Aven Lee

Cytoskeletal Anchoring of GLAST Determines Susceptibility to Brain Damage AN IDENTIFIED ROLE FOR GFAP

Glial fibrillary acidic protein (GFAP) is an enigmatic protein; it currently has no unambiguously defined role. It is expressed in the cytoskeleton of astrocytes in the mammalian brain. We have used co-immunoprecipitation to identify in vivo binding partners for GFAP in the rat and pig brain. We demonstrate interactions between GFAP, the glutamate transporter GLAST, the PDZ-binding protein NHERF1, and ezrin. These interactions are physiologically relevant; we demonstrate in vitro that transport of d-aspartate (a glutamate analogue) is significantly increased in the presence of GFAP and NHERF1. Moreover, we demonstrate in vivo that expression of GFAP is essential in retaining GLAST in the plasma membranes of astrocytes after an hypoxic insult. These data indicate that the cytoskeleton of the astrocyte plays an important role in protecting the brain against glutamate-mediated excitotoxicity.

Nedd4-2 Functionally Interacts with ClC-5 INVOLVEMENT IN CONSTITUTIVE ALBUMIN ENDOCYTOSIS IN PROXIMAL TUBULE CELLS

Constitutive albumin uptake by the proximal tubule is achieved by a receptor-mediated process in which the Cl– channel, ClC-5, plays an obligate role. Here we investigated the functional interaction between ClC-5 and ubiquitin ligases Nedd4 and Nedd4-2 and their role in albumin uptake in opossum kidney proximal tubule (OK) cells. In vivo immunoprecipitation using an anti-HECT antibody demonstrated that ClC-5 bound to ubiquitin ligases, whereas glutathione S-transferase pull-downs confirmed that the C terminus of ClC-5 bound both Nedd4 and Nedd4-2. Nedd4-2 alone was able to alter ClC-5 currents in Xenopus oocytes by decreasing cell surface expression of ClC-5. In OK cells, a physiological concentration of albumin (10 μg/ml) rapidly increased cell surface expression of ClC-5, which was also accompanied by the ubiquitination of ClC-5. Albumin uptake was reduced by inhibiting either the lysosome or proteasome. Total levels of Nedd4-2 and proteasome activity also increased rapidly in response to albumin. Overexpression of ligase defective Nedd4-2 or knockdown of endogenous Nedd4-2 with small interfering RNA resulted in significant decreases in albumin uptake. In contrast, pathophysiological concentrations of albumin (100 and 1000 μg/ml) reduced the levels of ClC-5 and Nedd4-2 and the activity of the proteasome to the levels seen in the absence of albumin. These data demonstrate that normal constitutive uptake of albumin by the proximal tubule requires Nedd4-2, which may act via ubiquitination to shunt ClC-5 into the endocytic pathway.

A new GLT1 splice variant: cloning and immunolocalization of GLT1c in the mammalian retina and brain

We have identified a novel carboxyl-terminal splice-variant of the glutamate transporter GLT1, which we denote as GLT1c. Within the rat brain only low levels of protein and message were detected, protein expression being restricted to end feet of astrocytes apposed to blood vessels or some astrocytes adjacent to the ventricles. Conversely, within the retina, this variant was selectively and heavily expressed in the synaptic terminals of both rod- and cone-photoreceptors in both humans and rats. Double-immunolabelling with antibodies to the carboxyl region of GLT1b/GLT1v, which is strongly expressed in apical dendrites of bipolar cells and in cone photoreceptors revealed that in the rat GLT1c was co-localised with GLT1b/GLT1v in cone photoreceptors but not with GLT1b/GLT1v in bipolar cells. GLT1c expression was developmentally regulated, only appearing at around postnatal day 7 in the rat retina, when photoreceptors first exhibit a dark current. Since the glutamate transporter EAAT5 is also expressed in terminals of rod photoreceptor terminals these data indicate that rod photoreceptors express two glutamate transporters with distinct properties. Similarly, cone photoreceptors express two glutamate transporters. We suggest that differential usage of these transporters by rod and cone photoreceptors may influence the kinetics of glutamate transmission by these neurons.

Regulation of Albumin Endocytosis by PSD95/Dlg/ZO-1 (PDZ) Scaffolds INTERACTION OF Na+-H+ EXCHANGE REGULATORY FACTOR-2 WITH ClC-5

The constitutive reuptake of albumin from the glomerular filtrate by receptor-mediated endocytosis is a key function of the renal proximal tubules. Both the Cl– channel ClC-5 and the Na+-H+ exchanger isoform 3 are critical components of the macromolecular endocytic complex that is required for albumin uptake, and therefore the cell-surface levels of these proteins may limit albumin endocytosis. This study was undertaken to investigate the potential roles of the epithelial PDZ scaffolds, Na+-H+ exchange regulatory factors, NHERF1 and NHERF2, in albumin uptake by opossum kidney (OK) cells. We found that ClC-5 co-immunoprecipitates with NHERF2 but not NHERF1 from OK cell lysate. Experiments using fusion proteins demonstrated that this was a direct interaction between an internal binding site in the C terminus of ClC-5 and the PDZ2 module of NHERF2. In OK cells, NHERF2 is restricted to the intravillar region while NHERF1 is located in the microvilli. Silencing NHERF2 reduced both cell-surface levels of ClC-5 and albumin uptake. Conversely, silencing NHERF1 increased cell-surface levels of ClC-5 and albumin uptake, presumably by increasing the mobility of NHE3 in the membrane and its availability to the albumin uptake complex. Surface biotinylation experiments revealed that both NHERF1 and NHERF2 were associated with the plasma membrane and that NHERF2 was recruited to the membrane in the presence of albumin. The importance of the interaction between NHERF2 and the cytoskeleton was demonstrated by a significant reduction in albumin uptake in cells overexpressing an ezrin binding-deficient mutant of NHERF2. Thus NHERF1 and NHERF2 differentially regulate albumin uptake by mechanisms that ultimately alter the cell-surface levels of ClC-5.

Na+-H+ exchanger regulatory factor 1 is a PDZ scaffold for the astroglial glutamate transporter GLAST

Glutamate is a key neurotransmitter and its levels in the synaptic cleft are tightly regulated by reuptake mechanisms that primarily involve transporters in astrocytes. This requires that the glutamate transporters be spatially constrained to effect maximum glutamate transport. GLAST (EAAT1) is the predominant astroglial transporter and contains a class I PDZ‐binding consensus (ETKM) in its C‐terminus. The epithelial Na+/H+ exchanger regulatory factors NHERF1 and NHERF2 are PDZ proteins that contain two tandem PDZ domains and a C‐terminal domain that binds members of the ERM (ezrin–radixin–moesin) family of membrane‐cytoskeletal adaptors. NHERF proteins have been extensively characterized in renal epithelia and their expression in brain has recently been reported; however, their function in the brain remains unknown. The aims of the current study were to (1) determine the distribution of NHERF1/2 in the rodent brain and (2) investigate whether GLAST was a physiological ligand for NHERF1/2. Immunohistochemistry revealed that NHERF1 expression was widespread in rat brain (abundant in cerebellum, cerebral cortex, hippocampus, and thalamus) and primarily restricted to astrocytes whereas NHERF2 expression was primarily restricted to endothelial cells of blood vessels and capillaries. Importantly, NHERF1 distribution closely matched that of GLAST and confocal imaging demonstrated co‐localization of the two proteins. Co‐immunoprecipitation demonstrated that GLAST, NHERF1, and ezrin associate in vivo. In vitro binding assays showed that GLAST bound directly to the PDZ1 domain of NHERF1 via the C‐terminal ETKM motif of GLAST. These findings implicate the GLAST–NHERF1 complex in the regulation of glutamate homeostasis in astrocytes.

Rapid loss of glutamine synthetase from astrocytes in response to hypoxia: Implications for excitotoxicity

We have examined brains of neonatal pigs that were rendered hypoxic. Glutamine synthetase (GS), a key enzyme in the detoxification of glutamate and ammonia, was rapidly lost from astrocytes in regions susceptible to damage, including the CA1 of hippocampus and various cortical regions. Conversely, resilient areas such as the dentate gyrus exhibited little or no loss of GS. Onset of loss was rapid, patches of loss being evident by 1h post-insult, and loss was extensive by 24h and did not recover by 72 h. Examination of counterstained sections revealed that GS losses preceded any overt neuronal damage. Loss of GS from astrocytes would plausibly lead to a rise in intracellular glutamate, and could explain why reversal of astrocytic glutamate transport during hypoxia/ischaemia is conceptually possible.

In vivo visualization of albumin degradation in the proximal tubule

Albuminuria is a key marker of renal injury and a major risk factor for cardiovascular disease. In vivo imaging techniques with fluorescent albumin have allowed visualization of its movement within the whole kidney but they could not distinguish between intact and degraded albumin. To visualize albumin degradation in proximal tubular cells in vivo we used an albumin conjugate (dye quenched (DQ)-albumin), which only fluoresces when it is degraded. In cultured proximal tubule cells, the fluorescent signal from DQ-albumin was dependent on endocytosis and lysosomal function and showed that at any time about 40% of endocytosed DQ-albumin was degraded. Significant accumulation of conventional Texas Red-labeled albumin and degraded DQ-albumin was found in rat proximal tubules 5 min after injection. Importantly, no hint of DQ-albumin was detected in the serum, suggesting that the fluorescent signal in the proximal tubules was derived from tubular degradation of intact albumin. Our study shows that DQ-albumin, together with conventional fluorescent conjugates of intact albumin, can be used to visualize albumin degradation by proximal tubules in vivo.

Na+-H+ Exchanger Regulatory Factor 1 (NHERF1) PDZ Scaffold Binds an Internal Binding Site in the Scavenger Receptor Megalin

The scavenger receptor megalin binds to albumin in the microvilli of the renal proximal tubule, and transports the ligand to the intravillar cleft for processing by endocytosis. Albumin endocytosis in the proximal tubule is regulated by protein complexes containing a number of transmembrane and accessory proteins including PDZ scaffolds such as NHERF1 and NHERF2. PDZ scaffold proteins bind to class I PDZ binding motifs (S/T-X-Φ) in the extreme C-terminus of targets. Megalin contains a functional PDZ binding motif (SDV) in its distal terminus, however a potential interaction with the NHERF proteins has not been investigated. As megalin associates with NHE3 in the microvilli and NHE3 is tethered to the intravillar cleft via its interaction with NHERF1, we investigated if there is a direct interaction between megalin and NHERF1 in renal proximal tubule cells. Using confocal microscopy we determined that megalin and NHERF1 co-localise in the apical region in proximal tubule cells. Immunoprecipitation experiments performed using rat kidney lysate indicated that megalin bound NHERF1 in vivo. Using fusion proteins and peptides, we determined that PDZ2 of NHERF1 bound to megalin and that this interaction was via the C-terminus of megalin directly and in the absence of any accessory protein. We next investigated which domain in megalin was regulating this interaction. Using GST fusion proteins we determined that the loss of the most distal C-terminus of megalin containing the PDZ binding motif (SDV) did not alter its ability to bind to NHERF1. Significantly, we then identified an internal NHERF binding domain in the C-terminus of megalin. Using peptide studies we were able to demonstrate that NHERF1 bound to an internal PDZ binding motif in megalin and that a loss of a single threonine residue abolished the interaction between megalin and NHERF1. Finally, in proximal tubule cells, silencing NHERF1 increased megalin expression. Therefore, we have identified a novel protein interaction in proximal tubule cells and specifically identified a new internal PDZ binding motif in the C-terminus of megalin.

Excitatory amino acid transporter 5 is widely expressed in peripheral tissues.

It is routinely stated in the literature that Excitatory Amino Acid Transporter 5 (EAAT5) is a retina-specific glutamate transporter. EAAT5 is expressed by retinal photoreceptors and bipolar cells, where it serves as a slow transporter and as an inhibitory glutamate receptor, the latter role is due to the gating of a large chloride conductance. The dogma of an exclusively retinal distribution has arisen because Northern blot analyses have previously shown only modest hybridisation in non-retinal tissues. Others have re-interpreted this as indicating that EAAT5 was only present in retinal tissues. However, this view appears to be erroneous; recent evidence demonstrating abundant expression of EAAT5 in rat testis prompted us to re-examine this dogma. A new antibody was developed to an intracellular loop region of rat EAAT5. This new tool, in concert with RT-PCR and sequencing, demonstrated that EAAT5 is widely distributed at the mRNA and protein levels in many non-nervous tissues including liver, kidney, intestine, heart, lung, and skeletal muscle. We conclude that EAAT5 is a widely distributed protein. Whether it functions in all locations as a glutamate transporter, or mainly as a glutamate-gated chloride conductance, remains to be determined.

Alternate splicing and expression of the glutamate transporter EAAT5 in the rat retina

Excitatory amino acid transporter 5 (EAAT5) is an unusual glutamate transporter that is expressed in the retina, where it is localised to two populations of glutamatergic neurons, namely the bipolar neurons and photoreceptors. EAAT5 exhibits two distinct properties, acting both as a slow glutamate transporter and as a glutamate-gated inhibitory receptor. The latter property is attributable to a co-associated chloride conductance. EAAT5 has previously been thought to exist only as a full-length form. We now demonstrate by PCR cloning and sequencing, the presence of five novel splice variant forms of EAAT5 which skip either partial or complete exons in the rat retina. Furthermore, we demonstrate that each of these variants is expressed at the protein level as assessed by Western blotting using splice-specific antibodies that we have generated. We conclude that EAAT5 exists in multiple spliced forms, and propose, based upon retention or absence of key structural features, that these variant forms may potentially exhibit distinct properties relative to the originally described form of EAAT5.