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Parasitology,
2014]
Nematodes are amongst the most successful and abundant organisms on the planet with approximately 30 000 species described, although the actual number of species is estimated to be one million or more. Despite sharing a relatively simple and invariant body plan, there is considerable diversity within the phylum. Nematodes have evolved to colonize most ecological niches, and can be free-living or can parasitize plants or animals to the detriment of the host organism. In this review we consider the role of heat shock protein 90 (Hsp90) in the nematode life cycle. We describe studies on Hsp90 in the free-living nematode Caenorhabditis elegans and comparative work on the parasitic species Brugia pahangi, and consider whether a dependence upon Hsp90 can be exploited for the control of parasitic species.
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Front Neurosci,
2017]
The accumulation of misfolded proteins in the human brain is one of the critical features of many neurodegenerative diseases, including Alzheimer's disease (AD). Assembles of beta-amyloid (A) peptide-either soluble (oligomers) or insoluble (plaques) and of tau protein, which form neurofibrillary tangles, are the major hallmarks of AD. Chaperones and co-chaperones regulate protein folding and client maturation, but they also target misfolded or aggregated proteins for refolding or for degradation, mostly by the proteasome. They form an important line of defense against misfolded proteins and are part of the cellular quality control system. The heat shock protein (Hsp) family, particularly Hsp70 and Hsp90, plays a major part in this process and it is well-known to regulate protein misfolding in a variety of diseases, including tau levels and toxicity in AD. However, the role of Hsp90 in regulating protein misfolding is not yet fully understood. For example, knockdown of Hsp90 and its co-chaperones in a Caenorhabditis elegans model of A misfolding leads to increased toxicity. On the other hand, the use of Hsp90 inhibitors in AD mouse models reduces A toxicity, and normalizes synaptic function. Stress-inducible phosphoprotein 1 (STI1), an intracellular co-chaperone, mediates the transfer of clients from Hsp70 to Hsp90. Importantly, STI1 has been shown to regulate aggregation of amyloid-like proteins in yeast. In addition to its intracellular function, STI1 can be secreted by diverse cell types, including astrocytes and microglia and function as a neurotrophic ligand by triggering signaling via the cellular prion protein (PrP(C)). Extracellular STI1 can prevent A toxic signaling by (i) interfering with A binding to PrP(C) and (ii) triggering pro-survival signaling cascades. Interestingly, decreased levels of STI1 in C. elegans can also increase toxicity in an amyloid model. In this review, we will discuss the role of intracellular and extracellular STI1 and the Hsp70/Hsp90 chaperone network in mechanisms underlying protein misfolding in neurodegenerative diseases, with particular focus on AD.
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Subcell Biochem,
2015]
The UCS (UNC-45/CRO1/She4p) family of proteins has emerged as chaperones that are specific for the folding, assembly and function of myosin. These proteins participate in various important myosin-dependent cellular processes that include myofibril organization and muscle functions, cell differentiation, cardiac and skeletal muscle development, cytokinesis and endocytosis. Mutations in the genes that code for UCS proteins cause serious defects in these actomyosin-based processes. Homologs of UCS proteins can be broadly divided into (1) animal UCS proteins, generally known as UNC-45 proteins, which contain an N-terminal tetratricopeptide repeat (TPR) domain in addition to the canonical UCS domain, and (2) fungal UCS proteins, which lack the TPR domain. Structurally, except for TPR domain, both sub-classes of UCS proteins comprise of several irregular armadillo (ARM) repeats that are divided into two-domain architecture: a combined central-neck domain and a C-terminal UCS domain. Structural analyses suggest that UNC-45 proteins form elongated oligomers that serve as scaffolds to recruit Hsp90 and/or Hsp70 to form a multi-protein chaperoning complex that assists myosin heads to fold and simultaneously organize them into myofibrils. Similarly, fungal UCS proteins may dimerize to promote folding of non-muscle myosins as well as determine their step size along actin filaments. These findings confirm UCS proteins as a new class of myosin-specific chaperones and co-chaperones for Hsp90. This chapter reviews the implications of the outcome of studies on these proteins in cellular processes such as muscle formation, and disease states such as myopathies and cancer.
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Biochim Biophys Acta,
2012]
The molecular chaperone Hsp90 has been discovered in the heat-shock response of the fruit fly more than 30years ago. Today, it is becoming clear that Hsp90 is in the middle of a regulatory system, participating in the modulation of many essential client proteins and signaling pathways. Exerting these activities, Hsp90 works together with about a dozen of cochaperones. Due to their organismal simplicity and the possibility to influence their genetics on a large scale, many studies have addressed the function of Hsp90 in several multicellular model systems. Defined pathways involving Hsp90 client proteins have been identified in the metazoan model systems of Caenorhabditis elegans, Drosophila melanogaster and the zebrafish Danio rerio. Here, we summarize the functions of Hsp90 during muscle maintenance, development of phenotypic traits and the involvement of Hsp90 in stress responses, all of which were largely uncovered using the model organisms covered in this review. These findings highlight the many specific and general actions of the Hsp90 chaperone machinery. This article is part of a Special Issue entitled: Heat Shock Protein 90 (HSP90).
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Essays Biochem,
2016]
Quality control is an essential aspect of cellular function, with protein folding quality control being carried out by molecular chaperones, a diverse group of highly conserved proteins that specifically identify misfolded conformations. Molecular chaperones are thus required to support proteins affected by expressed polymorphisms, mutations, intrinsic errors in gene expression, chronic insult or the acute effects of the environment, all of which contribute to a flux of metastable proteins. In this article, we review the four main chaperone families in metazoans, namely Hsp60 (where Hsp is heat-shock protein), Hsp70, Hsp90 and sHsps (small heat-shock proteins), as well as their co-chaperones. Specifically, we consider the structural and functional characteristics of each family and discuss current models that attempt to explain how chaperones recognize and act together to protect or recover aberrant proteins.
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Int Rev Cell Mol Biol,
2014]
UNC-45 (uncoordinated mutant number 45) is a UCS (UNC-45, CRO1, She4p) domain protein that is critical for myosin stability and function. It likely aides in folding myosin during cellular differentiation and maintenance, and protects myosin from denaturation during stress. Invertebrates have a single
unc-45 gene that is expressed in both muscle and nonmuscle tissues. Vertebrates possess one gene expressed in striated muscle (
unc-45b) and another that is more generally expressed (
unc-45a). Structurally, UNC-45 is composed of a series of -helices connected by loops. It has an N-terminal tetratricopeptide repeat domain that binds to Hsp90 and a central domain composed of armadillo repeats. Its C-terminal UCS domain, which is also comprised of helical armadillo repeats, interacts with myosin. In this chapter, we present biochemical, structural, and genetic analyses of UNC-45 in Caenorhabditis elegans, Drosophila melanogaster, and various vertebrates. Further, we provide insights into UNC-45 functions, its potential mechanism of action, and its roles in human disease.
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Cell Cycle,
2006]
The relationship between fever and microbial infections has been known for a number of years, as well as several key mediators involved in its elicitation. However, the mechanisms by which fever confers protection to infected hosts are less clear. The nematode Caenorhabditis elegans, which has been extensively used in recent years to study microbial infections and innate immune responses, has recently been used to study the effect of increased temperature in immunity. Upon heat shock exposure, nematodes become more resistant to Pseudomonas aeruginosa and the enhanced resistance to the pathogen requires heat shock transcription factor 1 (HSF-1) and a system of small and 90 kDa heat shock proteins (HSPs). Experiments using additional Gram negative and Gram positive pathogens show that HSF-1 is part of a multipathogen defense pathway. In addition, C. elegans innate immunity can be activated enhancing HSF-1 activity by directly overexpressing HSF-1 or by overexpressing DAF-16, which is a forkhead transcription factor that acts upstream HSF-1 in aging and immunity. Blocking the inhibitory signal of the DAF-2 insulin like receptor, which acts upstream DAF-16, also results in an enhanced HSF-1 dependent immunity. In addition, mutations that affect DAF-21, C. elegans homologue of Hsp90 which forms an inhibitory complex with HSF-1, appear to boost immunity by activating the HSF-1 pathway. The role of the HSF-1 pathway in innate immunity and immunosenescence is discussed.
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J Cell Sci,
1997]
Heat shock proteins, first observed because they are preferentially synthesized by organisms exposed to heat or other physiological stress, are also synthesized constitutively. These proteins are divided into several families, namely, HSP100, 90, 70, 60 (chaperonin), and the small heat shock/alpha-crystallin proteins. They enjoy a wide phylogenetic distribution and are important because they function as molecular chaperones, able to mediate many cellular processes through an influence on higher order protein structure. For example, molecular chaperones assist in the transport of proteins into mitochondria and chloroplasts, as well as influencing clathrin lattice dynamics, viral replication and transcriptional activation. Under conditions of stress, some molecular chaperones prevent denaturation of proteins while others may dissociate protein aggregates, refolding monomers derived therefrom or directing their proteolytic destruction. We present in this review an analysis of the emerging literature on the relationship between molecular chaperones and the cytoskeleton, a collection of polymeric structures consisting of microtubules, microfilaments and intermediate filaments. A recent development in this field is identification of the TCP-1 complex as the eukaryotic cytoplasmic chaperonin which directs folding of cytoskeletal proteins such as alpha/beta/gamma-tubulin, actin and centractin. Moreover, the TCP-1 complex is a centrosomal component, apparently involved in the nucleation of microtubules. Other molecular chaperones recognize one or more cytoskeletal elements and in most cases they modulate the assembly of and/or provide protection for their constituent proteins. For example, HSP70 protects the centrosome and perhaps intermediate filaments during heat shock, and like HSP90, it binds to microtubules. Small heat shock proteins interact with microfilaments and intermediate filaments, affect their polymerization and guard them from heat shock by a phosphorylation-dependent mechanism. We conclude that molecular chaperones have different but cooperative roles in the formation and function of the eukaryotic cell cytoskeleton.
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Front Genet,
2018]
In the last decade, case studies in plants and animals provided increasing insight into the molecular mechanisms of developmental plasticity. When complemented with evolutionary and ecological analyses, these studies suggest that plasticity represents a mechanism facilitating adaptive change, increasing diversity and fostering the evolution of novelty. Here, we summarize genetic, molecular and evolutionary studies on developmental plasticity of feeding structures in nematodes, focusing on the model organism <i>Pristionchus pacificus</i> and its relatives. Like its famous cousin <i>Caenorhabditis elegans</i>, <i>P. pacificus</i> reproduces as a self-fertilizing hermaphrodite and can be cultured in the laboratory on <i>E. coli</i> indefinitely with a four-day generation time. However, in contrast to <i>C. elegans</i>, <i>Pristionchus</i> worms show more complex feeding structures in adaptation to their life history. <i>Pristionchus</i> nematodes live in the soil and are reliably found in association with scarab beetles, but only reproduce after the insects' death. Insect carcasses usually exist only for a short time period and their turnover is partially unpredictable. Strikingly, <i>Pristionchus</i> worms can have two alternative mouth-forms; animals are either stenostomatous (St) with a single tooth resulting in strict bacterial feeding, or alternatively, they are eurystomatous (Eu) with two teeth allowing facultative predation. Laboratory-based studies revealed a regulatory network that controls the irreversible decision of individual worms to adopt the St or Eu form. These studies revealed that a developmental switch controls the mouth-form decision, confirming long-standing theory about the role of switch genes in developmental plasticity. Here, we describe the current understanding of <i>P. pacificus</i> mouth-form regulation. In contrast to plasticity, robustness describes the property of organisms to produce unchanged phenotypes despite environmental perturbations. While largely opposite in principle, the relationship between developmental plasticity and robustness has only rarely been tested in particular study systems. Based on a study of the Hsp90 chaperones in nematodes, we suggest that robustness and plasticity are indeed complementary concepts. Genetic switch networks regulating plasticity require robustness to produce reproducible responses to the multitude of environmental inputs and the phenotypic output requires robustness because the range of possible phenotypic outcomes is constrained. Thus, plasticity and robustness are actually not mutually exclusive, but rather complementary concepts.