Your search keyword '"Gal, Jozsef"' showing total 7 results

1. Self-assembled FUS binds active chromatin and regulates gene transcription

Author

Yang, Liuqing, Gal, Jozsef, Chen, Jing, and Zhu, Haining

Published

2014

2. ALS mutant SOD1 interacts with G3BP1 and affects stress granule dynamics.

Author

Gal, Jozsef, Kuang, Lisha, Barnett, Kelly, Zhu, Brian, Shissler, Susannah, Korotkov, Konstantin, Hayward, Lawrence, Kasarskis, Edward, and Zhu, Haining

Subjects

*GENETICS of amyotrophic lateral sclerosis, *GENETIC mutation, *STRESS granules, *CARRIER proteins, *MOTOR neurons, *RNA metabolism

Abstract

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease. Mutations in Cu/Zn superoxide dismutase (SOD1) are responsible for approximately 20 % of the familial ALS cases. ALS-causing SOD1 mutants display a gain-of-toxicity phenotype, but the nature of this toxicity is still not fully understood. The Ras GTPase-activating protein-binding protein G3BP1 plays a critical role in stress granule dynamics. Alterations in the dynamics of stress granules have been reported in several other forms of ALS unrelated to SOD1. To our surprise, the mutant G93A SOD1 transgenic mice exhibited pathological cytoplasmic inclusions that co-localized with G3BP1-positive granules in spinal cord motor neurons. The co-localization was also observed in fibroblast cells derived from familial ALS patient carrying SOD1 mutation L144F. Mutant SOD1, unlike wild-type SOD1, interacted with G3BP1 in an RNA-independent manner. Moreover, the interaction is specific for G3BP1 since mutant SOD1 showed little interaction with four other RNA-binding proteins implicated in ALS. The RNA-binding RRM domain of G3BP1 and two particular phenylalanine residues (F380 and F382) are critical for this interaction. Mutant SOD1 delayed the formation of G3BP1- and TIA1-positive stress granules in response to hyperosmolar shock and arsenite treatment in N2A cells. In summary, the aberrant mutant SOD1-G3BP1 interaction affects stress granule dynamics, suggesting a potential link between pathogenic SOD1 mutations and RNA metabolism alterations in ALS. [ABSTRACT FROM AUTHOR]

Published

2016

3. Self-assembled FUS binds active chromatin and regulates gene transcription.

Author

Liuqing Yang, Gal, Jozsef, Jing Chen, and Haining Zhu

Subjects

*AMYOTROPHIC lateral sclerosis, *NEURODEGENERATION, *DNA-binding proteins, *GENETIC mutation, *CYTOPLASM

Abstract

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease. Fused in sarcoma (FUS) is a DNA/RNA binding protein and mutations in FUS cause a subset of familial ALS. Most ALS mutations are clustered in the C-terminal nuclear localization sequence of FUS and consequently lead to the accumulation of protein inclusions in the cytoplasm. It remains debatable whether loss of FUS normal function in the nucleus or gain of toxic function in the cytoplasm plays a more critical role in the ALS etiology. Moreover, the physiological function of FUS in the nucleus remains to be fully understood. In this study, we found that a significant portion of nuclear FUS was bound to active chromatin and that the ALS mutations dramatically decreased FUS chromatin binding ability. Functionally, the chromatin binding is required for FUS transcription activation, but not for alternative splicing regulation. The N-terminal QGSY (glutamine-glycine-serine-tyrosine)-rich region (amino acids 1-164) mediates FUS self-assembly in the nucleus of mammalian cells and the self-assembly is essential for its chromatin binding and transcription activation. In addition, RNA binding is also required for FUS self-assembly and chromatin binding. Together, our results suggest a functional assembly of FUS in the nucleus under physiological conditions, which is different from the cytoplasmic inclusions. The ALS mutations can cause loss of function in the nucleus by disrupting this assembly and chromatin binding. [ABSTRACT FROM AUTHOR]

Published

2014

4. Mitochondrial dysfunction in amyotrophic lateral sclerosis

Author

Shi, Ping, Gal, Jozsef, Kwinter, David M., Liu, Xiaoyan, and Zhu, Haining

Subjects

*MITOCHONDRIAL pathology, *AMYOTROPHIC lateral sclerosis, *ETIOLOGY of diseases, *MOTOR neurons, *NEURODEGENERATION, *OXIDATIVE stress, *GENETIC mutation

Abstract

Abstract: The etiology of motor neuron degeneration in amyotrophic lateral sclerosis (ALS) remains to be better understood. Based on the studies from ALS patients and transgenic animal models, it is believed that ALS is likely to be a multifactorial and multisystem disease. Many mechanisms have been postulated to be involved in the pathology of ALS, such as oxidative stress, glutamate excitotoxicity, mitochondrial damage, defective axonal transport, glia cell pathology and aberrant RNA metabolism. Mitochondria, which play crucial roles in excitotoxicity, apoptosis and cell survival, have shown to be an early target in ALS pathogenesis and contribute to the disease progression. Morphological and functional defects in mitochondria were found in both human patients and ALS mice overexpressing mutant SOD1. Mutant SOD1 was found to be preferentially associated with mitochondria and subsequently impair mitochondrial function. Recent studies suggest that axonal transport of mitochondria along microtubules and mitochondrial dynamics may also be disrupted in ALS. These results also illustrate the critical importance of maintaining proper mitochondrial function in axons and neuromuscular junctions, supporting the emerging “dying-back” axonopathy model of ALS. In this review, we will discuss how mitochondrial dysfunction has been linked to the ALS variants of SOD1 and the mechanisms by which mitochondrial damage contributes to the disease etiology. [Copyright &y& Elsevier]

Published

2010

5. Nuclear localization sequence of FUS and induction of stress granules by ALS mutants

Author

Gal, Jozsef, Zhang, Jiayu, Kwinter, David M., Zhai, Jianjun, Jia, Hongge, Jia, Jianhang, and Zhu, Haining

Subjects

*AMYOTROPHIC lateral sclerosis, *AMINO acid sequence, *CYTOPLASMIC granules, *GENETIC mutation, *GENE expression, *CARRIER proteins, *RNA metabolism

Abstract

Abstract: Mutations in fused in sarcoma (FUS) have been reported to cause a subset of familial amyotrophic lateral sclerosis (ALS) cases. Wild-type FUS is mostly localized in the nuclei of neurons, but the ALS mutants are partly mislocalized in the cytoplasm and can form inclusions. We demonstrate that the C-terminal 32 amino acid residues of FUS constitute an effective nuclear localization sequence (NLS) as it targeted beta-galactosidase (LacZ, 116 kDa) to the nucleus. Deletion of or the ALS mutations within the NLS caused cytoplasmic mislocalization of FUS. Moreover, we identified the poly-A binding protein (PABP1), a stress granule marker, as an interacting partner of FUS. Large PABP1-positive cytoplasmic foci (i.e. stress granules) colocalized with the mutant FUS inclusions but were absent in wild-type FUS-expressing cells. Processing bodies, which are functionally related to stress granules, were adjacent to but not colocalized with the mutant FUS inclusions. Our results suggest that the ALS mutations in FUS NLS can impair FUS nuclear localization, induce cytoplasmic inclusions and stress granules, and potentially perturb RNA metabolism. [Copyright &y& Elsevier]

Published

2011

6. Effects of ALS-related SOD1 mutants on dynein- and KIF5-mediated retrograde and anterograde axonal transport

Author

Shi, Ping, Ström, Anna-Lena, Gal, Jozsef, and Zhu, Haining

Subjects

*AXONAL transport, *DYNEIN, *AMYOTROPHIC lateral sclerosis, *GENETIC mutation, *SUPEROXIDE dismutase, *MOTOR neurons, *KINESIN

Abstract

Abstract: Transport of material and signals between extensive neuronal processes and the cell body is essential to neuronal physiology and survival. Slowing of axonal transport has been shown to occur before the onset of symptoms in amyotrophic lateral sclerosis (ALS). We have previously shown that several familial ALS-linked copper–zinc superoxide dismutase (SOD1) mutants (A4V, G85R, and G93A) interacted and colocalized with the retrograde dynein–dynactin motor complex in cultured cells and affected tissues of ALS mice. We also found that the interaction between mutant SOD1 and the dynein motor played a critical role in the formation of large inclusions containing mutant SOD1. In this study, we showed that, in contrast to the dynein situation, mutant SOD1 did not interact with anterograde transport motors of the kinesin-1 family (KIF5A, B and C). Using dynein and kinesin accumulation at the sciatic nerve ligation sites as a surrogate measurement of axonal transport, we also showed that dynein mediated retrograde transport was slower in G93A than in WT mice at an early presymptomatic stage. While no decrease in KIF5A-mediated anterograde transport was detected, the slowing of anterograde transport of dynein heavy chain as a cargo was observed in the presymptomatic G93A mice. The results from this study along with other recently published work support that mutant SOD1 might only interact with and interfere with some kinesin members, which, in turn, could result in the impairment of a selective subset of cargos. Although it remains to be further investigated how mutant SOD1 affects different axonal transport motor proteins and various cargos, it is evident that mutant SOD1 can induce defects in axonal transport, which, subsequently, contribute to the propagation of toxic effects and ultimately motor neuron death in ALS. [Copyright &y& Elsevier]

Published

2010

7. Impaired activity and membrane association of most calpain-5 mutants causal for neovascular inflammatory vitreoretinopathy.

Author

Geddes, James W., Bondada, Vimala, Croall, Dorothy E., Rodgers, David W., and Gal, Jozsef

Subjects

*CALPAIN, *EYE diseases, *GENETIC mutation, *NONINVASIVE ventilation, *HEREDITY

Abstract

Neovascular inflammatory vitreoretinopathy (NIV) is a rare eye disease that ultimately leads to complete blindness and is caused by mutations in the gene encoding calpain-5 (CAPN5), with six pathogenic mutations identified. In transfected SH-SY5Y cells, five of the mutations resulted in decreased membrane association, diminished S-acylation, and reduced calcium-induced autoproteolysis of CAPN5. CAPN5 proteolysis of the autoimmune regulator AIRE was impacted by several NIV mutations. R243, L244, K250 and the adjacent V249 are on β-strands in the protease core 2 domain. Conformational changes induced by Ca2+binding result in these β-strands forming a β-sheet and a hydrophobic pocket which docks W286 side chain away from the catalytic cleft, enabling calpain activation based on comparison with the Ca2+-bound CAPN1 protease core. The pathologic variants R243L, L244P, K250N, and R289W are predicted to disrupt the β-strands, β-sheet, and hydrophobic pocket, impairing calpain activation. The mechanism by which these variants impair membrane association is unclear. G376S impacts a conserved residue in the CBSW domain and is predicted to disrupt a loop containing acidic residues which may contribute to membrane binding. G267S did not impair membrane association and resulted in a slight but significant increase in autoproteolytic and proteolytic activity. However, G267S is also identified in individuals without NIV. Combined with the autosomal dominant pattern of NIV inheritance and evidence that CAPN5 may dimerize, the results are consistent with a dominant negative mechanism for the five pathogenic variants which resulted in impaired CAPN5 activity and membrane association and a gain-of-function for the G267S variant. • The membrane association of most CAPN5 mutants linked to neovascular inflammatory vitreoretinopathy (NIV) is deficient. • The calcium induced autoproteolysis of most NIV-causing mutants of CAPN5 is impaired with the exception of G267S. • Several of the pathogenic mutations are in β-strands in the protease core 2 domain which are predicted to form a β-sheet and hydrophobic pocket during activation. • Co-immunoprecipitation studies suggest that CAPN5 self-associates into dimers or multimers. • The results and autosomal dominant pattern of inheritance suggest a dominant-negative mechanism for most pathogenic variants. [ABSTRACT FROM AUTHOR]

Published

2023