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ABSTRACT: Mitochondrial dysfunction is associated with neurodegenerative diseases and mutations in the HSPD1 gene, encoding the mitochondrial Hsp60 chaperone, are the causative factors of two neurodegenerative diseases, hereditary spastic paraplegia and MitChap60 disease. In cooperation with Hsp10, Hsp60 forms a barrel-shaped complex, which encloses unfolded polypeptides and provides an environment facilitating folding. We have generated an Hsp60 variant with a mutation (Asp423Ala) in the ATPase domain and established a stable human embryonic kidney (HEK293) cell line allowing tetracycline-controlled expression of this mutant variant. We monitored expression of the Hsp60-Asp423Ala variant protein following induction and examined its effects on cellular properties. We showed that the folding of mitochondrial-targeted green fluorescent protein, a well-known substrate protein of Hsp60, was consistently impaired in cells expressing Hsp60-Asp423Ala. The level of the Hsp60-Asp423Ala variant protein increased over time upon induction, cell proliferation stopped after 48-h induction and mitochondrial membrane potential decreased in a time-dependent manner. In summary, we have established a stable cell line with controllable expression of an Hsp60 variant, which allows detailed studies of different degrees of Hsp60 deficiency
Cell Stress Chaperones. 06/2011;
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ABSTRACT: The mitochondrial Hsp60 chaperonin plays an important role in sustaining cellular viability. Its dysfunction is related to inherited forms of the human diseases spastic paraplegia and hypomyelinating leukodystrophy. However, it is unknown whether the requirement for Hsp60 is neuron specific or whether a complete loss of the protein will impair mammalian development and postnatal survival. In this study, we describe the generation and characterization of a mutant mouse line bearing an inactivating gene-trap insertion in the Hspd1 gene encoding Hsp60. We found that heterozygous mice were born at the expected ratio compared to wild-type mice and displayed no obvious phenotype deficits. Using quantitative reverse transcription PCR, we found significantly decreased levels of the Hspd1 transcript in all of the tissues examined, demonstrating that the inactivation of the Hspd1 gene is efficient. By Western blot analysis, we found that the amount of Hsp60 protein, compared to either cytosolic tubulin or mitochondrial voltage-dependent anion-selective channel protein 1/porin, was decreased as well. The expression of the nearby Hspe1 gene, which encodes the Hsp10 co-chaperonin, was concomitantly down regulated in the liver, and the protein levels in all tissues except the brain were reduced. Homozygous Hspd1 mutant embryos, however, died shortly after implantation (day 6.5 to 7.5 of gestation, Theiler stages 9-10). Our results demonstrate that Hspd1 is an essential gene for early embryonic development in mice, while reducing the amount of Hsp60 by inactivation of one allele of the gene is compatible with survival to term as well as postnatal life
Cell Stress.Chaperones. 11/2010; 15(6).
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P. Bross,
S. Naundrup, J. Hansen,
M.N. Nielsen,
J.H. Christensen,
M. Kruhoffer,
J. Palmfeldt,
T.J. Corydon,
N. Gregersen,
D. Ang,
C. Georgopoulos,
K.L. Nielsen
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ABSTRACT: We have previously reported the association of a mutation (c.292G>A/p.Val98Ile) in the human HSPD1 gene that encodes the mitochondrial Hsp60 chaperonin with a dominantly inherited form of hereditary spastic paraplegia. Here, we show that the purified Hsp60-(p.Val98Ile) chaperonin displays decreased ATPase activity and exhibits a strongly reduced capacity to promote folding of denatured malate dehydrogenase in vitro. To test its in vivo functions, we engineered a bacterial model system that lacks the endogenous chaperonin genes and harbors two plasmids carrying differentially inducible operons with human Hsp10 and wild type Hsp60 or Hsp10 and Hsp60-(p.Val98Ile), respectively. Ten hours after shut-down of the wild type chaperonin operon and induction of the Hsp60-(p.Val98Ile)/Hsp10 mutant operon, bacterial cell growth was strongly inhibited. No globally increased protein aggregation was observed and microarray analyses showed that a number of genes involved in metabolic pathways, some of which are essential for robust aerobic growth, were strongly up-regulated in Hsp60-(p.Val98Ile) expressing bacteria, suggesting that the growth arrest was caused by defective folding of some essential proteins. Co-expression of Hsp60-(p.Val98Ile) and wild type Hsp60 exerted a dominant negative effect only when the chaperonin genes were expressed at relatively low levels. Based on our in vivo and in vitro data we propose that the major effect of heterozygosity for the Hsp60-(p.Val98Ile) mutation is a moderately decreased activity of chaperonin complexes composed of mixed wild type and Hsp60-(p.Val98Ile) mutant subunits
J.Biol.Chem. 06/2008; 283(23).
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ABSTRACT: The mitochondrial chaperonin heat shock protein 60 (Hsp60) assists the folding of a subset of proteins localized in mitochondria and is an essential component of the mitochondrial protein quality control system. Mutations in the HSPD1 gene that encodes Hsp60 have been identified in patients with an autosomal dominant form of hereditary spastic paraplegia (SPG13), a late-onset neurodegenerative disorder characterized by a progressive paraparesis of the lower limbs. The disease-associated Hsp60-(p.Val98Ile) protein, encoded by the c.292G>A HSPD1 allele, has reduced chaperonin activity, but how its expression affects mitochondrial functions has not been investigated. We have studied mitochondrial function and expression of genes encoding mitochondrial chaperones and proteases in a human lymphoblastoid cell line and fibroblast cells from a patient who is heterozygous for the c.292G>A HSPD1 allele. We found that both the c.292G>A RNA transcript and the corresponding Hsp60-(p.Val98Ile) protein were present at comparable levels to their wild-type counterparts in SPG13 patient cells. Compared with control cells, we found no significant cellular or mitochondrial dysfunctions in SPG13 patient cells by assessing the mitochondrial membrane potential, cell viability, and sensitivity toward oxidative stress. However, a decreased expression of the mitochondrial protein quality control proteases Lon and ClpP, both at the RNA and protein level, was demonstrated in SPG13 patient cells. We propose that decreased levels of mitochondrial proteases Lon and ClpP may allow Hsp60 substrate proteins to go through more folding attempts instead of being prematurely degraded, thereby supporting productive folding in cells with reduced Hsp60 chaperonin activity. In conclusion, our studies with SPG13 patient cells expressing the functionally impaired mutant Hsp60 chaperonin suggest that reduction of the degradative activity of the protein quality control system may represent a previously unrecognized cellular adaptation to reduced chaperone function.
Neuroscience 06/2008; 153(2):474-82. · 3.38 Impact Factor
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ABSTRACT: The mitochondrial chaperonin heat shock protein 60 (Hsp60) assists the folding of a subset of proteins localized in mitochondria and is an essential component of the mitochondrial protein quality control system. Mutations in the HSPD1 gene that encodes Hsp60 have been identified in patients with an autosomal dominant form of hereditary spastic paraplegia (SPG13), a late-onset neurodegenerative disorder characterized by a progressive paraparesis of the lower limbs. The disease-associated Hsp60-(p.Val98Ile) protein, encoded by the c.292G>A HSPD1 allele, has reduced chaperonin activity, but how its expression affects mitochondrial functions has not been investigated. We have studied mitochondrial function and expression of genes encoding mitochondrial chaperones and proteases in a human lymphoblastoid cell line and fibroblast cells from a patient who is heterozygous for the c.292G>A HSPD1 allele. We found that both the c.292G>A RNA transcript and the corresponding Hsp60-(p.Val98Ile) protein were present at comparable levels to their wild-type counterparts in SPG13 patient cells. Compared with control cells, we found no significant cellular or mitochondrial dysfunctions in SPG13 patient cells by assessing the mitochondrial membrane potential, cell viability, and sensitivity toward oxidative stress. However, a decreased expression of the mitochondrial protein quality control proteases Lon and ClpP, both at the RNA and protein level, was demonstrated in SPG13 patient cells. We propose that decreased levels of mitochondrial proteases Lon and ClpP may allow Hsp60 substrate proteins to go through more folding attempts instead of being prematurely degraded, thereby supporting productive folding in cells with reduced Hsp60 chaperonin activity. In conclusion, our studies with SPG13 patient cells expressing the functionally impaired mutant Hsp60 chaperonin suggest that reduction of the degradative activity of the protein quality control system may represent a previously unrecognized cellular adaptation to reduced chaperone function
Neuroscience. 05/2008; 153(2).
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ABSTRACT: A mutation in the HSPD1 gene has previously been associated with an autosomal dominant form of spastic paraplegia in a French family. HSPD1 encodes heat shock protein 60, a molecular chaperone involved in folding and quality control of mitochondrial proteins. In the present work we have investigated 23 Danish index patients with hereditary spastic paraplegia (HSP) for mutations in the HSPD1 gene. One patient was found to be heterozygous for a c.1381C > G missense mutation encoding the mutant heat shock protein 60 p.Gln461Glu. The mutation was also present in two unaffected brothers, but absent in 400 unrelated Danish individuals. We found that the function of the p.Gln461Glu heat shock protein 60 was mildly compromised. The c.1381C > G mutation likely represents a novel low-penetrance HSP allele
J.Neurol. 07/2007; 254(7).
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P. Bross,
Z. Li, J. Hansen,
J.J. Hansen,
M.N. Nielsen,
T.J. Corydon,
C. Georgopoulos,
D. Ang,
J.B. Lundemose,
K. Niezen-Koning,
H. Eiberg,
H. Yang,
S. Kolvraa,
L. Bolund,
N. Gregersen
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ABSTRACT: Molecular chaperones assist protein folding, and variations in their encoding genes may be disease-causing in themselves or influence the phenotypic expression of disease-associated or susceptibility-conferring variations in many different genes. We have screened three candidate patient groups for variations in the HSPD1 and HSPE1 genes encoding the mitochondrial Hsp60/Hsp10 chaperone complex: two patients with multiple mitochondrial enzyme deficiency, 61 sudden infant death syndrome cases (MIM: #272120), and 60 patients presenting with ethylmalonic aciduria carrying non-synonymous susceptibility variations in the ACADS gene (MIM: *606885 and #201470). Besides previously reported variations we detected six novel variations: two in the bidirectional promoter region, and one synonymous and three non-synonymous variations in the HSPD1 coding region. One of the non-synonymous variations was polymorphic in patient and control samples, and the rare variations were each only found in single patients and absent in 100 control chromosomes. Functional investigation of the effects of the variations in the promoter region and the non-synonymous variations in the coding region indicated that none of them had a significant impact. Taken together, our data argue against the notion that the chaperonin genes play a major role in the investigated diseases. However, the described variations may represent genetic modifiers with subtle effects
J.Hum.Genet. 01/2007; 52(1).
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ABSTRACT: We have analyzed the role of the highly abundant molecular chaperone Hsp60 in the biogenesis of medium-chain acyl-CoA dehydrogenase (MCAD) using RNA interference (RNAi). MCAD is a mitochondrial enzyme involved in the fatty acid metabolism and previous studies in isolated rat mitochondria or prokaryotic expression systems have shown that Hsp60 and GroEL are involved in the folding of MCAD proteins. To elucidate the impact of Hsp60 levels for folding and assembly of MCAD proteins in intact mammalian cells, we report the design and in vivo synthesis of anti-human Hsp60 small-hairpin RNAs (shRNAs). Quantitative PCR analysis of transfected HEK-293 cells showed significant down-regulation of endogenous Hsp60 mRNA 48h post-transfection and Western blot analysis confirmed the reduced levels of Hsp60 protein. Furthermore, expression of exogenous Myc-tagged Hsp60 was decreased in shRNA-transfected cells. Flow cytometry showed that shRNA-treatment only affects green fluorescent protein targeted to mitochondria, demonstrating that the shRNA effect is specific. In cells with reduced Hsp60 levels both the amounts of total MCAD proteins and folded MCAD were reduced for MCAD wild-type and the two disease-associated variants studied. A similar effect was observed in cells expressing mitochondrial short-chain acyl-CoA dehydrogenase. Thus, in intact human cells we demonstrate that Hsp60 is involved in the folding of MCAD variant proteins. The present system can be used to study the requirement of Hsp60 for folding of other mitochondrial proteins and to assess the role of Hsp60 for the severity of genetic defects involving these proteins
Mol.Genet.Metab. 05/2005; 85(4).
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ABSTRACT: The coordinated activities of chaperones and proteases that supervise protein folding and degradation are important factors for deciding the fate of proteins whose folding is impaired by missense variations. We have studied the role of Lon and ClpXP proteases in handling of wild-type and a folding-impaired disease-associated variant (R28C) of the mitochondrial enzyme medium-chain acyl-CoA dehydrogenase (MCAD). Using an Escherichia coli model system, we co-overexpressed the MCAD variants and the respective proteases at two conditions: at 31 degrees C where R28C MCAD protein folds partially and at 37 degrees C where it misfolds and aggregates. Co-overexpression of Lon protease considerably accelerated the degradation rate of a pool of R28C variant MCAD synthesised during a 30min pulse and counteracted accumulation of aggregates at 37 degrees C, whereas increasing the amounts of ClpXP protease had no clear effect. Co-overexpression of either Lon or ClpXP protease markedly decreased the steady state levels of both wild-type and R28C mutant MCAD at 37 degrees C but not at 31 degrees C. Our results suggest that Lon is more efficient than ClpXP in elimination of non-native MCAD protein conformations, and accordingly, that Lon can recognise a broader spectrum of MCAD protein conformations.
Biochem.Biophys.Res.Commun. 01/2005; 333.
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L. O'Reilly,
P. Bross,
T.J. Corydon,
S.E. Olpin, J. Hansen,
J.M. Kenney,
S.E. McCandless,
D.M. Frazier,
V. Winter,
N. Gregersen,
P.C. Engel,
B.S. Andresen
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ABSTRACT: Medium-chain acyl-CoA dehydrogenase (MCAD) is a homotetrameric flavoprotein which catalyses the initial step of the beta-oxidation of medium-chain fatty acids. Mutations in MCAD may cause disease in humans. A Y42H mutation is frequently found in babies identified by newborn screening with MS/MS, yet there are no reports of patients presenting clinically with this mutation. As a basis for judging its potential consequences we have examined the protein phenotype of the Y42H mutation and the common disease-associated K304E mutation. Our studies of the intracellular biogenesis of the variant proteins at different temperatures in isolated mitochondria after in vitro translation, together with studies of cultured patient cells, indicated that steady-state levels of the Y42H variant in comparison to wild-type were decreased at higher temperature though to a lesser extent than for the K304E variant. To distinguish between effects of temperature on folding/assembly and the stability of the native enzyme, the thermal stability of the variant proteins was studied after expression and purification by dye affinity chromatography. This showed that, compared with the wild-type enzyme, the thermostability of the Y42H variant was decreased, but not to the same degree as that of the K304E variant. Substrate binding, interaction with the natural electron acceptor, and the binding of the prosthetic group, FAD, were only slightly affected by the Y42H mutation. Our study suggests that Y42H is a temperature sensitive mutation, which is mild at low temperatures, but may have deleterious effects at increased temperatures
Eur.J.Biochem. 10/2004; 271(20).
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Humana Press.
