25 research outputs found
The Identity of Proteins Associated with a Small Heat Shock Protein during Heat Stress \u3ci\u3ein Vivo\u3c/i\u3e Indicates That These Chaperones Protect a Wide Range of Cellular Functions
The small heat shock proteins (sHSPs) are a ubiquitous
class of ATP-independent chaperones believed to
prevent irreversible protein aggregation and to facilitate
subsequent protein renaturation in cooperation
with ATP-dependent chaperones. Although sHSP chaperone
activity has been studied extensively in vitro, understanding
the mechanism of sHSP function requires
identification of proteins that are sHSP substrates in
vivo. We have used both immunoprecipitation and affinity
chromatography to recover 42 proteins that specifically
interact with Synechocystis Hsp16.6 in vivo during
heat treatment. These proteins can all be released from
Hsp16.6 by the ATP-dependent activity of DnaK and cochaperones
and are heat-labile. Thirteen of the putative
substrate proteins were identified by mass spectrometry
and reveal the potential for sHSPs to protect cellular
functions as diverse as transcription, translation, cell
signaling, and secondary metabolism. One of the putative
substrates, serine esterase, was purified and tested
directly for interaction with purified Hsp16.6. Hsp16.6
effectively formed soluble complexes with serine esterase
in a heat-dependent fashion, thereby preventing formation
of insoluble serine esterase aggregates. These
data offer critical insights into the characteristics of
native sHSP substrates and extend and provide in vivo
support for the chaperone model of sHSP function
The Identity of Proteins Associated with a Small Heat Shock Protein during Heat Stress \u3ci\u3ein Vivo\u3c/i\u3e Indicates That These Chaperones Protect a Wide Range of Cellular Functions
The small heat shock proteins (sHSPs) are a ubiquitous
class of ATP-independent chaperones believed to
prevent irreversible protein aggregation and to facilitate
subsequent protein renaturation in cooperation
with ATP-dependent chaperones. Although sHSP chaperone
activity has been studied extensively in vitro, understanding
the mechanism of sHSP function requires
identification of proteins that are sHSP substrates in
vivo. We have used both immunoprecipitation and affinity
chromatography to recover 42 proteins that specifically
interact with Synechocystis Hsp16.6 in vivo during
heat treatment. These proteins can all be released from
Hsp16.6 by the ATP-dependent activity of DnaK and cochaperones
and are heat-labile. Thirteen of the putative
substrate proteins were identified by mass spectrometry
and reveal the potential for sHSPs to protect cellular
functions as diverse as transcription, translation, cell
signaling, and secondary metabolism. One of the putative
substrates, serine esterase, was purified and tested
directly for interaction with purified Hsp16.6. Hsp16.6
effectively formed soluble complexes with serine esterase
in a heat-dependent fashion, thereby preventing formation
of insoluble serine esterase aggregates. These
data offer critical insights into the characteristics of
native sHSP substrates and extend and provide in vivo
support for the chaperone model of sHSP function
Article Real-Time Monitoring of Protein Complexes Reveals their Quaternary Organization and Dynamics
SUMMARY The dynamics of protein complexes are crucial for their function yet are challenging to study. Here, we present a nanoelectrospray (nESI) mass spectrometry (MS) approach capable of simultaneously providing structural and dynamical information for protein complexes. We investigate the properties of two small heat shock proteins (sHSPs) and find that these proteins exist as dodecamers composed of dimeric building blocks. Moreover, we show that these proteins exchange dimers on the timescale of minutes, with the rate of exchange being strongly temperature dependent. Because these proteins are expressed in the same cellular compartment, we anticipate that this dynamical behavior is crucial to their function in vivo. Furthermore, we propose that the approach used here is applicable to a range of nonequilibrium systems and is capable of providing both structural and dynamical information necessary for functional genomics
Dietary intake and lifestyle practices of eastern mediterranean postpartum women before and during COVID-19 pandemic: An internet-based cross-sectional survey
Background: During the lockdown period, a substantial group of these women reported lifestyle changes.
Aim: The aim of the study is to characterize the dietary patterns, intake and the adherence to the United States Department of Agriculture (USDA) pregnancy guidelines before and during the COVID-19 pandemic in Eastern Mediterranean postartum women.
Methods: An internet-based cross-sectional survey was used to collect the data. The survey was carried out among 1,939 postpartum women from five countries from the Eastern Mediterranean region. Change in dietary intake from the five food groups and the adherence to USDA's daily recommendations were assessed.
Findings: There was a significant increase in the mean (SD) consumption of all the food groups, including bread, rice, and other cereals, fruits, vegetables, milk and milk products, white and red meat, and nuts during the pandemic. Around 84% of participants reported no/low adherence (0–2) to USDA guidelines, whereas only 15% reported moderate or high adherence (3–5) to the guidelines before the pandemic. However, there was an increase in the proportion of subjects reporting moderate/high adherence (22%) during the pandemic.
Discussion and conclusions: A substantial proportion of our study participants reported a lower dietary intake than the recommended amounts, and low adherence to the five food groups. Reasonable and applicable actions should be taken to protect postpartum women and their children from the effects of low dietary intake, particularly during pandemics and lockdowns. More researches are needed to identify the modifiable factors which could improve the nutritional status of the postpartum women during the pandemic
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Insights Into Small Heat Shock Protein and Substrate Structure During Chaperone Action Derived from Hydrogen/Deuterium Exchange and Mass Spectrometry.
Small heat shock proteins (sHSPs) and the related alpha-crystallins are ubiquitous chaperones linked to neurodegenerative diseases, myopathies, and cataract. To better define their mechanism of chaperone action, we used hydrogen/deuterium exchange and mass spectrometry (HXMS) to monitor conformational changes during complex formation between the structurally defined sHSPs, pea PsHsp18.1, and wheat TaHsp16.9, and the heat-denatured model substrates malate dehydrogenase (MDH) and firefly luciferase. Remarkably, we found that even when complexed with substrate, the highly dynamic local structure of the sHSPs, especially in the N-terminal arm (\u3e70% exchange in 5 s), remains unchanged. These results, coupled with sHSP-substrate complex stability, indicate that sHSPs do not adopt new secondary structure when binding substrate and suggest sHSPs are tethered to substrate at multiple sites that are locally dynamic, a feature that likely facilitates recognition and refolding of sHSP-bound substrate by the Hsp70/DnaK chaperone system. Both substrates were found to be stabilized in a partially unfolded state that is observed only in the presence of sHSP. Furthermore, peptide-level HXMS showed MDH was substantially protected in two core regions (residues 95-156 and 228-252), which overlap with the MDH structure protected in the GroEL-bound MDH refolding intermediate. Significantly, despite differences in the size and structure of TaHsp16.9-MDH and PsHsp18.1-MDH complexes, peptide-level HXMS patterns for MDH in both complexes are virtually identical, indicating that stabilized MDH thermal unfolding intermediates are not determined by the identity of the sHSP
Novel technique in detecting marginal adaptation of all ceramic restoration after cementation: case report
Abstract Background Accurate marginal adaptation of dental restorations guarantees their long-term success and longevity. Clinical evaluation of marginal adaptation is done using different techniques utilizing conventional tools such as mirrors and probes, which are subjective and non-standardized. Precise determination of restorations marginal gap intraorally, represents a challenge, especially when conducting clinical research testing newly introduced restoration designs or materials. Case presentation A 31-years-old female patient came to dental clinic seeking full coverage restoration for an endodontically treated upper left maxillary first premolar. After the patient received an all ceramic Bruxzir crown, the marginal adaptation and precise gap determination were evaluated intraorally utilizing digital microscope, aided with a novel custom-made microscope-holding device that facilitated standardization and handling. Conclusions The described method aided with the novel custom-made microscope holding device proved to be an easy, time saving and precise technique in evaluating the marginal gap directly inside patient’s mouth especially in clinical researches
The Identity of Proteins Associated with a Small Heat Shock Protein during Heat Stress in Vivo Indicates That These Chaperones Protect a Wide Range of Cellular Functions
The small heat shock proteins (sHSPs) are a ubiquitous class of ATP-independent chaperones believed to prevent irreversible protein aggregation and to facilitate subsequent protein renaturation in cooperation with ATP-dependent chaperones. Although sHSP chaperone activity has been studied extensively in vitro, understanding the mechanism of sHSP function requires identification of proteins that are sHSP substrates in vivo. We have used both immunoprecipitation and affinity chromatography to recover 42 proteins that specifically interact with Synechocystis Hsp16.6 in vivo during heat treatment. These proteins can all be released from Hsp16.6 by the ATP-dependent activity of DnaK and cochaperones and are heat-labile. Thirteen of the putative substrate proteins were identified by mass spectrometry and reveal the potential for sHSPs to protect cellular functions as diverse as transcription, translation, cell signaling, and secondary metabolism. One of the putative substrates, serine esterase, was purified and tested directly for interaction with purified Hsp16.6. Hsp16.6 effectively formed soluble complexes with serine esterase in a heat-dependent fashion, thereby preventing formation of insoluble serine esterase aggregates. These data offer critical insights into the characteristics of native sHSP substrates and extend and provide in vivo support for the chaperone model of sHSP function
Structural and functional aspects of the interaction partners of the small heat-shock protein in Synechocystis
The canonical function of small heat-shock proteins (sHSPs) is to interact with proteins destabilized under conditions of cellular stress. While the breadth of interactions made by many sHSPs is well-known, there is currently little knowledge about what structural features of the interactors form the basis for their recognition. Here, we have identified 83 in vivo interactors of the sole sHSP in the cyanobacterium Synechocystis sp. PCC 6803, HSP16.6, reflective of stable associations with soluble proteins made under heat-shock conditions. By performing bioinformatic analyses on these interactors, we identify primary and secondary structural elements that are enriched relative to expectations from the cyanobacterial genome. In addition, by examining the Synechocystis interactors and comparing them with those identified to bind sHSPs in other prokaryotes, we show that sHSPs associate with specific proteins and biological processes. Our data are therefore consistent with a picture of sHSPs being broadly specific molecular chaperones that act to protect multiple cellular pathways.Correction in: Cell Stress and Chaperones, 2018, vol. 23, issue 4, page 733DOI:Â 10.1007/s12192-018-0901-6</p
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Cdc48/VCP and Endocytosis Regulate TDP-43 and FUS Toxicity and Turnover
Amyotrophic lateral sclerosis (ALS) is a fatal motor neuron degenerative disease. TDP-43 (TAR DNA-binding protein 43) and FUS (fused in sarcoma) are aggregation-prone RNA-binding proteins that in ALS can mislocalize to the cytoplasm of affected motor neuron cells, often forming cytoplasmic aggregates in the process. Such mislocalization and aggregation are implicated in ALS pathology, though the mechanism(s) of TDP-43 and FUS cytoplasmic toxicity remains unclear. Recently, we determined that the endocytic function aids the turnover (i.e., protein degradation) of TDP-43 and reduces TDP-43 toxicity. Here, we identified that Cdc48 and Ubx3, a Cdc48 cofactor implicated in endocytic function, regulates the turnover and toxicity of TDP-43 and FUS expressed in Saccharomyces cerevisiae Cdc48 physically interacts and colocalizes with TDP-43, as does VCP, in ALS patient tissue. In yeast, FUS toxicity also depends strongly on endocytic function but not on autophagy under normal conditions. FUS expression also impairs endocytic function, as previously observed with TDP-43. Taken together, our data identify a role for Cdc48/VCP and endocytic function in regulating TDP-43 and FUS toxicity and turnover. Furthermore, endocytic dysfunction may be a common defect affecting the cytoplasmic clearance of ALS aggregation-prone proteins and may represent a novel therapeutic target of promise.6 month embargo; published online: 30 January 2020This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at [email protected]
The quaternary organization and dynamics of the molecular chaperone HSP26 are thermally regulated
The function of ScHSP26 is thermally controlled: the heat shock that causes the destabilization of target proteins leads to its activation as a molecular chaperone. We investigate the structural and dynamical properties of ScHSP26 oligomers through a combination of multiangle light scattering, fluorescence spectroscopy, NMR spectroscopy, and mass spectrometry. We show that ScHSP26 exists as a heterogeneous oligomeric ensemble at room temperature. At heat-shock temperatures, two shifts in equilibria are observed: toward dissociation and to larger oligomers. We examine the quaternary dynamics of these oligomers by investigating the rate of exchange of subunits between them and find that this not only increases with temperature but proceeds via two separate processes. This is consistent with a conformational change of the oligomers at elevated temperatures which regulates the disassembly rates of this thermally activated protein