rho GTPases including Rho, Rac and Cdc42 are involved in cell morphogenesis by inducing specific types of actin cytoskeleton and alignment and stabilization of microtubules. Previous studies suggest that they also regulate cell cycle progression; Rho, Rac and Cdc42 regulate the G1-S progression and Rho controls cytokinesis. However, a role of Rho GTPases in nuclear division has not been definitely shown. We have recently found that Cdc42 and its downstream effector mDia3 are involved in bi-orientation and stabilization of spindle microtubules attachment to kinetochores and regulate chromosome alignment and segregation. Here, we discuss how this is coordinated with other events in mitosis, particularly, with the action of Rho in cytokinesis and how attachment of microtubules to kinetochores is achieved and stabilized. We also discuss redundancy of Cdc42 and Cdc42-related GTPase(s) and potential mechanisms of chromosome instability in cancer     

Evidence that a Proliferation of the Endoplasmic Reticulum Precedes the Formation of Glyoxysomes and Mitochondria in Germinating Castor Bean Endosperm

Excised castor bean endosperm halves incubated with CDP-[Me-¹⁴C]cholineactively incorporated this compound into membrane phosphatidylcholine.The capacity of the tissue to synthesize phosphatidyl-[¹⁴C]cholineincreased during the first 3 d of germination and subsequentlydeclined. At the onset of germination phosphatidyl-[^l4C]cholinewas exclusively recovered in the ER membrane fraction. The rateof incorporation into the ER membranes increased strikinglyduring the first 24 h of germination while that into mitochondriaand glyoxysomes remained low. At later developmental stagesan increasing proportion of the newly synthesized phosphatidyl-[¹⁴C]cholinewas present in mitochondria and glyoxysomes; the rate of incorporationinto the membranes of these organelles increased while thatinto the ER membrane began to level off. The kinetics of CDP-[¹⁴C]cholineincorporation into membrane phosphatidylcholine of the majororganelle fractions of 3-d-old endosperm tissue showed thatthe ER was immediately labelled, whereas a lag period precededthe labelling of mitochondria and glyoxysomes. Assuming that the incorporation of CDP-[¹⁴C]choline into phosphatidylcholineserves as a reliable indicator of membrane synthesis, the resultsobtained suggest that a proliferation of ER membranes precedesthe formation of glyoxysomes and mitochondria in germinatingcastor bean endosperm. A comparison of developmental changesin (a) total ER and glyoxysomal phospholipid content and (b)ER and mitochondrial NADH cytochrome c reductase activity providedadditional evidence supporting this conclusion.