Molecular chaperones: toward new therapeutic tools.

Molecular chaperones (or heat shock proteins) are evolutionarily conserved and essential proteins that play a key role in cell survival through cytoprotective mechanisms. Despite their possible clinical applications, the understanding of these structures is still quite limited. The aim of the present study is to review the literature to understand the physiological importance, implication in various diseases (especially in cancer and neurodegenerative diseases), possible applicability, and future prospects of heat shock proteins. The cytoprotective mechanisms of molecular chaperones can be co-opted by oncogenic processes favoring tumor growth, invasion, evasion of apoptosis, and metastasis, thus making inhibitors to these molecules possible therapeutic options for cancer patients. However, there is also evidence showing that upregulation of heat shock proteins can have an antineoplastic effect through immunomodulatory activity. This is why chaperones have already been investigated for conventional chemotherapy under specific conditions, yielding interesting results. The induction of heat shock protein activity is also of potential benefit in many other diseases where structural and functional preservation of proteins may enhance cell survival, including neurodegeneration, trauma, stroke, and cardiovascular disease. In addition, the immune properties of chaperones can potentially be exploited for such diseases as diabetes, atherosclerosis, and other chronic inflammatory conditions. Thus, continuing efforts to clarify the role of chaperones may guide the development of new therapeutic modalities capable of minimizing the impact of diseases such as cancer, heart disease, and diabetes as well as obtaining better results in neurological conditions currently lacking alternative treatments.

Unexpected stress-reducing effect of PhaP, a poly(3-hydroxybutyrate) granule-associated protein, in Escherichia coli.

Phasins (PhaP) are proteins normally associated with granules of poly(3-hydroxybutyrate) (PHB), a biodegradable polymer accumulated by many bacteria as a reserve molecule. These proteins enhance growth and polymer production in natural and recombinant PHB producers. It has been shown that the production of PHB causes stress in recombinant Escherichia coli, revealed by an increase in the concentrations of several heat stress proteins. In this work, quantitative reverse transcription (qRT)-PCR analysis was used to study the effect of PHB accumulation, and that of PhaP from Azotobacter sp. strain FA8, on the expression of stress-related genes in PHB-producing E. coli. While PHB accumulation was found to increase the transcription of dnaK and ibpA, the expression of these genes and of groES, groEL, rpoH, dps, and yfiD was reduced, when PhaP was coexpressed, to levels even lower than those detected in the non-PHB-accumulating control. These results demonstrated the protective role of PhaP in PHB-synthesizing E. coli and linked the effects of the protein to the expression of stress-related genes, especially ibpA. The effect of PhaP was also analyzed in non-PHB-synthesizing strains, showing that expression of this heterologous protein has an unexpected protective effect in E. coli, under both normal and stress conditions, resulting in increased growth and higher resistance to both heat shock and superoxide stress by paraquat. In addition, PhaP expression was shown to reduce RpoH protein levels during heat shock, probably by reducing or titrating the levels of misfolded proteins.

Reduction of AHSP synthesis in hemin-induced K562 cells and EPO-induced CD34(+) cells leads to alpha-globin precipitation, impairment of normal hemoglobin production, and increased cell death.

OBJECTIVE: alpha-Hemoglobin stabilizing protein (AHSP) binds alpha-hemoglobin (Hb), avoiding its precipitation and its pro-oxidant activity. In the presence of betaHb, the alphaHb-AHSP complex is dismembered and betaHb displaces AHSP to generate the quaternary structure of Hb. The relationship between Hb formation and alterations in AHSP expression, which may affect human erythropoiesis, has not yet been described in human cells. Hence, in this study, we examined the effects of AHSP knockdown in hemin-induced K562 and erythropoietin-induced CD34(+) cells with particular reference to cellular aspects and gene expression. MATERIALS AND METHODS: Short-hairpin RNA expression vectors aimed at the AHSP mRNA target sequence were cloned and transfected into K562 and CD34(+) cells. K562 and CD34(+) cells were stimulated to erythroid differentiation. Cells were examined in terms of gene expression using quantitative real-time polymerase chain reaction; reactive oxygen species (ROS) production, apoptosis, and Hb production through flow cytometry assays; and immunofluorescence assays for globin chains. RESULTS: RNA interference-mediated knockdown of AHSP expression resulted in considerable alphaHb precipitation, as well as in a significant decrease in HbF formation. AHSP-knockdown cells demonstrated an increased ROS production and increased rate of apoptosis. CONCLUSION: These findings strengthen the hypothesis that AHSP stabilizes the alphaHb chain, avoiding its precipitation and its ability to generate ROS, which implicate in cell death. Moreover, data indicate that AHSP may be highly significant for human hemoglobin formation and suggest that AHSP is a key chaperone protein during human erythropoiesis.

Metallothionein is crucial for safe intracellular copper storage and cell survival at normal and supra-physiological exposure levels.

MTs (metallothioneins) increase the resistance of cells to exposure to high Cu (copper) levels. Characterization of the MT-Cu complex suggests that MT has an important role in the cellular storage and/or delivery of Cu ions to cuproenzymes. In this work we investigate how these properties contribute to Cu homoeostasis by evaluating the uptake, accumulation and efflux of Cu in wild-type and MT I/II null rat fibroblast cell lines. We also assessed changes in the expression of Cu metabolism-related genes in response to Cu exposure. At sub-physiological Cu levels (0.4 microM), the metal content was not dependent on MT; however, when extracellular Cu was increased to physiological levels (10 microM), MTs were required for the cell's ability to accumulate the metal. The subcellular localization of the accumulated metal in the cytoplasm was MT-dependent. Following supra-physiological Cu exposure (>50 microM), MT null cells had a decreased capacity for Cu storage and an elevated sensitivity to a minor increment in intracellular metal levels, suggesting that intracellular Cu toxicity is due not to the metal content but to the interactions of the metal with cellular components. Moreover, MT null cells failed to show increased levels of mRNAs encoding MT I, SOD1 (superoxide dismutase 1) and Ccs1 (Cu chaperone for SOD) in response to Cu exposure. These results support a role for MT in the storage of Cu in a safe compartment and in sequestering an intracellular excess of Cu in response to supra-physiological Cu exposure. Gene expression analysis suggests the necessity of having MT as part of the signalling pathway that induces gene expression in response to Cu.

[Genetic regulation of the heat-shock response in Escherichia coli]. / Regulación genética en la respuesta al estrés calórico en Escherichia coli.

Cells of almost any organism respond to a sudden up-shift of temperature and to several other stress conditions, by a transient increase in the cellular concentration of a set of proteins, the heat-shock proteins (HSPs). The main HSPs, chaperones and proteases, are constituents of the cellular machinery of protein folding, translocation, repair and degradation. The bacteria Escherichia coli has been a paradigm regarding heat shock gene expression in prokaryotes. In this bacterium, the expression of the HSPs is regulated at the transcriptional level. The approximately 40 genes that encode the HSPs define the heat-shock stimulon. Most of these genes, including the main chaperone and protease genes, are under the positive control of sigma32, encoded by rpoH, while approximately 10 genes, including rpoH and rpoE, are regulated by sigma(E) , encoded by rpoE. The cytoplasmic response to heat is regulated by sigma32, while that of the periplasm is regulated by sigma(E). The expression of both regulons is interconnected, since sigma(E) regulates the transcription of rpoH at high temperatures. The activity of these sigma factors, under non-stress and stress conditions, depends upon negative and positive regulatory mechanisms acting at different levels: transcription, translation, half-life and activity of the factors. Models for the regulation of the cytoplasmic and periplasmic response to heat in E. coli are presented.