Adverse Effects of Fenofibrate in Mice Deficient in the Protein Quality Control Regulator, CHIP

Ravi, Saranya; Parry, Traci L.; Willis, Monte S.; Lockyer, Pamela; Patterson, Cam; Bain, James R.; Stevens, Robert; Newgard, Christopher B.; Schisler, Jonathan C.

doi:10.3390/jcdd5030043

Cited by 8 publications

(7 citation statements)

References 69 publications

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“…For example, mutant CHIP may be unable to either ubiquitinate chaperone-engaged proteins or promote the refolding of proteins that are usually degraded by the proteasome. Similarly, mutant CHIP may promote the activation of compensatory pathways involved in proteins degradation or clearing protein aggregates such as autophagy [ 29 , 49 ] that could sensitize the cells to additional proteotoxic stress. Moreover, the formation of soluble CHIP oligomers that alter the chaperone or co-chaperone functions of CHIP may also contribute to the pathophysiology.…”

Section: Discussionmentioning

confidence: 99%

Disrupted structure and aberrant function of CHIP mediates the loss of motor and cognitive function in preclinical models of SCAR16

et al. 2018

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CHIP (carboxyl terminus of heat shock 70-interacting protein) has long been recognized as an active member of the cellular protein quality control system given the ability of CHIP to function as both a co-chaperone and ubiquitin ligase. We discovered a genetic disease, now known as spinocerebellar autosomal recessive 16 (SCAR16), resulting from a coding mutation that caused a loss of CHIP ubiquitin ligase function. The initial mutation describing SCAR16 was a missense mutation in the ubiquitin ligase domain of CHIP (p.T246M). Using multiple biophysical and cellular approaches, we demonstrated that T246M mutation results in structural disorganization and misfolding of the CHIP U-box domain, promoting oligomerization, and increased proteasome-dependent turnover. CHIP-T246M has no ligase activity, but maintains interactions with chaperones and chaperone-related functions. To establish preclinical models of SCAR16, we engineered T246M at the endogenous locus in both mice and rats. Animals homozygous for T246M had both cognitive and motor cerebellar dysfunction distinct from those observed in the CHIP null animal model, as well as deficits in learning and memory, reflective of the cognitive deficits reported in SCAR16 patients. We conclude that the T246M mutation is not equivalent to the total loss of CHIP, supporting the concept that disease-causing CHIP mutations have different biophysical and functional repercussions on CHIP function that may directly correlate to the spectrum of clinical phenotypes observed in SCAR16 patients. Our findings both further expand our basic understanding of CHIP biology and provide meaningful mechanistic insight underlying the molecular drivers of SCAR16 disease pathology, which may be used to inform the development of novel therapeutics for this devastating disease.

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Section: Discussionmentioning

confidence: 99%

Disrupted structure and aberrant function of CHIP mediates the loss of motor and cognitive function in preclinical models of SCAR16

et al. 2018

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“…More recently, CHIP was identified as a regulator of many other processes, such as TFEB activity and thereby macroautophagy regulation ( Guo et al, 2015 ; Sha et al, 2017 ), necroptosis ( Seo et al, 2016 ; Tang et al, 2018 ), cAMP and AMPK signaling ( Schisler et al, 2013 ; Rinaldi et al, 2019 ), oxidative metabolism ( Ravi et al, 2018 ), chaperone-mediated autophagy ( Ferreira et al, 2015 ) and neuronal preconditioning ( Lizama et al, 2018 ). In addition to this, CHIP was shown to be cytoprotective in many forms of neurodegeneration by degrading inter alia α-synuclein ( Shin et al, 2005 ; Tetzlaff et al, 2008 ), LRRK2 ( Ding and Goldberg, 2009 ), APP and BACE1 ( Kumar et al, 2007 ; Singh and Pati, 2015 ), as well as huntingtin ( Jana et al, 2005 ; Miller et al, 2005 ).…”

Section: Introductionmentioning

confidence: 99%

CHIP mutations affect the heat shock response differently in human fibroblasts and iPSC-derived neurons

Schuster

Heuten

Velić

et al. 2020

Disease Models &Amp; Mechanisms

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C-terminus of HSC70-interacting protein (CHIP) encoded by the gene STUB1 is a co-chaperone and E3 ligase that acts as a key regulator of cellular protein homeostasis. Mutations in STUB1 cause autosomal recessive spinocerebellar ataxia type 16 (SCAR16) with widespread neurodegeneration manifesting as spastic-ataxic gait disorder, dementia and epilepsy. CHIP−/− mice display severe cerebellar atrophy, show high perinatal lethality and impaired heat stress tolerance. To decipher the pathomechanism underlying SCAR16, we investigated the heat shock response (HSR) in primary fibroblasts of three SCAR16 patients. We found impaired HSR induction and recovery compared to healthy controls. HSPA1A/B transcript levels (coding for HSP70) were reduced upon heat shock but HSP70 remained higher upon recovery in patient- compared to control-fibroblasts. As SCAR16 primarily affects the central nervous system we next investigated the HSR in cortical neurons (CNs) derived from induced pluripotent stem cells of SCAR16 patients. We found CNs of patients and controls to be surprisingly resistant to heat stress with high basal levels of HSP70 compared to fibroblasts. Although heat stress resulted in strong transcript level increases of many HSPs, this did not translate into higher HSP70 protein levels upon heat shock, independent of STUB1 mutations. Furthermore, STUB1(−/−) neurons generated by CRISPR/Cas9-mediated genome editing from an isogenic healthy control line showed a similar HSR to patients. Proteomic analysis of CNs showed dysfunctional protein (re)folding and higher basal oxidative stress levels in patients. Our results question the role of impaired HSR in SCAR16 neuropathology and highlight the need for careful selection of proper cell types for modeling human diseases.

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“…In contrast, SCAR16 patients with cognitive dysfunction and Ubox mutations may benefit from the use of molecular chaperones to prevent the oligomerization of these mutant CHIP proteins. CHIP impacts several cellular pathways, and identifying the CHIP-dependent pathways that may contribute to the specific pathologies in SCAR16, such as necroptosis (23), IGF1 (24), mitophagy (25), autophagy (26, 27), or water balance (28), may also uncover therapeutically relevant targets. Additionally, gene therapy approaches might be applicable to SCAR16.…”

Section: Discussionmentioning

confidence: 99%

Changes in protein function underlie the disease spectrum in patients with CHIP mutations

Madrigal

McNeil

Sanchez‐Hodge

et al. 2019

Journal of Biological Chemistry

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Monogenetic disorders that cause cerebellar ataxia are characterized by defects in gait and atrophy of the cerebellum; however, patients often suffer from a spectrum of disease, complicating treatment options. Spinocerebellar ataxia autosomal recessive 16 (SCAR16) is caused by coding mutations in STUB1, a gene that encodes the multifunctional enzyme CHIP (C terminus of HSC70-interacting protein). The disease spectrum of SCAR16 includes a varying age of disease onset, cognitive dysfunction, increased tendon reflex, and hypogonadism. Although SCAR16 mutations span the multiple functional domains of CHIP, it is unclear whether the location of the mutation and the change in the biochemical properties of CHIP contributes to the clinical spectrum of SCAR16. In this study, we examined relationships between the clinical phenotypes of SCAR16 patients and the changes in biophysical, biochemical, and functional properties of the corresponding mutated protein. We found that the severity of ataxia did not correlate with age of onset; however, cognitive dysfunction, increased tendon reflex, and ancestry were able to predict 54% of the variation in ataxia severity. We further identified domain-specific relationships between biochemical changes in CHIP and clinical phenotypes and specific biochemical activities that associate selectively with either increased tendon reflex or cognitive dysfunction, suggesting that specific changes to CHIP–HSC70 dynamics contribute to the clinical spectrum of SCAR16. Finally, linear models of SCAR16 as a function of the biochemical properties of CHIP support the concept that further inhibiting mutant CHIP activity lessens disease severity and may be useful in the design of patient-specific targeted approaches to treat SCAR16.

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Adverse Effects of Fenofibrate in Mice Deficient in the Protein Quality Control Regulator, CHIP

Cited by 8 publications

References 69 publications

Disrupted structure and aberrant function of CHIP mediates the loss of motor and cognitive function in preclinical models of SCAR16

Disrupted structure and aberrant function of CHIP mediates the loss of motor and cognitive function in preclinical models of SCAR16

CHIP mutations affect the heat shock response differently in human fibroblasts and iPSC-derived neurons

Changes in protein function underlie the disease spectrum in patients with CHIP mutations

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