Protein C‐terminal enzymatic labeling identifies novel caspase cleavages during the apoptosis of multiple myeloma cells induced by kinase inhibition

Caspase activation and proteolytic cleavages are the major events in the early stage of apoptosis. Identification of protein substrates cleaved by caspases will reveal the occurrence of the early events in the apoptotic process and may provide potential drug targets for cancer therapy. Although several N‐terminal MS‐based proteomic approaches have been developed to identify proteolytic cleavages, these methods have their inherent drawbacks. Here we apply a previously developed proteomic approach, protein C‐terminal enzymatic labeling (ProC‐TEL), to identify caspase cleavage events occurring in the early stage of the apoptosis of a myeloma cell line induced by kinase inhibition. Both previously identified and novel caspase cleavage sites are detected and the reduction of the expression level of several proteins is confirmed biochemically upon kinase inhibition although the current ProC‐TEL procedure is not fully optimized to provide peptide identifications comparable to N‐terminal labeling approaches. The identified cleaved proteins form a complex interaction network with central hubs determining morphological changes during the apoptosis. Sequence analyses show that some ProC‐TEL identified caspase cleavage events are unidentifiable when traditional N‐terminomic approaches are utilized. This work demonstrates that ProC‐TEL is a complementary approach to the N‐terminomics for the identification of proteolytic cleavage events such as caspase cleavages in signaling pathways.     

Regulation of DNA fragmentation: the role of caspases and phosphorylation

DNA fragmentation is a hallmark of apoptosis that is induced by apoptotic stimuli in various cell types. Apoptotic signal pathways, which eventually cause DNA fragmentation, are largely mediated by the family of cysteinyl aspartate-specific protease caspases. Caspases mediate apoptotic signal transduction by cleavage of apoptosis-implicated proteins and the caspases themselves. In the process of caspase activation, reversible protein phosphorylation plays an important role. The activation of various proteins is regulated by phosphorylation and dephosphorylation, both upstream and downstream of caspase activation. Many kinases/phosphatases are involved in the control of cell survival and death, including the mitogen-activated protein kinase signal transduction pathways. Reversible protein phosphorylation is involved in the widespread regulation of cellular signal transduction and apoptotic processes. Therefore, phosphatase/kinase inhibitors are commonly used as apoptosis inducers/inhibitors. Whether protein phosphorylation induces apoptosis depends on many factors, such as the type of phosphorylated protein, the degree of activation and the influence of other proteins. Phosphorylation signaling pathways are intricately interrelated; it was previously shown that either induction or inhibition of phosphorylation causes cell death. Determination of the relationship between protein and phosphorylation helps to reveal how apoptosis is regulated. Here we discuss DNA fragmentation and protein phosphorylation, focusing on caspase and serine/threonine protein phosphatase activation.     

Regulation of cell proliferation and survival: Convergence of protein kinases and caspases

Intricate networks of protein kinases are intimately involved in the regulation of cellular events related to cell proliferation and survival. In addition to protein kinases, cells also contain networks of proteases including aspartic-acid directed caspases organized in cascades that play a major role in the regulation of cell survival through their involvement in the initiation and execution phases of apoptosis. Perturbations in regulatory protein kinase and caspase networks induce alterations in cell survival and frequently accompany transformation and tumorigenesis. Furthermore, recent studies have documented that caspases or their substrates are subject to phosphorylation in cells illustrating a potential convergence of protein kinase and caspase signaling pathways. Interestingly, a number of caspase substrates are protected from cleavage when they are phosphorylated at sites that are adjacent to caspase cleavage sites. While it is theoretically possible that many distinct protein kinases could protect proteins from caspase-mediated cleavage, protein kinase CK2 is of particular interest because acidic amino acids, including aspartic acid residues that are recognized by caspases, are its dominant specificity determinants.     

Impact of protein kinase CK2 on inhibitor of apoptosis proteins in prostate cancer cells

We have previously demonstrated that protein kinase CK2 is a potent suppressor of apoptosis in cells subjected to diverse mediators of apoptosis. The process of apoptosis involves a complex series of molecules localized in various cellular compartments. Among the various proteins that modulate apoptotic activity are inhibitors of apoptosis proteins (IAPs) which are elevated in cancers and have been proposed to block caspase activity. We have examined the impact of CK2 signal on these proteins in prostate cancer cells. Cellular IAPs demonstrate distinct localization and responsiveness to altered CK2 expression or activity in the cytoplasmic and nuclear matrix fractions. Modulation of cellular CK2 by various approaches impacts on cellular IAPs such that inhibition or downregulation of CK2 results in reduction in these proteins. Further, IAPs are also reduced when cells are treated with sub-optimal concentrations of chemical inhibitors of CK2 combined with low or sub-optimal levels of apoptosis-inducing agents (such as etoposide) suggesting that downregulation of CK2 sensitizes cells to induction of apoptosis which may be related to attenuation of IAPs. Decreased IAP protein levels in response to apoptotic agents such as TNFalpha or TRAIL were potently blocked upon forced overexpression of CK2 in cells. Together, our results suggest that one of the modes of CK2-mediated modulation of apoptotic activity is via its impact on cellular IAPs.     

Functional interplay between caspase cleavage and phosphorylation sculpts the apoptotic proteome

Caspase proteases are principal mediators of apoptosis, where they cleave hundreds of proteins. Phosphorylation also plays an important role in apoptosis, although the extent to which proteolytic and phosphorylation pathways crosstalk during programmed cell death remains poorly understood. Using a quantitative proteomic platform that integrates phosphorylation sites into the topographical maps of proteins, we identify a cohort of over 500 apoptosis-specific phosphorylation events and show that they are enriched on cleaved proteins and clustered around sites of caspase proteolysis. We find that caspase cleavage can expose new sites for phosphorylation, and, conversely, that phosphorylation at the +3 position of cleavage sites can directly promote substrate proteolysis by caspase-8. This study provides a global portrait of the apoptotic phosphoproteome, revealing heretofore unrecognized forms of functional crosstalk between phosphorylation and caspase proteolytic pathways that lead to enhanced rates of protein cleavage and the unveiling of new sites for phosphorylation.     

Conservation of caspase substrates across metazoans suggests hierarchical importance of signaling pathways over specific targets and cleavage site motifs in apoptosis

Caspases, cysteine proteases with aspartate specificity, are key players in programmed cell death across the metazoan lineage. Hundreds of apoptotic caspase substrates have been identified in human cells. Some have been extensively characterized, revealing key functional nodes for apoptosis signaling and important drug targets in cancer. But the functional significance of most cuts remains mysterious. We set out to better understand the importance of caspase cleavage specificity in apoptosis by asking which cleavage events are conserved across metazoan model species. Using N-terminal labeling followed by mass spectrometry, we identified 257 caspase cleavage sites in mouse, 130 in Drosophila, and 50 in Caenorhabditis elegans. The large majority of the caspase cut sites identified in mouse proteins were found conserved in human orthologs. However, while many of the same proteins targeted in the more distantly related species were cleaved in human orthologs, the exact sites were often different. Furthermore, similar functional pathways are targeted by caspases in all four species. Our data suggest a model for the evolution of apoptotic caspase specificity that highlights the hierarchical importance of functional pathways over specific proteins, and proteins over their specific cleavage site motifs.     

Regulation of caspase 9 through phosphorylation by protein kinase C zeta in response to hyperosmotic stress

Caspase 9 is a critical component of the mitochondrial or intrinsic apoptotic pathway and is activated by Apaf-1 following release of cytochrome c from mitochondria in response to a variety of stimuli. Caspase 9 cleaves and activates effector caspases, mainly caspase 3, leading to the demise of the cell. Survival signaling pathways can impinge on this pathway to restrain apoptosis. Here, we have identified Ser144 of human caspase 9as an inhibitory site that is phosphorylated in a cell-free system and in cells in response to the protein phosphatase inhibitor okadaic acid. Inhibitor sensitivity and interactions with caspase 9 indicate that the predominant kinase that targets Ser144 is the atypical protein kinase C isoform zeta (PKCzeta). Prevention of Ser144 phosphorylation by inhibition of PKCzeta or mutation of caspase 9 promotes caspase 3 activation. Phosphorylation of serine 144 in cells is also induced by hyperosmotic stress, which activates PKCzeta and regulates its interaction with caspase 9, but not by growth factors, phorbol ester, or other cellular stresses. These results indicate that phosphorylation and inhibition of caspase 9 by PKCzeta restrain the intrinsic apoptotic pathway during hyperosmotic stress. This work provides further evidence that caspase 9 acts as a focal point for multiple protein kinase signaling pathways that regulate apoptosis.     

Drosophila caspase transduces Shaggy/GSK-3beta kinase activity in neural precursor development

Caspases are well known for their role in the execution of apoptotic programs, in which they cleave specific target proteins, leading to the elimination of cells, and for their role in cytokine maturation. In this study, we identified a novel substrate, which, through cleavage by caspases, can regulate Drosophila neural precursor development. Shaggy (Sgg)46 protein, an isoform encoded by the sgg gene and essential for the negative regulation of Wingless signaling, is cleaved by the Dark-dependent caspase. This cleavage converts it to an active kinase, which contributes to the formation of neural precursor (sensory organ precursor (SOP)) cells. Our evidence suggests that caspase regulation of the wingless pathway is not associated with apoptotic cell death. These results imply a novel role for caspases in modulating cell signaling pathways through substrate cleavage in neural precursor development.     

Cellular regulators of protein kinase CK2

Protein phosphorylation is a key regulatory post-translational modification and is involved in the control of many cellular processes. Protein kinase CK2, formerly known as casein kinase II, which is a ubiquitous and highly conserved protein serine/threonine kinase, plays a central role in the control of a variety of pathways in cell proliferation, transformation, apoptosis and senescence. An understanding of the regulation of such a central protein kinase would greatly help our comprehension of the regulation of many pathways in cellular regulation. A number of reviews have addressed the detection, the development, and the characterization of inhibitors of CK2. The present review focuses on possible natural regulators of CK2, i.e. proteins and other cellular factors that bind to CK2 and thereby regulate its activity.     

A CK2-dependent mechanism for degradation of the PML tumor suppressor

The PML tumor suppressor controls key pathways for growth suppression, induction of apoptosis, and cellular senescence. PML loss occurs frequently in human tumors through unknown posttranslational mechanisms. Casein kinase 2 (CK2) is oncogenic and frequently upregulated in human tumors. Here we show that CK2 regulates PML protein levels by promoting its ubiquitin-mediated degradation dependent on direct phosphorylation at Ser517. Consequently, PML mutants that are resistant to CK2 phosphorylation display increased tumor-suppressive functions. In a faithful mouse model of lung cancer, we demonstrate that Pml inactivation leads to increased tumorigenesis. Furthermore, CK2 pharmacological inhibition enhances the PML tumor-suppressive property in vivo. Importantly, we found an inverse correlation between CK2 kinase activity and PML protein levels in human lung cancer-derived cell lines and primary specimens. These data identify a key posttranslational mechanism that controls PML protein levels and provide therapeutic means toward PML restoration through CK2 inhibition.     

Effect of phosphorylation and single nucleotide polymorphisms on caspase substrates processing

Posttranslational modifications that involve either reversible covalent modification of proteins or irreversible proteolysis are central to the regulation of key cellular mechanisms, including apoptosis, cell-cycle regulation and signal transduction. There is mounting evidence suggesting cross-talk between proteases and kinases. For instance: caspases, a class of proteases involved in programmed cell death—apoptosis, cleave a large set of various types of proteins. Simultaneously, kinases restrict caspase activity by phosphorylating their protein substrates in the vicinity of cleavage site. In addition, the caspase cleavage pattern in target proteins may be modified as a result of single nucleotide polymorphisms (SNPs) in the coding gene. This may either create a novel cleavage site, or increase/decrease the cleavage efficiency of a substrate. Such point mutations are often associated with the onset of disease. In this study, we predicted how phosphorylation and SNPs affect known human caspase proteolytic events collected in the CASBAH and Degrabase databases by applying Random Forest caspases’ substrates prediction method, as implemented in the CaspDB, and the molecular dynamics free energy simulations approach. Our analysis confirms several experimental observations. Phosphorylation could have both positive or negative regulatory effects depending on its position with respect to the caspase cleavage site. For instance, we demonstrate that phosphorylation at P1′ is the most detrimental for proteolytic efficiency of caspases. Phosphorylation at the P2 and P2′ positions also negatively affect the cleavage events. In addition, we uncovered SNPs in 11 caspase substrates capable of completely abolishing the cleavage site due to polymorphism at the P1 position. The findings presented here may be useful for determining the link between aberrant proteolysis and disease.     

Post-translational modification of Bid has differential effects on its susceptibility to cleavage by caspase 8 or caspase 3

Bid is instrumental in death receptor-mediated apoptosis where it is cleaved by caspase 8 at aspartate 60 and aspartate 75 to generate truncated Bid (tBID) forms that facilitate release of mitochondrial cytochrome c. Bid is also cleaved at these sites by caspase 3 that is activated downstream of cytochrome c release after diverse apoptotic stimuli. In this context, tBid may amplify the apoptotic process. Bid is phosphorylated in vitro by casein kinases that regulate its cleavage by caspase 8 (Desagher, S., Osen-Sand, A., Montessuit, S., Magnenat, E., Vilbois, F., Hochmann, A., Journot, L. Antonsson, A., and Martinou, J.-C. (2001) Mol. Cell 8, 601-611). Using a Bid decapeptide substrate, we observed that phosphorylation at threonine 59 inhibited cleavage by caspase 8. This was also seen when recombinant Bid (rBid) and Bid isolated from murine kidney were incubated with casein kinase II. However, there were differences in the susceptibility of rBid and isolated Bid to cleavage by caspases 3 and 8. Caspase 8 cleaved rBid to generate two C-terminal products, p15 and p13 tBid, but produced only p15 tBid from isolated Bid. Contrary to rBid, isolated Bid was resistant to cleavage by caspase 3, yet was readily cleaved within the cytosolic milieu. Our data suggest that one or more distinct cellular mechanisms regulate Bid cleavage by caspases 8 and 3 in situ.     

A subset of caspase substrates functions as the Jekyll and Hyde of apoptosis

Cleavage of caspase substrates is believed to be the commitment point that will lead a cell towards apoptosis. While the cleavage of some caspase substrates participates directly in the dismantling of the cell, others regulate the extent of caspase activation. In this communication, we discuss some recent findings indicating that two caspase substrates, MEKK1 and RasGAP, change their functions from anti- to pro-apoptotic as caspase activity increases. MEKK1 is a MAPK kinase kinase regulating the JNK MAPK pathway. As a full-length protein, MEKK1 generates protective signals (e.g. in cardiomyocytes), but potentiates apoptosis when cleaved by caspases. This switch is mediated by a translocation of the kinase activity from insoluble to soluble cellular structures. RasGAP is a regulator of Ras GTPase family members. As a full-length protein, RasGAP does not modulate apoptosis. However, low caspase activity readily induces the cleavage of RasGAP into an N-terminal fragment that generates potent anti-apoptotic signals. At higher caspase activity, the N-terminal fragment is further cleaved into two fragments that strongly potentiate apoptosis. RasGAP can, thus, be viewed as an apoptostat because it allows the cells to determine when caspases have been mildly activated to fulfill functions other than apoptosis or when caspases are strongly activated to mediate apoptosis.     

The lysine-specific demethylase 1 is a novel substrate of protein kinase CK2

Protein kinase CK2 is a pleiotropic serine/threonine kinase responsible for the generation of a substantial proportion of the human phosphoproteome. CK2 is generally found as a tetramer with two catalytic, α and α′ and two non catalytic β subunits. CK2α C-terminal tail phosphorylation is regulated during the mitotic events and the absence of these phosphosites in α′ suggests an isoform specialization. We used a proteomic approach to identify proteins specifically phosphorylated by a CK2α phosphomimetic mutant, CK2αT344ET360ES362ES370E (CK2α4E), in human neuroblastoma SKNBE cellular extract. One of these proteins is lysine-specific demethylase 1 (LSD1 or KDM1A), an important player of the epigenetic machinery. LSD1 is a FAD-dependent amine oxidase and promotes demethylation of lysine 4 and lysine 9 of mono- and di-methylated histone H3. We found that LSD1 is a new substrate and an interacting partner of protein kinase CK2. Three CK2 phosphosites, (Ser131, Ser137 and Ser166) in the N-terminal region of LSD1 have been identified. This domain is found in all chordates but not in more ancient organisms and it is not essential for LSD1 catalytic event while it could modulate the interaction with CK2 and with other partners in gene repressing and activating complexes. Our data support the view that the phosphorylation of the N-terminal domain by CK2 may represent a mechanism for regulating histone methylation, disclosing a new role for protein kinase CK2 in epigenetics.     

Both phosphorylation and caspase-mediated cleavage contribute to regulation of the Ste20-like protein kinase Mst1 during CD95/Fas-induced apoptosis

The serine/threonine kinase Mst1, a mammalian homolog of the budding yeast Ste20 kinase, is cleaved by caspase-mediated proteolysis in response to apoptotic stimuli such as ligation of CD95/Fas or treatment with staurosporine. Furthermore, overexpression of Mst1 induces morphological changes characteristic of apoptosis in human B lymphoma cells. Mst1 may therefore represent an important target for caspases during cell death which serves to amplify the apoptotic response. Here we report that Mst1 has two caspase cleavage sites, and we present evidence indicating that cleavage may occur in an ordered fashion and be mediated by distinct caspases. We also show that caspase-mediated cleavage alone is insufficient to activate Mst1, suggesting that full activation of Mst1 during apoptosis requires both phosphorylation and proteolysis. Another role of phosphorylation may be to influence the susceptibility of Mst1 to proteolysis. Autophosphorylation of Mst1 on a serine residue close to one of the caspase sites inhibited caspase-mediated cleavage in vitro. Finally, Mst1 appears to function upstream of the protein kinase MEKK1 in the SAPK pathway. In conclusion, Mst1 activity is regulated by both phosphorylation and proteolysis, suggesting that protein kinase and caspase pathways work in concert to regulate cell death.     

Protein kinase CK2 links polyamine metabolism to MAPK signalling in Drosophila

MAPK signalling is a complex process not only requiring the core components Raf, MEK and Erk, but also many proteins like the scaffold protein KSR and several kinases to specifically localize, modulate and fine-tune the outcome of the pathway in a cell context specific manner. In mammals, protein kinase CK2 was shown to bind to the scaffold protein KSR and to phosphorylate Raf proteins at a conserved serine residue in the negative-charge regulatory (N−) region, thereby facilitating maximal activity of the MAPK signalling pathway. In this work we show that in Drosophila CK2 is also bound to KSR. However, despite the presence of a corresponding serine residue in the N-region of DRaf, CK2-mediated phosphorylation of DRaf takes place on a serine residue at the N-terminus and is required for Erk activation. Previous work identified polyamines as regulators of CK2 kinase activity. The main cellular source of polyamines is the catabolism of amino acids. Evidence is provided that phosphorylation of DRaf by CK2 is modulated by polyamines, with spermine being the most potent inhibitor of the reaction. We suggest that CK2 is able to monitor intracellular polyamine levels and translates this information to modulate MAPK signalling.     

An Unbiased Proteomic Screen Reveals Caspase Cleavage Is Positively and Negatively Regulated by Substrate Phosphorylation

Post-translational modifications of proteins regulate diverse cellular functions, with mounting evidence suggesting that hierarchical cross-talk between distinct modifications may fine-tune cellular responses. For example, in apoptosis, caspases promote cell death via cleavage of key structural and enzymatic proteins that in some instances is inhibited by phosphorylation near the scissile bond. In this study, we systematically investigated how protein phosphorylation affects susceptibility to caspase cleavage using an N-terminomic strategy, namely, a modified terminal amino isotopic labeling of substrates (TAILS) workflow, to identify proteins for which caspase-catalyzed cleavage is modulated by phosphatase treatment. We validated the effects of phosphorylation on three of the identified proteins and found that Yap1 and Golgin-160 exhibit decreased cleavage when phosphorylated, whereas cleavage of MST3 was promoted by phosphorylation. Furthermore, using synthetic peptides we systematically examined the influence of phosphoserine throughout the entirety of caspase-3, -7, and -8 recognition motifs and observed a general inhibitory effect of phosphorylation even at residues considered outside the classical consensus motif. Overall, our work demonstrates a role for phosphorylation in controlling caspase-mediated cleavage and shows that N-terminomic strategies can be tailored to study cross-talk between phosphorylation and proteolysis.Apoptosis is a cell death program integral to various biological processes such as tissue homeostasis and development (1). The ability of cancer cells to evade apoptosis is considered a driving feature that imparts a selective cellular advantage allowing cells to persist inappropriately (2). A major component of apoptotic evasion in cancer arises from the misregulation of two enzyme classes, protein kinases and caspases. Kinases transfer the γ-phosphate from ATP to proteins to alter substrate function, and caspases act as executioners of the apoptotic program by facilitating the demolition of cellular constituents by cleaving key structural and enzymatic proteins (3, 4). Attenuation of caspase activity arising through kinase-mediated post-translational modifications or genetic mutations or deletions can contribute to malignant phenotypes by blocking apoptotic progression (5, 6).Interestingly, numerous examples have implicated cross-talk between caspases and kinases as a major apoptotic regulatory mechanism, and anecdotal examples have been identified in which phosphorylation at P4, P2, and P1′ (see Fig. 1A for cleavage site nomenclature) has been shown to block cleavage and affect cellular phenotypes (6–12). Accordingly, phosphorylation-dependent regulation of caspase-mediated cleavage has been hypothesized as a global regulator of apoptotic progression, especially in the context of cancer, where hyperactive, oncogenic kinases may act to increase phosphosite occupancy within caspase cleavage motifs (7). Indeed, we previously tested this hypothesis using predictive peptide match programs and identified CK2 phosphorylation sites on caspase-3 that regulated its activation by caspase-8 and -9 (13).Open in a separate windowFig. 1.Workflow for the global, unbiased analysis of the integration of phosphorylation and caspase-mediated degradation. A, illustration of the cleavage site nomenclature for proteases. Caspases cleave the scissile bond between a P1 aspartic acid and the P1′ residue. B, HeLa cell lysates were treated with or without λ phosphatase and subjected to caspase treatment followed by dephosphorylation of the sample previously left phosphorylated. Primary amines on protein N termini and lysine residues were dimethylated using heavy (+34, open circles) or light (+28, black circles) formaldehyde. Samples were pooled and trypsinized, which exposed an amine on the N terminus of the internal tryptic peptide. These peptides are captured through reaction with an ∼80-kDa aldehyde-substituted polymer. Importantly, native protein N termini and neo-N termini generated by caspase cleavage are resistant to reaction with the polymer because their reactive amines have been blocked by dimethylation. Enrichment of the N-terminome then occurs via negative selection when the reacted polymer is filtered away using a 10-kDa cut-off spin column. LC-MS/MS analysis of isotopically dimethylated peptides then allows comparative analysis between caspase degradomes of phosphorylated and dephosphorylated lysates. Caspase substrates will be inferred through identification of those peptides with a P1 aspartic acid. In the event that there is no difference in caspase substrate proteolysis between phosphorylated and dephosphorylated samples, a peptide ratio of ∼1:1 will be observed in MS1 [1]. Of interest are those peptide pairs that deviate from a 1:1 ratio [2].To build on our predictive strategy, we devised an unbiased, proteomic methodology to identify novel proteins for which phosphorylation regulates cleavage via caspases. We measured the caspase degradome in the context of a native phosphoproteome and compared it to the caspase degradome generated from lysates formerly dephosphorylated with λ bacteriophage phosphatase. To identify these events, we utilized the N-terminomic workflow TAILS¹ (terminal amino isotopic labeling of substrates) (14). Comparative analysis of the caspase degradomes from phosphorylated and dephosphorylated lysates revealed Yap1 and Golgin-160 as caspase substrates negatively regulated by phosphorylation.Surprisingly, we also identified a number of caspase substrates for which cleavage is promoted by phosphorylation, and during the course of our study, Dix et al. (15) demonstrated that phosphorylation at P3 can promote the cleavage of caspase peptide substrates. Our proteomic screen highlighted MST3 as a caspase substrate positively regulated by phosphorylation; however, in contrast to results obtained for MST3 protein in lysates, phosphorylation exerted a negative influence on the cleavage of an MST3 peptide, as was the case for other peptides modeled after Yap1 and Golgin-160. Collectively, these data suggest that although inhibitory effects of phosphorylation can arise through phosphorylation of residues proximal to the cleavage site, the positive effect of phosphorylation may stem from determinants other than those near the scissile bond. Subsequently, to test the effect of phosphorylation throughout the entirety of the caspase motif, we systematically walked phosphoserine through the length of model caspase-3, -7, and -8 substrate peptides and found that phosphorylation was generally inhibitory to caspase cleavage. Again, these observations suggest that positive effects of phosphorylation on the caspase cleavage of proteins observed in lysates likely arise through modulated ternary protein structure. Overall, our studies demonstrate that N-terminomics approaches can be tailored to identify novel, hierarchical events controlling the cleavage of caspase substrates.     

Basal caspase activity promotes migration and invasiveness in glioblastoma cells

Glioblastomas, the most malignant of all brain tumors, are characterized by cellular resistance to apoptosis and a highly invasive growth pattern. These factors contribute to the poor response of glioblastomas to radiochemotherapy and prevent their complete neurosurgical resection. However, the driving force behind the distinct motility of glioma cells is only partly understood. Here, we report that in the absence of cellular stress and proapoptotic stimuli, human glioblastoma cells exhibit a constitutive activation of caspases in vivo and in vitro. The inhibition of caspases by various peptide inhibitors decreases the migration of cells in scrape motility assays and the invasiveness of cells in spheroid assays. Similarly, specific small interfering RNA- or antisense-mediated down-regulation of caspase-3 and caspase-8 results in an inhibition of the migratory potential of glioma cells. The constitutive caspase-dependent motility of glioblastoma cells is independent of CD95 activation and it is not mediated by mitogen-activated protein/extracellular signal-regulated kinase kinase signaling. The basal caspase activity is accompanied by a constant cleavage of the motility-associated gelsolin protein, which may contribute to the caspase-mediated promotion of migration and invasiveness in glioblastoma cells. Our results suggest that the administration of low doses of caspase inhibitors that block glioma cell motility without affecting the execution of apoptotic cell death may be exploited as a novel strategy for the treatment of glioblastomas.     

蛋白激酶CK2在神经退行性疾病病理生理机制中的作用及应用进展

蛋白激酶CK2(casein kinase 2,CK2)是一种高度保守的丝/苏氨酸蛋白激酶,广泛分布于真核细胞的胞质和胞核中.CK2可通过对其底物的磷酸化作用调制底物的生物学活性,从而参与细胞内多条重要的信号转导通路.越来越多的研究发现,在多种神经退行性疾病中CK2表达及活性异常,是其病理生理机制的重要一环,提示CK2...