Motoneuronal cell death is not correlated with aggregate formation of androgen receptors containing an elongated polyglutamine tract

Spinal and bulbar muscular atrophy (SBMA) is associated with an abnormal expansion of the (CAG)(n)repeat in the androgen receptor (AR) gene. Similar mutations have been reported in other proteins that cause neurodegenerative disorders. The CAG-coded elongated polyglutamine (polyGln) tracts induce the formation of neuronal intracellular aggregates. We have produced a model to study the effects of potentially 'neurotoxic' aggregates in SBMA using immortalized motoneuronal cells (NSC34) transfected with AR containing polyGln repeats of different sizes [(AR.Q(n = 0, 23 or 46)]. Using chimeras of AR.Q(n) and the green fluorescent protein (GFP), we have shown that aggregate formation occurs when the polyGln tract is elongated and AR is activated by androgens. In NSC34 cells co-expressing the AR with the polyGln of pathological length (AR.Q46) and the GFP we have noted the presence of several dystrophic neurites. Cell viability analyses have shown a reduced growth/survival rate in NSC34 expressing the AR.Q46, whereas testosterone treatment partially counteracted both cell death and the formation of dystrophic neurites. These observations indicate the lack of correlation between aggregate formation and cell survival, and suggest that neuronal degeneration in SBMA might be secondary to axonal/dendritic insults.     

CHIP deletion reveals functional redundancy of E3 ligases in promoting degradation of both signaling proteins and expanded glutamine proteins

CHIP (carboxy terminus of Hsc70-interacting protein) an E3 ubiquitin ligase that binds to Hsp70 and Hsp90, promotes degradation of several Hsp90-regulated signaling proteins and disease-causing proteins containing expanded glutamine tracts. In polyglutamine disease models, CHIP has been considered a primary protection factor by promoting degradation of these misfolded proteins. Here, we show that two CHIP substrates, the glucocorticoid receptor (GR), a classic Hsp90-regulated signaling protein, and the expanded glutamine androgen receptor (AR112Q), are degraded at the same rate in CHIP(-/-) and CHIP(+/+) mouse embryonic fibroblasts after treatment with the Hsp90 inhibitor geldanamycin. CHIP(-/-) cytosol has the same ability as CHIP(+/+) cytosol to ubiquitinate purified neuronal nitric oxide synthase (nNOS), another established CHIP substrate. To determine whether other E3 ubiquitin ligases that bind to Hsp70 (Parkin) or Hsp90 (Mdm2) act on CHIP substrates, each E3 ligase was co-expressed with the GR, nNOS, AR112Q or Q78 ataxin-3. CHIP lowered the levels of all four proteins, Parkin acted on nNOS and Q78 ataxin-3 but not on the steroid receptors, and Mdm2 did not affect any of the co-expressed proteins. Moreover, both CHIP and Parkin co-localized to aggregates of the expanded glutamine AR formed in cell culture and in a knock-in mouse model of spinal and bulbar muscular atrophy. These observations establish that CHIP does not play an exclusive role in regulating the turnover of Hsp90 client signaling proteins or expanded glutamine tract proteins, and show that the Hsp70-dependent E3 ligase Parkin acts redundantly to CHIP on some substrates.     

Huntingtin-associated protein 1 (HAP1) interacts with androgen receptor (AR) and suppresses SBMA-mutant-AR-induced apoptosis

Huntingtin-associated protein 1 (HAP1), an interactor of huntingtin, has been known as an essential component of the stigmoid body (STB) and recently reported to play a protective role against neurodegeneration in Huntington's disease (HD). In the present study, subcellular association between HAP1 and androgen receptor (AR) with a long polyglutamine tract (polyQ) derived from spinal-and-bulbar-muscular-atrophy (SBMA) was examined using HEp-2 cells cotransfected with HAP1 and/or normal ARQ25, SBMA-mutant ARQ65 or deletion-mutant AR cDNAs. The results provided the first clear evidence that HAP1 interacts with AR through its ligand-binding domain in a polyQ-length-dependent manner and forms prominent inclusions sequestering polyQ-AR, and that addition of dihydrotestosterone reduces the association strength of HAP1 with ARQ25 more dramatically than that with ARQ65. Furthermore, SBMA-mutant-ARQ65-induced apoptosis was suppressed by cotransfection with HAP1. Our findings strongly suggest that HAP1/STB is relevant to polyQ-length-dependent modification on subcellular AR functions and critically involved in pathogenesis of not only HD but also SBMA as an important intrinsic neuroprotectant determining the threshold for cellular vulnerability to apoptosis. Taking together with previous reports that HAP1/STB is selectively expressed in the brain regions spared from degenerative targets in HD and SBMA, the current study might explain the region-specific occurrence of neurodegeneration in both diseases, shedding light on common aspects of their molecular pathological mechanism and yet-to-be-uncovered diagnostic or therapeutic applications for HD and SBMA patients.     

Progressive decrease in chaperone protein levels in a mouse model of Huntington's disease and induction of stress proteins as a therapeutic approach

The manipulation of chaperone levels has been shown to inhibit aggregation and/or rescue cell death in Saccharomyces cerevisiae, Caenorhabditis elegans, Drosophila melanogaster and cell culture models of Huntington's disease (HD) and other polyglutamine (polyQ) disorders. We show here that a progressive decrease in Hdj1, Hdj2, Hsp70, alphaSGT and betaSGT brain levels likely contributes to disease pathogenesis in the R6/2 mouse model of HD. Despite a predominantly extranuclear location, Hdj1, Hdj2, Hsc70, alphaSGT and betaSGT were found to co-localize with nuclear but not with extranuclear aggregates. Quantification of Hdj1 and alphaSGT mRNA levels showed that these do not change and therefore the decrease in protein levels may be a consequence of their sequestration to aggregates, or an increase in protein turnover, possibly as a consequence of their relocation to the nucleus. We have used genetic and pharmacological approaches to assess the therapeutic potential of chaperone manipulation. Ubiquitous overexpression of Hsp70 in the R6/2 mouse (as a result of crossing to Hsp70 transgenics) delays aggregate formation by 1 week, has no effect on the detergent solubility of aggregates and does not alter the course of the neurological phenotype. We used an organotypic slice culture assay to show that pharmacological induction of the heat shock response might be a more useful approach. Radicicol and geldanamycin could both maintain chaperone induction for at least 3 weeks and alter the detergent soluble properties of polyQ aggregates over this time course.     

The role of pre-existing aggregates in Hsp104-dependent polyglutamine aggregate formation and epigenetic change of yeast prions

Amyloid-like protein aggregates have been implicated in various diseases and in the protein-based inheritance of yeast prions. The molecular chaperone Hsp104 has been shown to be necessary for the aggregate formation of polyglutamine in yeast, and for the maintenance of several yeast prion phenotypes through the formation of self-propagating aggregates. In this paper, we show that the polyglutamine aggregates that are formed independently of Hsp104, are required for Hsp104 to efficiently produce more aggregates. Similarly, in the yeast prion [PSI+] system, Hsp104-dependent epigenetic changes to the [PSI+] prion phenotype require the presence of prion aggregates in the normal [psi-] state. We also show that the co-localization of different prion aggregates suggests that cross-seeding by different yeast prions increases the probability of Hsp104-dependent epigenetic change. These findings highlight the role of pre-existing aggregates in chaperone-dependent establishment of the epigenetic trait in yeast prions, and possibly in the pathology of several neurodegenerative diseases.     

Polyglutamine length-dependent interaction of Hsp40 and Hsp70 family chaperones with truncated N-terminal huntingtin: their role in suppression of aggregation and cellular toxicity

Huntington's disease (HD) is an autosomal dominant neurodegenerative disorder caused by polyglutamine expansion in the disease protein, huntingtin. In HD patients and transgenic mice, the affected neurons form characteristic ubiquitin-positive nuclear inclusions (NIs). We have established ecdysone-inducible stable mouse Neuro2a cell lines that express truncated N-terminal huntingtin (tNhtt) with different polyglutamine lengths which form both cytoplasmic and nuclear aggregates in a polyglutamine length- and inducer dose-dependent manner. Here we demonstrate that newly synthesized polyglutamine-expanded truncated huntingtin interacts with members of Hsp40 and Hsp70 families of chaperones in a polyglutamine length-dependent manner. Of these interacting chaperones, only Hdj-2 and Hsc70 frequently (Hdj-2 > Hsc70) co-localize with both the aggregates in the cellular model and with the NIs in the brains of HD exon 1 transgenic mice. However, Hdj-2 and Hsc70 do not co-localize with cytoplasmic aggregates in the brains of transgenic mice despite these chaperones being primarily localized in the cytoplasmic compartment. This strongly suggests that the chaperone interaction and their redistribution to the aggregates are two completely different phenomena of the cellular unfolded protein response. This unfolded protein response is also evident from the dramatic induction of Hsp70 on expression of polyglutamine-expanded protein in the cellular model. Transient overexpression of either Hdj-1 or Hsc70 suppresses the aggregate formation; however, suppression efficiency is much higher in Hdj-1 compared with Hsc70. Overexpression of Hdj-1 and Hsc70 is also able to protect cell death caused by polyglutamine-expanded tNhtt and their combination proved to be most effective.     

Initial process of polyglutamine aggregate formation in vivo

BACKGROUND: Polyglutamine expansion in protein is responsible for several inherited neuro-degenerative diseases. The expansion has toxic effects on neural cells as well as results in forming aggregates. Using yeast, we examined the initial process of polyglutamine aggregate formation in vivo. RESULTS: Following expression, polyglutamine tracts were of a soluble form during a lag period, and then formed insoluble complexes. The lag was prolonged and the formation of insoluble complex became slower by decreasing the number of polyglutamine tracts and by a treatment with guanidine hydrochloride. Gel filtration analysis revealed that the soluble polyglutamine existed in a small form. Formation of polyglutamine aggregates appeared to follow similar kinetics reported in the in vitro studies, where polyglutamine tracts self-aggregate in a length-, concentration- and time-dependent manner. However, in vivo, Hsp104 was required for the conversion from a soluble to an insoluble state. Without Hsp104, polyglutamine tracts tended to remain in a small soluble form, prolonging the lag. Moreover, the dependency on Hsp104 for aggregate formation was strong with the short polyglutamine tract, and decreased with the long polyglutamine tract. CONCLUSION: For polyglutamine aggregate formation, a balance of parameters including the length of the polyglutamine tract, Hsp104, and level of polyglutamine expression determined its efficiency.     

Novel mechanism of Hsp70 chaperone-mediated prevention of polyglutamine aggregates in a cellular model of huntington disease

The key feature of polyglutamine aggregates accumulating in the course of Huntington disease (HD) is their resistance to protein denaturants, and to date only chaperones are proved to prevent mutant protein aggregation. It was suggested that expanded polyglutamine chains (polyQ) of mutant huntingtin are cross-linked to other proteins such as glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Here we clarify the roles of GAPDH and molecular chaperone Hsp70 in the formation of sodium dodecyl sulfate (SDS)-insoluble polyQ aggregates. First, the addition of pure GAPDH was found to enhance the aggregation of polyQ in a cell-free model of HD. Secondly, the immunodepletion of GAPDH dose-dependently decreased polyQ aggregation. Finally, siRNA-mediated inhibition of GAPDH protein in SK-N-SH neuroblastoma cells has also reduced the aggregation of cellular polyQ. Regulated over-expression of Hsp70 decreased the amount of GAPDH associated with SDS-insoluble polyQ aggregates. Physical association of Hsp70 and GAPDH in SK-N-SH cells was shown by reciprocal immunoprecipitation and confocal microscopy. Pure Hsp70 dose-dependently inhibited the formation of polyQ aggregates in cell-free model of HD by sequestering both GAPDH and polyQ. We demonstrated that Hsp70 binds to polyQ in adenosine triphosphate-dependent manner, which suggests that Hsp70 exerts a chaperoning activity in the course of this interaction. Binding of Hsp70 to GAPDH was nicotinamide adenine dinucleotide-dependent suggesting another type of association. Based on our findings, we conclude that Hsp70 protects cells in HD by removing/sequestering two intrinsic components of protein aggregates: the polyQ itself and GAPDH. We propose that GAPDH might be an important target for pharmacological treatment of HD and other polyglutamine expansion-related diseases.     

Overexpression of yeast hsp104 reduces polyglutamine aggregation and prolongs survival of a transgenic mouse model of Huntington's disease

Huntington's disease is a devastating neurodegenerative condition associated with the formation of intraneuronal aggregates by mutant huntingtin. Aggregate formation is a property shared by the nine related diseases caused by polyglutamine codon expansion mutations and also by other neurodegenerative conditions like Parkinsons's disease. The roles of aggregates and aggregation in these diseases have been a subject of heated controversy. Here, we have addressed the question in vivo by generating a new transgenic mouse overexpressing the yeast chaperone hsp104, as hsp104 overexpression reduced mutant huntingtin aggregation and toxicity in cell models. Hsp104 has no close mammalian orthologues and does not appear to have effects on mammalian cell death pathways. We crossed hsp104 transgenic mice with mice expressing the first 171 residues of mutant huntingtin. Hsp104 reduced aggregate formation and prolonged the lifespan of the HD mice by 20%. This protection may be mediated at the level of changing the conformation of a putative toxic monomer, reducing oligomerization or aggregation, reducing the levels of oligomeric species or aggregates or combinations of these non-mutually exclusive possibilities.     

Hsc70/Hsp40 chaperone system mediates the Hsp90-dependent refolding of firefly luciferase

BACKGROUND: The 90-kDa heat shock protein, Hsp90, was previously shown to capture firefly luciferase during thermal inactivation, thereby preventing its irreversible off-pathway aggregation and maintaining it in a folding-competent state. However, subsequent refolding of the luciferase required addition of rabbit reticulocyte lysate. RESULTS: Here we demonstrate that Hsc70 (cytosolic Hsp70) and Hsp40/Hdj1 (cytosolic DnaJ homologue) are the effective components in a reticulocyte lysate, while other unidentified factor in the lysate is also required for the refolding of Hsp90-captured luciferase. Though another cytosolic DnaJ homologue, Hdj2/HSDJ, was more efficient than Hsp40 in suppressing the aggregation of rhodanese, Hdj2 was less effective for the refolding of luciferase than Hsp40. In the absence of the third factor, Hsp40 could bind to the luciferase captured by Hsp90, which suggested that Hsp40 on its own was able to bind the substrate protein, but Hsc70 could not. CONCLUSIONS: Hsc70, Hsp40 and at least another additional component in the reticulocyte lysate are necessary for full accomplishment of the refolding of Hsp90-captured luciferase. The third factor may be required for the loading of Hsc70 on to the substrate protein bound to Hsp90.     

GRP78 up-regulation is associated with androgen receptor status, Hsp70-Hsp90 client proteins and castrate-resistant prostate cancer

GRP78/BiP is a key member of the molecular chaperone heat shock protein (Hsp) 70 family. It has a critical role in prostate cancer (PC) including Pten loss‐driven carcinogenesis, but the molecular basis of this remains unclear. We investigated the effect of GRP78 and its putative client proteins, including androgen receptor (AR) in clinical PC. Expression of GRP78 and key Hsp70–hsp90 client proteins (HER2, HER3, AR and AKT) were studied in an incidence tissue microarray (TMA) of prostate cancer. The relationship of GRP78 and AR was further tested in in vitro cell models (LNCaP and its derived LNCaP‐CR subclone) and a matched TMA of hormone‐naïve (HNPC) and castrate‐resistant prostate cancer (CRPC). In vitro and in vivo expression of GRP78 and client proteins were assessed by western blotting and immunohistochemistry, respectively, using the weighted histoscore method. Significant co‐expression of GRP78, pAKT, HER2, HER3 and AR was observed in PC. Abnormal AR, GRP78 and pAKT expression have significant impact on patient survival. GRP78 expression in AR⁺ tumours was significantly higher than in AR^? tumours. In keeping with our clinical data, activation of AR by dihydrotestosterone (DHT) potently activated GRP78 expression in both LNCaP and LNCaP‐CR cells. For the first time, using a matched HNPC and CRPC TMA, enhanced cytoplasmic and membranous GRP78 expression was observed in CRPC. Future prospective studies are therefore warranted to validate GRP78 as prognostic marker and therapeutic target, in the context of the AR and pAKT status. In summary, GRP78 is co‐expressed with Hsp70–hsp90 client proteins. Up‐regulated expression of AR and GRP78 expression in untreated prostate cancer predicts a less favourable outcome. This points to the importance of understanding in the molecular interaction among AR, GRP78 and AKT. Copyright © 2010 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Genetic modulation of polyglutamine toxicity by protein conjugation pathways in Drosophila

Spinal and bulbar muscular atrophy (SBMA) is a heritable neurodegenerative disease caused by the expansion of a polyglutamine [poly(Q)] repeat within the androgen receptor (AR) protein. We studied SBMA in Drosophila using an N-terminal fragment of the human AR protein. Expression of a pathogenic AR protein with an expanded poly(Q) repeat in Drosophila results in nuclear and cytoplasmic inclusion formation, and cellular degeneration, preferentially in neuronal tissues. We have studied the influence of ubiquitin-dependent modification and the proteasome pathway on neural degeneration and AR protein fragment solubility. Compromising the ubiquitin/proteasome pathway enhances degeneration and decreases poly(Q) protein solubility. Our data further suggest that Hsp70 and the proteasome act in an additive manner to modulate neurodegeneration. Through the over-expression of a mutant of the SUMO-1 activating enzyme Uba2, we further show that poly(Q)-induced degeneration is intensified when the cellular SUMO-1 protein conjugation pathway is altered. These data suggest that post-translational protein modification, including the ubiquitin/proteasome and the SUMO-1 pathways, modulate poly(Q) pathogenesis.     

Newly imported proteins in mitochondria are particularly sensitive to aggregation

Aim

A functional proteome is essential for life and maintained by protein quality control (PQC) systems in the cytosol and organelles. Protein aggregation is an indicator of a decline of PQC linked to aging and disease. Mitochondrial PQC is critical to maintain mitochondrial function and thus cellular fitness. How mitochondria handle aggregated proteins is not well understood. Here we tested how the metabolic status impacts on formation and clearance of aggregates within yeast mitochondria and assessed which proteins are particularly sensitive to denaturation.

Methods

Confocal microscopy, electron microscopy, immunoblotting and genetics were applied to assess mitochondrial aggregate handling in response to heat shock and ethanol using the mitochondrial disaggregase Hsp78 as a marker for protein aggregates.

Results

We show that aggregates formed upon heat or ethanol stress with different dynamics depending on the metabolic state. While fermenting cells displayed numerous small aggregates that coalesced into one large foci that was resistant to clearance, respiring cells showed less aggregates and cleared these aggregates more efficiently. Acute inhibition of mitochondrial translation had no effect, while preventing protein import into mitochondria by inhibition of cytosolic translation prevented aggregate formation.

Conclusion

Collectively, our data show that the metabolic state of the cells impacts the dynamics of aggregate formation and clearance, and that mainly newly imported and not yet assembled proteins are prone to form aggregates. Because mitochondrial functionality is crucial for cellular metabolism, these results highlight the importance of efficient protein biogenesis to maintain the mitochondrial proteome operational during metabolic adaptations and cellular stress.     

Molecular chaperones enhance the degradation of expanded polyglutamine repeat androgen receptor in a cellular model of spinal and bulbar muscular atrophy

Spinal and bulbar muscular atrophy (SBMA) is one of a growing number of neurodegenerative diseases caused by a polyglutamine-encoding CAG trinucleotide repeat expansion, and is caused by an expansion within exon 1 of the androgen receptor (AR) gene. The family of polyglutamine diseases is characterized by the presence of ubiquitinated, intranuclear inclusions associated with molecular chaperones and 26S proteasome components, although the role of these inclusions in the pathogenesis of polyglutamine diseases remains unclear. The over-expression of molecular chaperones of the Hsp70 and Hsp40 families has been shown to modulate inclusion frequency and cellular toxicity. We developed a cell culture system which enables the quantitative analysis of the effects of molecular chaperones on the biochemical properties of an expanded repeat AR. Using this approach, we demonstrate that Hsp70 and its co-chaperone Hsp40 not only increase expanded repeat AR solubility, but function to enhance the degradation of expanded repeat AR through the proteasome. Furthermore, our studies indicate that these molecular chaperones significantly decrease the half-life of an expanded repeat AR. Molecular chaperone enhancement of protein degradation points to the modulation of molecular chaperones as a potential therapeutic target for polyglutamine diseases.     

Fetal and Maternal Red Cell Immune Adherence (RCIA) Receptors*

ABSTRACT: The addition of autologous serum to mixtures containing human red cells, from pregnant and nonpregnant females, and sheep red cells resulted in the formation of mixed aggregates containing both human and sheep red cells. In contrast, no aggregate formation occurred when autologous cord serum was addded to mixtures containing cord red cells and sheep red cells. Heat inactivation of the adult serum or the presence of 0.15 M EDTA prevented the formation of mixed aggregates. These observations indicated that the mixed aggregates occurred through the complement-dependent red cell immune adherence (RCIA) phenomenon. The addition of untreated cord serum to mixtures containing inactivated adult serum restored the formation of mixed aggregates, indicating that the cord serum contained sufficient complement for RCIA. Natural antibody against sheep red cells was present in adult sera but was absent in cord sera. Using the RCIA receptor assay, the RCIA receptor activity of cord red cells was found to exceed significantly that of the adult pregnant cells (p < 0.0025). It is postulated that this may represent an aspect of immune adaptation between mother and fetus.     

Involvement of valosin-containing protein (VCP)/p97 in the formation and clearance of abnormal protein aggregates

Abnormal protein aggregates are commonly observed in affected neurons in many neurodegenerative disorders. We have reported that valosin-containing protein (VCP) co-localizes with protein aggregates in patients' neurons and in cultured cells expressing diseased proteins. However, the significance of such co-localization remains elucidated. Here we report the involvement of VCP in the re-solubilization process of abnormal protein aggregates. VCP recognized and accumulated onto pre-formed protein aggregates created by proteasome inhibition. VCP knockdown or the expression of dominant-negative VCP both significantly delayed the elimination of ubiquitin-positive aggregates. VCP was involved in the clearance of pre-formed polyglutamine aggregates as well. Paradoxically, VCP knockdown also diminished polyglutamine aggregate formation. Furthermore, its ATPase activity was required for the re-solubilization and re-activation of heat-denatured proteins, such as luciferase, from insoluble aggregates. We thus propose that VCP functions as a mediator for both aggregate formation and clearance depending upon the concentration of soluble aggregate-prone proteins, indicating dual VCP functions as an aggregate formase and an unfoldase.     

Glucocorticoid modulation of androgen receptor nuclear aggregation and cellular toxicity is associated with distinct forms of soluble expanded polyglutamine protein.

Spinobulbar muscular atrophy is a progressive motor neuron disease caused by abnormal polyglutamine tract expansion in the androgen receptor (AR) gene, and is part of a family of central nervous system (CNS) neurodegenerative diseases, including Huntington's disease (HD). Each pathologic protein is widely expressed, but the cause of neuronal degeneration within the CNS remains unknown. Many reports now link abnormal polyglutamine protein aggregation to pathogenesis. A previous study reported that activation of the wild-type glucocorticoid receptor (wtGR) suppressed the aggregation of expanded polyglutamine proteins derived from AR and huntingtin, whereas a mutant receptor containing an internal deletion, GRDelta108-317, increased polyglutamine protein aggregation, in this case primarily within the nucleus. In this study, we use these two forms of GR to study expanded polyglutamine AR protein in different cell contexts. Using cell biology and biochemical approaches, we find that wtGR promotes soluble forms of the protein and prevents nuclear aggregation in NIH3T3 cells and cultured neurons. In contrast, GRDelta108-317 decreases polyglutamine protein solubility, and causes formation of nuclear aggregates in non-neuronal cells. Nuclear aggregates recruit hsp72 more rapidly than cytoplasmic aggregates, and are associated with decreased cell viability. Limited proteolysis and chemical cross-linking suggest unique soluble forms of the expanded AR protein underlie these distinct biological activities. These observations provide an experimental framework to understand why expanded polyglutamine proteins may be toxic only to certain populations of cells, and suggest that unique protein associations or conformations of expanded polyglutamine proteins may determine subsequent cellular effects such as nuclear localization and cellular toxicity.     

Polyglutamine protein aggregation and toxicity are linked to the cellular stress response

Chronic exposure of cells to expanded polyglutamine proteins results in eventual cell demise. We constructed mouse cell lines expressing either the full-length androgen receptor (AR), or truncated forms of AR containing 25 or 65 glutamines to study the cellular consequences of chronic low-level exposure to these proteins. Expression of the polyglutamine-expanded truncated AR protein, but not the full-length expanded protein, resulted in the formation of cytoplasmic and nuclear aggregates and eventual cell death. Nuclear aggregates preferentially stained positive for heat shock protein (hsp)72, a sensitive indicator of a cellular stress response. Biochemical studies revealed that the presence of nuclear aggregates correlated with activation of the c-jun NH2-terminal kinase (JNK). Different metabolic insults, including heat shock treatment, and exposure to sodium arsenite or menadione, proved more toxic to those cells expressing the polyglutamine-expanded truncated protein than to cells expressing the non-expanded form. Cells containing cytoplasmic polyglutamine-protein aggregates exhibited a delayed expression of hsp72 after heat shock. Once expressed, hsp72 failed to localize normally and instead was sequestered within the protein aggregates. This was accompanied by an inability of the aggregate-containing cells to cease their stress response as evidenced by the continued presence of activated JNK. Finally, activation of the cellular stress response increased the overall extent of polyglutamine protein aggregation, especially within the nucleus. Inclusion of a JNK inhibitor reduced this stress-dependent increase in nuclear aggregates. Abnormal stress responses may contribute to enhanced cell vulnerability in cells expressing polyglutamine-expanded proteins and may increase the propensity of such cells to form cytoplasmic and nuclear inclusions.     

Specific N-terminal mutations in the human androgen receptor induce cytotoxicity

Polyglutamine (polyQ) stretch amplification in different proteins causes neurodegenerative disease. These proteins form intracellular aggregates thought to be cytotoxic but differ in pathology and tissue specificity. Here, we demonstrate that specific sequences outside the polyQ stretch of the human androgen receptor contribute to polyQ pathology. An exchange of two N-terminal serine phosphorylation residues to alanine in the wild type androgen receptor (ARQ22dm) resulted in cytoplasmic accumulation and increased early hormone-dependent aggregation of the receptor. In a Drosophila model, the ARQ22dm was cytotoxic, and developing larvae expressing this receptor showed behavioral abnormalities and severely impaired locomotion. In contrast, the same double mutation in an androgen receptor with an extended polyQ stretch was less toxic. The response of the receptors to inhibitors of polyglutamine toxicity is altered by the amino acid exchanges suggesting that careful consideration is needed in the choice of potential therapies of disorders involving toxic polyQ species.