A Novel Pulse-Chase SILAC Strategy Measures Changes in Protein Decay and Synthesis Rates Induced by Perturbation of Proteostasis with an Hsp90 Inhibitor

Fierro-Monti, Ivo; Racle, Julien; Hernandez, Céline; Waridel, Patrice; Hatzimanikatis, Vassily; Quadroni, Manfredo

doi:10.1371/journal.pone.0080423

Cited by 44 publications

(62 citation statements)

References 61 publications

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“…As an essential molecular chaperone that assures the correct folding and maturation of a number of cellular proteins, Hsp90 inhibition leads to a global repression of protein synthesis and an increase in the degradation of its client proteins. 58 This finding is consistent with our observation that KU-596 also decreased a subset of 25 ribosomal proteins only in diabetic Hsp70 KO sensory neurons. A recent proteomics study using human T cells revealed that Hsp90 inhibition resulted in the depletion of proteins involved in transcription and DNA damage response as well as a mild but general decrease of ribosomal proteins and other components of the protein synthesis machinery.…”

Section: Resultssupporting

confidence: 92%

Modulating Molecular Chaperones Improves Mitochondrial Bioenergetics and Decreases the Inflammatory Transcriptome in Diabetic Sensory Neurons

Pan

Anyika

et al. 2015

ACS Chem. Neurosci.

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We have previously demonstrated that modulating molecular chaperones with KU-32, a novobiocin derivative, ameliorates physiologic and bioenergetic deficits of diabetic peripheral neuropathy (DPN). Replacing the coumarin core of KU-32 with a meta-fluorinated biphenyl ring system created KU-596, a novobiocin analogue (novologue) that showed neuroprotective activity in a cell-based assay. The current study sought to determine whether KU-596 offers similar therapeutic potential for treating DPN. Administration of 2–20 mg/kg of KU-596 improved diabetes induced hypoalgesia and sensory neuron bioenergetic deficits in a dose-dependent manner. However, the drug could not improve these neuropathic deficits in diabetic heat shock protein 70 knockout (Hsp70 KO) mice. To gain further insight into the mechanisms by which KU-596 improved DPN, we performed transcriptomic analysis of sensory neuron RNA obtained from diabetic wild-type and Hsp70 KO mice using RNA sequencing. Bioinformatic analysis of the differentially expressed genes indicated that diabetes strongly increased inflammatory pathways and that KU-596 therapy effectively reversed these increases independent of Hsp70. In contrast, the effects of KU-596 on decreasing the expression of genes regulating the production of reactive oxygen species were more Hsp70-dependent. These data indicate that modulation of molecular chaperones by novologue therapy offers an effective approach toward correcting nerve dysfunction in DPN but that normalization of inflammatory pathways alone by novologue therapy seems to be insufficient to reverse sensory deficits associated with insensate DPN.

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Section: Resultssupporting

confidence: 92%

Modulating Molecular Chaperones Improves Mitochondrial Bioenergetics and Decreases the Inflammatory Transcriptome in Diabetic Sensory Neurons

Pan

Anyika

et al. 2015

ACS Chem. Neurosci.

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“…[74], in order to study how HSP90 inhibition with GA affects the proteome in T cells [75]. Seventeen percent of all proteins were impacted by GA, with upregulation of proteins involved in protein folding and stress response, including HSP90 and co-chaperones AHSA1, CDC37, STIP1, and FKBP4, but intriguingly not AARSD or FKBP5, suggesting that GA may remodel the HSP90 chaperone complexes.…”

Section: Global Impact Of Hsp90 Inhibition On the Proteomementioning

confidence: 99%

Proteomic interrogation of HSP90 and insights for medical research

Weidenauer

Wang

Joshi

et al. 2017

Expert Review of Proteomics

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Introduction Heat shock protein 90 (HSP90) regulates protein homeostasis in eukaryotes. As a ‘professional interactor’, HSP90 binds to and chaperones many proteins and has both housekeeping and disease-related functions but its regulation remains in part elusive. HSP90 complexes are a target for therapy, notably against cancer, and several inhibitors are currently in clinical trials. Proteomic studies have revealed the vast interaction network of HSP90 and, in doing so, the extent of cellular processes the chaperone takes part in, especially in yeast and human cells. Furthermore, small-molecule inhibitors were used to probe the global impact of its inhibition on the proteome. Areas covered We review here recent HSP90-related interactomics and total proteome studies and their relevance for research on cancer, neurodegenerative and pathogen diseases. Expert commentary Proteomics experiments are our best chance to identify the context-dependent global proteome of HSP90 and thus uncover and understand its disease-specific biology. However, understanding the complexity of HSP90 will require multiple complementary, quantitative approaches and novel bioinformatics to translate interactions into ordered functional networks and pathways. Developing therapies will necessitate more knowledge on HSP90 complexes and networks with disease relevance and on total proteome changes induced by their perturbation. Most work has been done in cancer, thus a lot remains to be done in the context of other diseases.

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“…Protein turnover is not only important to maintain protein concentrations in the cell, but also to allow for changes. Modulation of the proteome is necessary for most cellular responses, involving modifications in general or specific protein turnover (3,4). Neurons also have the ability to modulate and adjust their proteome in response to specific cues, for example, synaptic remodeling in response to patterns of action potentials in neurons.…”

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confidence: 99%

The Regulation of Synaptic Protein Turnover

Álvarez-Castelao

2015

Journal of Biological Chemistry

100

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Emerging evidence indicates that protein synthesis and degradation are necessary for the remodeling of synapses. These two processes govern cellular protein turnover, are tightly regulated, and are modulated by neuronal activity in time and space. The anisotropic anatomy of the neurons presents a challenge for the study of protein turnover, but the understanding of protein turnover in neurons and its modulation in response to activity can help us to unravel the fine-tuned changes that occur at synapses in response to activity. Here we review the key experimental evidence demonstrating the role of protein synthesis and degradation in synaptic plasticity, as well as the turnover rates of specific neuronal proteins.The human brain is composed of a trillion neurons with complex and intricate arbors, which are interconnected by synapses (1). Synapses are highly dynamic in number and shape as a consequence of the continuous remodeling of neural circuits. A change in synaptic transmission elicited by neural activity is collectively called "synaptic plasticity," and learning and memory rely, at least in part, on this process. Synapses are made up of proteins, including receptors for neurotransmitters, scaffolding molecules, and signaling molecules. All proteins have a finite lifetime: they are synthesized and degraded continuously to maintain cellular function and viability. This continuous process is called "protein turnover." However, why is protein turnover important for cells? Even when the cells are in a basal state, the protein pool is dynamic and the coordination between protein synthesis and degradation maintains a steady-state level of proteins that is constantly renewed (2). Protein turnover is not only important to maintain protein concentrations in the cell, but also to allow for changes. Modulation of the proteome is necessary for most cellular responses, involving modifications in general or specific protein turnover (3,4). Neurons also have the ability to modulate and adjust their proteome in response to specific cues, for example, synaptic remodeling in response to patterns of action potentials in neurons.One complication of protein turnover in neurons is that synapses can be located up to hundreds of microns from the cell body. Where are proteins synthesized and degraded? Are proteins transported over the long distance from the soma to dendrites or axons, and if so, how do they reach their specific location within the intricate axonal and dendritic arbors. In fact, to overcome these challenges, neurons have very effective transport mechanisms to deliver proteins to remote regions of axons or dendrites; this has been recently reviewed in Refs. 5 and 6. Moreover, some proteins, such as receptors or scaffolding proteins, are in continuous movement in and out of the synapse with rapid rates (reviewed in Refs. 7 and 8). In addition to protein movement, neurons use local translation and degradation in dendrites and axons, allowing for a fine-tuned local protein turnover. Here we present an overview focused on...

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A Novel Pulse-Chase SILAC Strategy Measures Changes in Protein Decay and Synthesis Rates Induced by Perturbation of Proteostasis with an Hsp90 Inhibitor

Cited by 44 publications

References 61 publications

Modulating Molecular Chaperones Improves Mitochondrial Bioenergetics and Decreases the Inflammatory Transcriptome in Diabetic Sensory Neurons

Modulating Molecular Chaperones Improves Mitochondrial Bioenergetics and Decreases the Inflammatory Transcriptome in Diabetic Sensory Neurons

Proteomic interrogation of HSP90 and insights for medical research

The Regulation of Synaptic Protein Turnover

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