Anoikis: an emerging hallmark in health and diseases.

Anoikis is a programmed cell death occurring upon cell detachment from the correct extracellular matrix, thus disrupting integrin ligation. It is a critical mechanism in preventing dysplastic cell growth or attachment to an inappropriate matrix. Anoikis prevents detached epithelial cells from colonizing elsewhere and is thus essential for tissue homeostasis and development. As anchorage-independent growth and epithelial-mesenchymal transition, two features associated with anoikis resistance, are crucial steps during tumour progression and metastatic spreading of cancer cells, anoikis deregulation has now evoked particular attention from the scientific community. The aim of this review is to analyse the molecular mechanisms governing both anoikis and anoikis resistance, focusing on their regulation in physiological processes, as well as in several diseases, including metastatic cancers, cardiovascular diseases and diabetes.

Redox regulation of anoikis resistance of metastatic prostate cancer cells: key role for Src and EGFR-mediated pro-survival signals.

Resistance to detachment-induced apoptosis, a process commonly referred as anoikis, is emerging as a hallmark of metastatic malignancies, mainly because it can ensure anchorage-independent growth and survival during organ colonization. Besides, a sustained oxidative stress has been associated with several steps of carcinogenesis, including transformation and achievement of a motile mesenchymal phenotype. Here, we demonstrate that metastatic prostate carcinoma cells, undergoing a constitutive deregulated production of reactive oxygen species due to sustained activation of 5-lipoxygenase, lack suicidal pathways in response to lack of matrix contact. These amplified and persistent redox signals in PC3 cells leads to maintenance of Src oxidation and activation in the absence of adhesion, thereby sustaining a ligand-independent phosphorylation of epidermal growth factor receptor. This leads to chronic activation of pro-survival signals, culminating in degradation of the pro-apoptotic protein Bim, thereby promoting cell survival even in the absence of proper adhesion. Anoikis sensitivity of metastatic cells is restored with antioxidant intervention or genetic manipulation of the redox-mediated pro-survival pathway, as well as exposure to a pro-oxidant environment strongly increases anoikis resistance in non-transformed prostate epithelial cells. Hence, our results allow new insight into the aetiology of the molecular mechanisms granting anoikis resistance of metastatic cancers, opening new avenues to pharmacological intervention for antioxidant-sensitive invasive tumours.

Down-regulation of platelet-derived growth factor receptor signaling during myogenesis.

Cell differentiation is often associated with a block in the cell cycle. Growth factor signaling has been reported to be impaired in differentiated cells, due to the withdrawal of growth factors or to transcriptional down-regulation of their receptors. Our proposal is that the down regulation of growth factor signaling may be achieved through an alternative pathway: the decrease of growth factor receptor activation and the ensuing inhibition of intracellular pathways leading the cell to division. Here we report that platelet-derived growth factor receptor (PDGFr) signaling is down-regulated during muscle differentiation, although its expression level remains unchanged. PDGFr signaling inhibition is achieved through a decrease in the receptor tyrosine phosphorylation level, in particular of Tyr716, Tyr751, Tyr857 and Tyr1021, leading to down-regulation of intracellular signaling pathways. Furthermore, during myogenesis, the expression level of several phosphotyrosine phosphatases (PTPs) increases and most of them shift toward the reduced/activated state. We propose a causal link between the down-regulation of PDGFr tyrosine phosphorylation and the increases in PTP specific activity during myogenesis.

Low molecular weight protein-tyrosine phosphatase is involved in growth inhibition during cell differentiation.

Low molecular weight protein-tyrosine phosphatase (LMW-PTP) is an enzyme involved in mitogenic signaling and cytoskeletal rearrangement after platelet-derived growth factor (PDGF) stimulation. Recently, we demonstrated that LMW-PTP is regulated by a redox mechanism involving the two cysteine residues of the catalytic site, which turn reversibly from reduced to oxidized state after PDGF stimulation. Since recent findings showed a decrease of intracellular reactive oxygen species in contact inhibited cells and a lower tyrosine phosphorylation level in dense cultures in comparison to sparse ones, we studied if the level of endogenous LMW-PTP is regulated by growth inhibition conditions, such as cell confluence and differentiation. Results show that both cell confluence and cell differentiation up-regulate LMW-PTP expression in C2C12 and PC12 cells. We demonstrate that during myogenesis LMW-PTP is regulated at translational level and that the protein accumulates at the plasma membrane. Furthermore, we showed that both myogenesis and cell-cell contact lead to a dramatic decrease of tyrosine phosphorylation level of PDGF receptor. In addition, we observed an increased association of the receptor with LMW-PTP during myogenesis. Herein, we demonstrate that myogenesis decreases the intracellular level of reactive oxygen species, as observed in dense cultures. As a consequence, LMW-PTP turns from oxidized to reduced form during muscle differentiation, increasing its activity in growth inhibition conditions such as differentiation. These data suggest that LMW-PTP plays a crucial role in physiological processes, which require cell growth arrest such as confluence and differentiation.

Two vicinal cysteines confer a peculiar redox regulation to low molecular weight protein tyrosine phosphatase in response to platelet-derived growth factor receptor stimulation.

Low molecular weight protein tyrosine phosphatase (LMW-PTP) is an enzyme involved in platelet-derived growth factor (PDGF)-induced mitogenesis and cytoskeleton rearrangement because it is able to bind and dephosphorylate the activated receptor. LMW-PTP presents two cysteines in positions 12 and 17, both belonging to the catalytic pocket; this is a unique feature of LMW-PTP among all protein tyrosine phosphatases. Our previous results demonstrated that in vitro LMW-PTP is oxidized by either H(2)O(2) or nitric oxide with the formation of a disulfide bond between Cys-12 and Cys-17. This oxidation leads to reversible enzyme inactivation because treatment with reductants permits catalytic activity rescue. In the present study we investigated the in vivo inactivation of LMW-PTP by either extracellularly or intracellularly generated H(2)O(2), evaluating its action directly on its natural substrate, PDGF receptor. LMW-PTP is oxidized and inactivated by exogenous oxidative stress and recovers its activity after oxidant removal. LMW-PTP is oxidized also during PDGF signaling, very likely upon PDGF-induced H(2)O(2) production, and recovers its activity within 40 min. Our results strongly suggest that reversibility of in vivo LMW-PTP oxidation is glutathione-dependent. In addition, we propose an intriguing and peculiar role of Cys-17 in the formation of a S-S intramolecular bond, which protects the catalytic Cys-12 from further and irreversible oxidation. On the basis of our results we propose that the presence of an additional cysteine near the catalytic cysteine could confer to LMW-PTP the ability to rapidly recover its activity and finely regulate PDGF receptor activation during both extracellularly and intracellularly generated oxidative stress.

Acylphosphatase is a strong apoptosis inducer in HeLa cell line.

Acylphosphatase (AcP) is a low-molecular-weight protein widely distributed in many vertebrate tissues with a yet unknown physiologic function. To study the in vivo behavior of AcP, HeLa cells were transiently transfected with a vector expressing the AcP/EGFP fusion protein. Analysis of the transfected cells showed a high level of cellular death in cells expressing the AcP/EGFP fusion protein with respect to control cells expressing EGFP alone. Flow cytometry and time lapse analysis of AcP/EGFP transfected cells evidenced a typical pattern of apoptosis. Surprisingly, cells transfected with a mutated form of AcP, with negligible in vitro acylphosphatase activity, undergo apoptosis as well as cells transfected with wild-type protein, suggesting that the physiologic role of AcP could be not related to this catalytic activity.

Stabilisation of alpha-helices by site-directed mutagenesis reveals the importance of secondary structure in the transition state for acylphosphatase folding.

The effects of stabilising mutations on the folding process of common-type acylphosphatase have been investigated. The mutations were designed to increase the helical propensity of the regions of the polypeptide chain corresponding to the two alpha-helices of the native protein. Various synthetic peptides incorporating the designed mutations were produced and their helical content estimated by circular dichroism. The most substantial increase in helical content is found for the peptide carrying five mutations in the second alpha-helix. Acylphosphatase variants containing the corresponding mutations display, to different extents, enhanced conformational stabilities as indicated by equilibrium urea denaturation experiments monitored by changes of intrinsic fluorescence. All the protein variants studied here refold with apparent two-state kinetics. Mutations in the first alpha-helix are responsible for a small increase in the refolding rate, accompanied by a marked decrease in the unfolding rate. On the other hand, multiple mutations in the second helix result in a considerable increase in the refolding rate without any significant effect on the unfolding rate. Addition of trifluoroethanol was found to accelerate the folding of the acylphosphatase variants, the extent of the acceleration being inversely proportional to the intrinsic rate of folding of the corresponding mutant. The trifluoroethanol-induced acceleration is far less marked for those variants whose alpha-helical structure is efficiently stabilised by amino acid replacements. This observation suggests that trifluoroethanol acts in a similar manner to the stabilising mutations in promoting native-like secondary structure. Analysis of the kinetic data indicates that the second helix is fully consolidated in the transition state for folding of acylphosphatase, whereas the first helix is only partially formed. These data suggest that the second helix is an important element in the folding process of the protein.

The inhibitory effect of the 5' untranslated region of muscle acylphosphatase mRNA on protein expression is relieved during cell differentiation.

Previous experiments suggested that the upstream AUG triplet present in the 5' untranslated region (UTR) of muscle acylphosphatase mRNA is involved in the regulation of protein expression. In this paper, we study the involvement of the 5'UTR secondary structure and upstream peptide on mRNA stability and protein translation. Our data, obtained using deletion and frame-shift mutants, demonstrate that the 5'UTR controls protein expression regulating translation together with mRNA stability. Furthermore, we demonstrate that the inhibitory effect of the 5'UTR of muscle acylphosphatase is relieved during the differentiation process in agreement with previous data reporting an increase of acylphosphatase content during cell differentiation. Finally, UV cross-linking experiments show that specific mRNA-binding proteins are associated with the 5'UTR of the muscle acylphosphatase mRNA.

Acceleration of the folding of acylphosphatase by stabilization of local secondary structure.

The addition of trifluoroethanol or hexafluoroisopropanol converts the apparent two-state folding of acylphosphatase, a small alpha/beta protein, into a multistate mechanism where secondary structure accumulates significantly in the denatured state before folding to the native state. This results in a marked acceleration of folding as revealed by following the intrinsic fluorescence and circular dichroism changes upon folding. The folding rate is at a maximum when the secondary-structure content of the denatured state corresponds to that of the native state, while further stabilization of secondary structure decreases the folding rate. These findings indicate that stabilization of intermediate structure can either enhance or retard folding depending on its nature and content of native-like interactions.

The contribution of acidic residues to the conformational stability of common-type acylphosphatase.

Common-type acylphosphatase is a small cytosolic enzyme whose catalytic properties and three-dimensional structure are known in detail. All the acidic residues of the enzyme have been replaced by noncharged residues in order to assess their contributions to the conformational stability of acylphosphatase. The enzymatic activity parameters and the conformational free energy of each mutant were determined by enzymatic activity assays and chemically induced unfolding, respectively. Some mutants exhibit very similar conformational stability, DeltaG(H2O), and specific activity values as compared to the wild-type enzyme. By contrast, six mutants show a significant reduction of conformational stability and two mutants are more stable than the wild-type protein. Although none of the mutated acidic residues is directly involved in the catalytic mechanism of the enzyme, our results indicate that mutations of residues located on the surface of the protein are responsible for a structural distortion which propagate up to the active site. We found a good correlation between the free energy of unfolding and the enzymatic activity of acylphosphatase. This suggests that enzymatic activity measurements can provide valuable indications on the conformational stability of acylphosphatase mutants, provided the mutated residue lies far apart from the active site. Moreover, our results indicate that the distortion of hydrogen bonds rather than the loss of electrostatic interactions, contributes to the decrease of the conformational stability of the protein.

Thermodynamics and kinetics of folding of common-type acylphosphatase: comparison to the highly homologous muscle isoenzyme.

The thermodynamics and kinetics of folding of common-type acylphosphatase have been studied under a variety of experimental conditions and compared with those of the homologous muscle acylphosphatase. Intrinsic fluorescence and circular dichroism have been used as spectroscopic probes to follow the folding and unfolding reactions. Both proteins appear to fold via a two-state mechanism. Under all the conditions studied, common-type acylphosphatase possesses a lower conformational stability than the muscle form. Nevertheless, common-type acylphosphatase folds more rapidly, suggesting that the conformational stability and the folding rate are not correlated in contrast to recent observations for a number of other proteins. The unfolding rate of common-type acylphosphatase is much higher than that of the muscle enzyme, indicating that the differences in conformational stability between the two proteins are primarily determined by differences in the rate of unfolding. The equilibrium m value is markedly different for the two proteins in the pH range of maximum conformational stability (5. 0-7.5); above pH 8.0, the m value for common-type acylphosphatase decreases abruptly and becomes similar to that of the muscle enzyme. Moreover, at pH 9.2, the dependencies of the folding and unfolding rate constants of common-type acylphosphatase on denaturant concentration (mf and mu values, respectively) are notably reduced with respect to pH 5.5. The pH-induced decrease of the m value can be attributed to the deprotonation of three histidine residues that are present only in the common-type isoenzyme. This would decrease the positive net charge of the protein, leading to a greater compactness of the denatured state. The folding and unfolding rates of common-type acylphosphatase are not, however, significantly different at pH 5.5 and 9.2, indicating that this change in compactness of the denatured and transition states does not have a notable influence on the rate of protein folding.

The Src and signal transducers and activators of transcription pathways as specific targets for low molecular weight phosphotyrosine-protein phosphatase in platelet-derived growth factor signaling.

The low molecular weight phosphotyrosine-protein phosphatase (LMW-PTP) is a cytosolic phosphotyrosine-protein phosphatase specifically interacting with the activated platelet-derived growth factor (PDGF) receptor through its active site. Overexpression of the LMW-PTP results in modulation of PDGF-dependent mitogenesis. In this study we investigated the effects of this tyrosine phosphatase on the signaling pathways relevant for PDGF-dependent DNA synthesis. NIH 3T3 cells were stably transfected with active or dominant negative LMW-PTP. The effects of LMW-PTP were essentially restricted to the G1 phase of the cell cycle. Upon stimulation with PDGF, cells transfected with the dominant negative LMW-PTP showed an increased activation of Src, whereas the active LMW-PTP induced a reduced activation of this proto-oncogene. We observe that c-Src binding to PDGF receptor upon stimulation is prevented by overexpression of LMW-PTP. These effects were associated with parallel changes in myc expression. Moreover, wild-type and dominant negative LMW-PTP differentially regulated STAT1 and STAT3 activation and tyrosine phosphorylation, whereas they did not modify extracellular signal-regulated kinase activity. However, these modifications were associated with changes in fos expression despite the lack of any effect on extracellular signal-regulated kinase activation. Other independent pathways involved in PDGF-induced mitogenesis, such as phosphatidylinositol 3-kinase and phospholipase C-gamma1, were not affected by LMW-PTP. These data indicate that this phosphatase selectively interferes with the Src and the STATs pathways in PDGF downstream signaling. The resulting changes in myc and fos proto-oncogene expression are likely to mediate the modifications observed in the G1 phase of the cell cycle.

The 5'-untranslated region of the human muscle acylphosphatase mRNA has an inhibitory effect on protein expression.

The cDNA of the human muscle type acylphosphatase was isolated and characterized. The mRNA presents a very long 5'-untranslated region, covering the first half of the molecule: 175 bases of this part were cloned and prediction of the possible secondary structure showed that a very stable stem-loop structure could be formed in that region. Moreover, an additional AUG triplet was found upstream of the start codon of the protein, defining an open reading frame of 60 codons which overlapped that of acylphosphatase. The possible regulatory effect on translation of this part of the mRNA molecule was studied by means of transient transfection experiments: a 10-fold decrease in the expression of a reporter protein and a dramatic decrease in the corresponding mRNA was observed, due to the presence of the 5'-untranslated region of acylphosphatase mRNA. Mutagenesis of the upstream AUG triplet eliminated mRNA instability, leading to the hypothesis that the product of the upstream open reading frame could play a role in this mechanism.

Differential migration of acylphosphatase isoenzymes from cytoplasm to nucleus during apoptotic cell death.

The subcellular distribution of both muscle and common type acylphosphatases was studied during apoptosis. Both isoenzymes were previously shown to have in vitro nucleolytic activity having a pH optimum at 6.8. In this paper we demonstrate a nuclear migration of the muscle type isoenzyme in response to various apoptotic stimuli either in K562 or in Jurkat cells, while the common type acylphosphatase isoform remains cytoplasmatic under the same conditions. Furthermore, we present evidences of a direct in vivo interaction between muscle acylphosphatase and two other DNAses of about 60 and 80 kDa in size. Our results are consistent with an in vivo involvement of the muscle isoform in apoptosis, possibly as a part of a multimeric protein complex that binds and hydrolyses DNA during this process.

Mechanism of acylphosphatase inactivation by Woodward's reagent K.

The organ common-type (CT) isoenzyme of acylphosphatase is inactivated by Woodward's reagent K (WRK) (N-ethyl-5-phenylisoxazolium-3'-sulphonate) at pH6.0. The inactivation reaction follows apparent pseudo first-order kinetics. The dependence of the reciprocal of the pseudo first-order kinetic constant (kobs) on the reciprocal WRK concentration reveals saturation kinetics, suggesting that the WRK forms a reversible complex with the enzyme before causing inactivation. Competitive inhibitors, such as inorganic phosphate and ATP, protect the enzyme from WRK inactivation, suggesting that this reagent acts at or near to the enzyme active site. The reagent-enzyme adduct, which elicits a strong absorption band with lambdamax at 346 nm, was separated from unreacted enzyme by reverse phase HPLC and the modified protein was cleaved with endoproteinase Glu-C to produce fragments. The HPLC fractionation gave two reagent-labelled peptides (peak 1 and peak 2) that were analysed by ion-spray MS and sequenced. The former is VFFRKHTQAE (residues 20-29 of human CT acylphosphatase) and the latter IFGKVQGVFFRKHTQAE (residues 13-29). MS demonstrated that both peptides are WRK adducts. A fragment ion with m/z of 1171, which is present in the mass spectrum of peak 1, has been identified as a WRK adduct of the peptide fragment 20-26. The lambdamax at 346 nm of WRK adduct suggests that the modified residue is His-25. Five recombinant enzymes mutated in residues included in the 20-29 polypeptide stretch have been produced. Analysis of their reactivities with WRK demonstrates that His-25 is the molecular target of the reagent as its modification causes the inactivation of the enzyme. Since both His-25-->Gln and His-25-->Phe mutants maintain high catalytic activity, we suggest that the observed enzyme inactivation is caused by the reagent (covalently bound to His-25), which shields the active site.

Characterization of a novel nucleolytic activity of acylphosphatases.

A novel enzymatic activity on nucleic acids was discovered in both muscle type (MT) and erythrocyte or common type (CT) isoforms of acylphosphatase, an enzyme that was previously known as a hydrolase (E.C.3.6.1.7). Both deoxyribonucleic and ribonucleic hydrolitic activity were assayed on a variety of substrates. Our results demonstrate that acylphosphatase possesses both Mg++ dependent deoxyribonuclease and ribonuclease activities, at pH ranging from 5.0 to 6.8. Furthermore, we present evidences, for both isoenzymatic forms, of the coexistence of exonucleolytic and endonucleolytic activities on DNA.

The molecular basis of the differing kinetic behavior of the two low molecular mass phosphotyrosine protein phosphatase isoforms.

The low molecular mass phosphotyrosine protein phosphatase is a cytosolic enzyme of 18 kDa. Mammalian species contain a single gene that codifies for two distinct isoenzymes; they are produced through alternative splicing and thus differ only in the sequence from residue 40 to residue 73. Isoenzymes differ also in substrate specificity and in the sensitivity to activity modulators. In our study, we mutated a number of residues included in the alternative 40-73 sequence by substituting the residues present in the type 2 isoenzyme with those present in type 1 and subsequently examined the kinetic properties of the purified mutated proteins. The results enabled us to identify the molecular site that determines the kinetic characteristics of each isoform; the residue in position 50 plays the main role in the determination of substrate specificity, while the residues in both positions 49 and 50 are involved in the strong activation of the type 2 low M(r) phosphotyrosine protein phosphatase isoenzyme by purine compounds such as guanosine and cGMP. The sequence 49-50 is included in a loop whose N terminus is linked to the beta 2-strand and whose C terminus is linked to the alpha 2-helix; this loop is very near the active site pocket. Our findings suggest that this loop is involved both in the regulation of the enzyme activity and in the determination of the substrate specificity of the two low M(r) phosphotyrosine protein phosphatase isoenzymes.

Differential modulation of expression of the two acylphosphatase isoenzymes by thyroid hormone.

The modulation of expression of the skeletal muscle and erythrocyte acylphosphatase isoenzymes by thyroid hormone has been investigated. Our results indicate a differential regulation of the two enzymic isoforms by tri-iodothyronine (T3) in K562 cells in culture: an increase in the specific mRNA during T3-stimulation is shown only for the skeletal muscle isoenzyme. A fast and transient T3 induction of the accumulation of the specific mRNA can be observed, reaching a maximum 8 h after hormone treatment and then rapidly decreasing almost to the steady-state level after 24 h. A nuclear run-on assay was performed to explore the mechanisms of this regulation. These studies indicate that T3 induction of skeletal muscle acylphosphatase mRNA is due, at least in part, to a fast and transient increase in the rate of gene transcription, within 4 h after hormone administration. A very rapid decrease is then observed within a further 2 h. T3-dependent accumulation of the mRNA for the skeletal muscle acylphosphatase requires ongoing protein synthesis, as confirmed by inhibition with cycloheximide or puromycin. These findings indicate that the transcriptional regulation of the gene may be indirect.

Cloning and expression of the cDNA coding for the erythrocyte isoenzyme of human acylphosphatase.

Three independent cDNAs coding for the erythrocyte isoform of human acylphosphatase were isolated and characterized. All the clones were incomplete at the 5' end, but Northern blot analysis using the cDNA as a probe showed the presence of an unusually long mRNA 5'-untranslated region. The transcript was present in a variety of human cell lines of different origins, although at different levels. Southern blot analysis on DNA from different individuals revealed a simple hybridization pattern. Large amounts of pure enzyme with kinetic characteristics very similar to those of the native protein were expressed in E. coli.