Sumoylation in Lens Differentiation and Pathogenesis.

Sumoylation, a post-translational modification discovered over a decade ago, turns out to be a very important regulatory mechanism mediating multiple cellular processes. Recent studies from our laboratory and others also revealed that it plays a crucial role in regulating both differentiation and pathogenesis of the ocular lens. This review will summarize these progresses.

HspB1 dynamic phospho-oligomeric structure dependent interactome as cancer therapeutic target.

Human HspB1 (Hsp27), a molecular chaperone bearing tumorigenic and metastatic roles, is characterized by its dynamic phosphorylation and heterogenous oligomerization in response to changes in cell physiology. The phenomenon is particularly intense and specific when cells are exposed to different death inducers. This favors the hypothesis that the structural organization of HspB1 acts as a sensor which, through reversible modifications, allows cells to adapt and/or mount a protective response. A large number of HspB1 interacting partners have already been described in the literature. Specific changes in oligomerphosphorylation organization may therefore allow HspB1 to interact with the more appropriate polypeptides and to subsequently modulate their folding/activity and/or half-life. This could indirectly link HspB1 to multiple cellular functions and could explain the apparently unrelated effects associated to its over- or underexpression. In cancer, HspB1 is tumorigenic, stimulates metastasis and provide cancer cells with resistance to many anti-cancer drugs, so compounds aimed at disrupting HspB1 deleterious pro-cancer activity are actively looked for. One example, is brivudine that impairs HspB1 ability to recognize pathological protein substrates and appears as a promising anti-cancer drug. Similarly, we have observed that peptide aptamers that specifically interfere with HspB1 structural organization reduced its anti-apoptotic and tumorigenic activities. We propose that, in addition to RNA interference approaches, the tumorigenic activity of HspB1 could be inhibited by altering HspB1 structural organization and consequently its interaction with inappropriate procancerous polypeptide partners. Hence, developping HspB1 structure-based interfering strategies could lead to new anti-cancer drugs discovery.

Targeting heat shock protein 27 (HspB1) interferes with bone metastasis and tumour formation in vivo.

BACKGROUND: The small stress heat shock protein 27 (Hsp27) has recently turned as a promising target for cancer treatment. Hsp27 upregulation is associated with tumour growth and resistance to chemo- and radio-therapeutic treatments, and several ongoing drugs inhibiting Hsp27 expression are under clinical trial. Hsp27 is now well described to counteract apoptosis and its elevated expression is associated with increased aggressiveness of several primary tumours. However, its role in the later stage of tumour progression and, more specifically, in the later and most deadly stage of tumour metastasis is still unclear. METHODS/RESULTS: In the present study, we showed by qRT-PCR that Hsp27 gene is overexpressed in a large fraction of the metastatic breast cancer area in 53 patients. We further analysed the role of this protein in mice during bone metastasis invasion and establishment by using Hsp27 genetically depleted MDA-MB231/B02 human breast cancer cell line as a model. We demonstrate that Hsp27 silencing led to reduced cell migration and invasion in vitro and that in vivo it correlated with a decreased ability of breast cancer cells to metastasise and grow in the skeleton. CONCLUSION: Altogether, these data characterised Hsp27 as a potent therapeutic target in breast cancer bone metastasis and skeletal tumour growth.

Pathology-dependent effects linked to small heat shock proteins expression: an update.

Small heat shock proteins (small Hsps) are stress-induced molecular chaperones that act as holdases towards polypeptides that have lost their folding in stress conditions or consequently of mutations in their coding sequence. A cellular protection against the deleterious effects mediated by damaged proteins is thus provided to cells. These chaperones are also highly expressed in response to protein conformational and inflammatory diseases and cancer pathologies. Through specific and reversible modifications in their phospho-oligomeric organization, small Hsps can chaperone appropriate client proteins in order to provide cells with resistance to different types of injuries or pathological conditions. By helping cells to better cope with their pathological status, their expression can be either beneficial, such as in diseases characterized by pathological cell degeneration, or deleterious when they are required for tumor cell survival. Moreover, small Hsps are actively released by cells and can act as immunogenic molecules that have dual effects depending on the pathology. The cellular consequences linked to their expression levels and relationships with other Hsps as well as therapeutic strategies are discussed in view of their dynamic structural organization required to interact with specific client polypeptides.

Inhibition of heat shock protein 27 (HspB1) tumorigenic functions by peptide aptamers.

Human heat shock protein 27 (Hsp27, HspB1) is an anti-apoptotic protein characterized for its tumorigenic and metastatic properties, and now referenced as a major therapeutic target in many types of cancer. Hsp27 biochemical properties rely on a structural oligomeric and dynamic organization. Downregulation by small interfering RNA or inhibition with dominant-negative mutant have proven their efficiency to counteract the anti-apoptotic and protective properties of Hsp27. In this study, we report the isolation and characterization of Hsp27-targeted molecules interfering with its structural organization. Using the peptide aptamer (PA) strategy, we isolated PAs that specifically interact with Hsp27 and not with the other members of the small heat shock protein family. In mammalian cell cultures, PAs expression perturbed the dimerization and oligomerization of Hsp27, and acted as negative regulators of the anti-apoptotic and cytoprotective activities of this protein. Further studies analyzing SQ20B cell xenografts in immunocompromised mice showed that PAs strongly reduced tumor development through cell cycle arrest. Our data suggest that PAs could provide a potential tool to develop strategies for the discovery of Hsp27 chemical inhibitors.

Expression and functions of heat shock proteins in the normal and pathological mammalian eye.

Heat shock proteins (Hsps) are expressed in mammalian embryonic, adult and aging lens, cornea and retina. These proteins, particularly those belonging to the family of small Hsps, such as αA-crystallin (HspB4) and αB-crystallin (HspB5), play important roles in the differentiation of lens cells and are essential for the maintenance and protection of the supraorganization of proteins in differentiated corneal and lens fiber cells. Hsps are molecular chaperones characterized by their protective activity against different types of stress. They also have anti-apoptotic and anti-oxidant functions that help lens and corneal cells to better cope with the oxidative conditions that result from light induced injuries. They are also effective to protect the retina against the high rate of oxidative metabolism observed in this tissue. The goal of this review is to highlight recent works describing the expression and function(s) of the different Hsps as an attempt to better understand their roles in the normal and pathological eye. Particular emphasis is given to the α-crystallin polypeptides which, in addition to their protective functions, are key structural polypeptides that are essential for the refractive and light focusing properties of the lens, a property demonstrated by the caractogenic potential of their mutation.

Protection against heat and staurosporine mediated apoptosis by the HSV-1 US11 protein.

US11 protein, one of herpes simplex virus type 1 (HSV-1) true late gene products, plays a role in the virally induced post-transcriptional control of gene expression. In addition, US11 expression also interferes with the cellular response to HSV-1 infection that can lead to apoptosis. We have previously shown that US11 expression enhanced the recovery of cellular protein synthesis and increased cell survival in response to thermal stress. Since heat shock can activate apoptosis, we tested for a possible anti-apoptotic behavior of US11. Here, we show that, in HeLa cells, US11 expression strongly reduced heat induced apoptosis, a phenomenon independent of Hsp expression and characterized by a delayed cytochrome c efflux from mitochondria and reduced caspase 3 activation. Moreover, US11 expression also protected against staurosporine induced apoptosis. Hence, our results favor an anti-apoptotic activity of US11 polypeptide that appears to be located at the level of mitochondria or upstream signaling pathways.

Dithiocarbamate fungicide thiram detection: comparison of bioluminescent and fluorescent whole-cell bioassays based on hsp22 stress promoter induction.

Detection of toxic substances interfering with endocrine system is one of the major preoccupations of the European community. A whole-cell bioassay for pollution detection based on stress induction has been designed. Well characterized toxicants, cadmium chloride and thiram (a dithiocarbamate fungicide), were used to optimize the detection conditions such as time-course conditions, cell line and reporter gene to be used. HeLa cells containing the firefly luciferase (luc) reporter gene under the control of the Drosophila melanogaster hsp22 promoter were compared to liver cells (HepG2) containing the same stress gene promoter fused either to the luc or the EGFP (Enhanced-Green Fluorescent Protein) gene. The sensitivity of the obtained bioassay was found to be enhanced by the concomitant use of liver cells and EGFP reporter gene. The detection limits of the toxicants were then lowered from 1 to 0.1 microM and from 1 to 0.01 microM for CdCl(2) and thiram, respectively.

Chemical stress sensitive luminescent human cells: molecular biology approach using inducible Drosophila melanogaster hsp22 promoter.

A whole-cell bioassay has been developed for the total toxicity testing of liquid samples. The method is based on the induction of the bioluminescent activity of genetically manipulated mammalian cells. For that purpose, transfection was used to introduce, in HeLa cells, a DNA sensing element that responds to chemical stress agents (heavy metals, genotoxic agents, and endocrine-disrupting chemicals). Such element was designed to direct the expression of a reporting gene (firefly luciferase) through the activation of Drosophila melanogaster hsp22 promoter. A molecular approach was conducted to optimize hsp22 promoter element in order to decrease the background expression level of the reporting gene and to increase the sensitivity of the bioassay for testing endocrine disruptors. As a result, in the presence of 20-100 microM cadmium chloride, a 6-fold increase in luciferase expression was obtained using a specially designed truncated hsp22 promoter construction. The following chemicals known to be found in the polluted samples were tested: CdCl2, Cd(NO3)2, NaAsO2, alachlore, fentine acetate, thiram, and maneb. The stressing effect of each of them was sensitively detected by the present bioassay in the 0.05-50 microM concentration range.

The role of heat shock proteins Hsp70 and Hsp27 in cellular protection of the central nervous system.

Heat shock proteins (Hsps) are highly conserved and under physiological conditions act as molecular chaperones and/or have anti-apoptotic activities. Expression in the brain of two heat shock proteins, the70 kDa Hsp (Hsp70) and the 27 kDa Hsp (Hsp27), is notable because both proteins are highly inducible in glial cells and neurons following a wide range of noxious stimuli including ischemia, epileptic seizure and hyperthermia. In the central nervous system, constitutive expression of Hsp27 is limited to many (but not all) sensory and motor neurons of the brain stem and spinal cord, while there is little or no constitutive expression of Hsp70. However, inducible expression of both Hsp70 and Hsp27 is present in many areas of the brain and retina and is associated with cellular resistance to a variety of insults. The potential for manipulating the expression levels of Hsps for therapeutic advantage in neurodegenerative diseases such as Alzheimer's disease, stroke and glaucoma will be explored.

Proliferation and activation of bronchial epithelial cells in corticosteroid-dependent asthma.

BACKGROUND: Structural and functional characteristics of bronchial epithelial cells in corticosteroid-dependent asthma are unknown. OBJECTIVE: In bronchial biopsy specimens from 16 control, 9 untreated asthmatic, 9 inhaled corticosteroid-treated asthmatic, and 19 corticosteroid-dependent asthmatic subjects, we evaluated epithelium morphology and patterns of cell apoptosis, proliferation, and activation. METHODS: We used the terminal deoxynucleotidyl-mediated dUTP nick end labeling (TUNEL) technique to study apoptosis. Immunohistochemistry was used to evaluate the expression of molecules related to apoptosis (such as Bcl-2 and P53), cell proliferation (PCNA), and cell activation (NFkappaB and CD40/CD40-L). RESULTS: Epithelium thickness was higher in corticosteroid-dependent asthmatic and control subjects than in inhaled corticosteroid-treated and untreated asthmatic subjects (P < .0001 and P <.0003). Very few TUNEL-positive epithelial cells were found in the 4 groups. Bcl-2 expression was higher in all groups of asthmatic subjects than in controls (P < .001). In corticosteroid-dependent asthmatic subjects, PCNA, NFkappaB, and CD40-L expression was higher than in inhaled corticosteroid-treated asthmatic (P < .001), untreated asthmatic (P <.001 and P < .04), and control (P < .01) subjects. CD40 expression was greater in corticosteroid-dependent asthmatic and untreated asthmatic subjects than in inhaled corticosteroid-treated asthmatic subjects (P < .0001 and P < .0006) and controls (P < .02 and P < .03). In corticosteroid-dependent asthma, PCNA expression was correlated with the epithelium thickness (P < .007). CONCLUSION: This study shows that in bronchial epithelial cells of corticosteroid-dependent asthma, markers of cell survival and proliferation are coexpressed with markers of cell activation, suggesting that in this disease epithelium repair is associated with a persistent activation state of epithelial cells.

Selenium: a key element that controls NF-kappa B activation and I kappa B alpha half life.

Treatment of mammalian cells with hydrogen peroxide induces the nuclear translocation of the transcription factor NF-kappa B and its binding to kappa B DNA sequences present in the promoter region of numerous genes. The role of selenium in NF-kappa B activation was analyzed in human T47D cells overexpressing the seleno-dependent detoxifiant enzyme glutathione peroxidase. Following exposure to H(2)O(2), these cells showed a seleno-dependent decreased accumulation of intracellular ROS and NF-kappa B activation. This phenomenon was correlated with an inhibition of the nuclear translocation of NF-kappa B (p50 subunit) and with an absence of I kappa B alpha degradation. We also report that the half-life of I kappa B alpha in untreated cells was increased two-fold by the overexpression of active glutathione peroxidase. These results suggest that selenium is a key element that through its modulation of glutathione peroxidase activity can inhibit NF-kappa B activation and can up-regulate I kappa B alpha normal half life.

NFkappa B-dependent transcriptional activation during heat shock recovery. Thermolability of the NF-kappaB.Ikappa B complex.

Heat shock induces the accumulation of misfolded proteins and results in the preferential expression of heat shock proteins, which help the cell to recover from thermal damage. Heat shock is a well known transcriptional activator of the human immunodeficiency virus type 1 long terminal repeat (LTR). We report here that mutations or deletions of the LTR kappaB sites impaired the LTR transcriptional activation by heat shock. Further analysis revealed that, during heat shock recovery, the NF-kappaB p65 and p50 subunits migrated into the nucleus of HeLa cells, bound to DNA, and induced kappaB-dependent reporter gene expression. This NF-kappaB activation did not depend on new transcriptional and/or translational events and on the pro-oxidant state generated by heat shock. It was not concomitant with IkappaBalpha phosphorylation and was not abolished by the expression of IkappaB kinase or IkappaBalpha dominant-negative mutants. Moreover, NF-kappaB activation and migration into the nucleus were not concomitant with IkappaBalpha/beta or p105 degradation. However, during heat shock recovery, NF-kappaB was dissociated from its complexing partners, allowing its migration into the nucleus. Hence, we describe here a novel mechanism for activation of NF-kappaB based on the thermolability of the NF-kappaB.IkappaB complex.

Modulation of HSP25 expression during anterior horn motor neuron degeneration in the paralysé mouse mutant.

The paralysé spontaneous mutation in mice involves degeneration and death of anterior horn motor neurons. Mutant mice are not viable past postnatal day 16. At present, the mechanisms involved in motor neuron death are unknown. Here, we investigate the expression of the small heat shock protein Hsp25, in the spinal cord of paralysé at two different stages during postnatal development, i.e., day 11 and day 14. Western blot analysis reveals that the level of Hsp25 was strikingly different in paralysé as compared to control littermates. Hsp25 expression level in paralysé at day 11 was much lower than in control mice. At day 14, an opposite pattern was observed. Such pattern seems to be restricted to spinal cord, since level of Hsp25 in other tissues (lung, brain, liver, and heart) was quite similar. Immunofluorescence examination of the lumbar spinal cord sections reveals that in control mice, Hsp25 was expressed at high level in motor neurons located in the ventral horn at both day 11 and day 14. By contrast, in paralysé mice, Hsp25 staining within the motor neurons was barely detectable except as a spot in the nucleolus (day 11). At the end stage of the disease (day 14), not only was Hsp25 staining even less intense in motor neurons, but also a strong Hsp25 staining was observed in reactive astrocytes within the gray matter. Taken together, these data suggest that Hsp25 expression is differently modulated in neuronal and glial cells during neurodegenerative processes leading to motor neuron death.

Hsp27 protects mitochondria of thermotolerant cells against apoptotic stimuli.

Enhanced cell survival and resistance to apoptosis during thermotolerance correlates with an increased expression of heat shock proteins (Hsps). Here we present additional evidence in support of the hypothesis that the induction of Hsp27 and Hsp72 during acquired thermotolerance in Jurkat T-lymphocytes prevents apoptosis. In thermotolerant cells, Hsp27 was shown to associate with the mitochondrial fraction, and inhibition of Hsp27 induction during thermotolerance in cells transfected with hsp27 antisense potentiated mitochondrial cytochrome c release after exposure to various apoptotic stimuli, despite the presence of elevated levels of Hsp72. Caspase activation and apoptosis were inhibited under these conditions. In vitro studies revealed that recombinant Hsp72 more efficiently blocked cytochrome c-mediated caspase activation than did recombinant Hsp27. A model is presented for the inhibition of apoptosis during thermotolerance in which Hsp27 preferentially blocks mitochondrial cytochrome c release, whereas Hsp72 interferes with apoptosomal caspase activation.

Hsp27: novel regulator of intracellular redox state.

Small stress proteins are molecular chaperones that modulate the ability of cells to respond to several types of injuries. In this regard, a protection generated by the expression of mammalian small stress proteins against the cell death induced by oxidative stress has been described. This review summarizes the current knowledge of the protective mechanism generated by the expression of the major mammalian small stress protein Hsp27 in cells exposed to oxidative stress. A possible role of this chaperone protein in the presentation of oxidized proteins to the proteasome degradation machinery is proposed.

Comparison of the protective activities generated by two survival proteins: Bcl-2 and Hsp27 in L929 murine fibroblasts exposed to menadione or staurosporine.

Hsp27 and Bcl-2 are survival proteins that protect against cell death. We have compared the specific protective activity (protection per number of molecules expressed) mediated by these proteins when they are expressed in L929 murine fibroblasts. We found that Hsp27 and Bcl-2 efficiently delayed the cytotoxicity generated by menadione. Both proteins interfered with the mitochondria membrane potential collapse, the reactive oxygen species (ROS) burst and the decrease in glutathione level induced by this oxidant. In untreated cells, both proteins decreased the ROS levels and raised the glutathione cellular content. Taking their levels of expression into account, we concluded that Bcl-2 was much more active than Hsp27 for counteracting the above-mentioned menadione effects, and for modulating the ROS and glutathione levels in untreated cells. Both Hsp27 and Bcl-2 also conferred cellular resistance to staurosporine, a kinase inhibitor that induces apoptosis without generating an oxidative stress. In this case, Bcl-2 was again much more active than Hsp27. Fractionation studies indicated that, in L929 cells, Hsp27 is essentially present in the cytosol while Bcl-2 is membrane and mitochondria-associated. Hence, despite some similar cellular effects resulting from their expression, Bcl2 and Hsp27 polypeptides protect against oxidative stress and apoptosis with different efficiencies and by using different mechanisms.

Differential regulation of HSP27 oligomerization in tumor cells grown in vitro and in vivo.

HSP27 form oligomeric structures up to 800 Kda. In cultured cells, the equilibrium between small and large oligomers shifted towards smaller oligomers when phosphorylated on serine residues. To further explore HSP27 structural organization and its repercussion in HSP27 antiapoptotic and tumorigenic properties, we transfected colon cancer REG cells with wild type HSP27 and two mutants in which the phosphorylatable serine residues have been replaced by alanine (to mimic the non phosphorylated protein) or aspartate (to mimic the phosphorylated protein). In growing cells, wild type and alanine mutant formed small and large oligomers and demonstrated antiapoptotic activity while aspartate mutant only formed small multimers and had no antiapoptotic activity. In a cell-free system, only large oligomeric structures interfered with cytochrome c-induced caspase activation, thereby inhibiting apoptosis. The inability of the aspartate mutant to form large oligomers and to protect tumor cells from apoptosis was overcome by growing the cells in vivo, either in syngeneic animals or nude mice. These observations were reproduced by culturing the cells at confluence in vitro. In conclusion (1) large oligomers are the structural organization of HSP27 required for its antiapoptotic activity and (2) cell-cell contacts induce the formation of large oligomers, whatever the status of phosphorylatable serines, thereby increasing cell tumorigenicity.

Hsp27 negatively regulates cell death by interacting with cytochrome c.

Mammalian cells respond to stress by accumulating or activating a set of highly conserved proteins known as heat-shock proteins (HSPs). Several of these proteins interfere negatively with apoptosis. We show that the small HSP known as Hsp27 inhibits cytochrome-c-mediated activation of caspases in the cytosol. Hsp27 does not interfere with granzyme-B-induced activation of caspases, nor with apoptosis-inducing factor-mediated, caspase-independent, nuclear changes. Hsp27 binds to cytochrome c released from the mitochondria to the cytosol and prevents cytochrome-c-mediated interaction of Apaf-1 with procaspase-9. Thus, Hsp27 interferes specifically with the mitochondrial pathway of caspase-dependent cell death.