The role of cathepsin X in cell signaling

Cathepsin X is a lysosomal cysteine protease, found predominantly in cells of monocyte/macrophage lineage. It acts as a monocarboxypepidase and has a strict positional and narrower substrate specificity relative to the other human cathepsins. In our recent studies we identified—β₂ subunit of integrin receptors and α and γ enolase as possible substrates for cathepsin X carboxypeptidase activity. In both cases cathepsin X is capable to cleave regulatory motifs at C-terminus affecting the function of targeted molecules. We demonstrated that via activation of β₂ integrin receptor Mac-1 (CD11b/CD18) active cathepsin X enhances adhesion of monocytes/macrophages to fibrinogen and regulates the phagocytosis. By activation of Mac-1 receptor cathepsin X may regulate also the maturation of dendritic cells, a process, which is crucial in the initiation of adaptive immunity. Cathepsin X activates also the other β₂ integrin receptor, LFA-1 (CD11a/CD18) which is involved in the proliferation of T lymphocytes. By modulating the activity of LFA-1 cathepsin X causes cytoskeletal rearrangements and morphological changes of T lymphocytes enhancing ameboid-like migration in 2-D and 3-D barriers and increasing homotypic aggregation. The cleavage of C-terminal amino acids of α and γ enolase by cathepsin X abolishes their neurotrophic activity affecting neuronal cell survival and neuritogenesis.Key words: cathepsin X, integrin, enolase, T lymphocyte, macrophage, dendritic cell, adhesion, migration, neuritogenesisProteases comprise a group of enzymes that catalyse the cleavage of a peptide bond in a polypeptide chain by nucleophilic attack on the carbonyl carbon. The proteases are either exopeptidases cleaving one or a few amino acids at the N- or C-terminus of polypeptide chain or endopeptidases that cleave the peptide bond internally. According to the catalytic mechanism the endopeptidases are divided into aspartic, cysteine, serine, threonine and metallo endoproteases—see MEROPS database.¹ To date, 561 genes encoding for proteases have been identified in human genome. Among them 148 genes encode for cysteine proteases including a group of eleven lysosomal cysteine proteases (members of C1 family) also called cathepsins. They exhibit different expression patterns, levels and specificities, all of which contribute to their differential physiological roles. Some of them, like cathepsins B, H, L and C are ubiquitously present in tissues, whereas others (cathepsins S, V, X, O, K, F and W) are expressed by specific cell types. Cysteine cathepsins were long believed to be responsible for the terminal protein degradation in the lysosomes, however, this view has changed dramatically when they have been found to be involved in a number of important cellular processes and pathologies.^2,3In contrast to other cathepsins, cathepsin X was discovered only recently. Its gene,^4,5 structure^6,7 and activity properties^8,9 show several unique features that distinguish it clearly from other human cysteine proteases. It has a very short pro-region⁷ and a three residue insertion motif which forms a characteristic “mini loop.”⁶ Cathepsin X exhibits carboxypeptidase activity⁶ and, in contrast to cathepsin B, the other carboxypeptidase, it does not act as an endopeptidase. Contrary to the first reports,⁴ cathepsin X is not widely expressed in cells and tissues, but is restricted to the cells of the immune system, predominantly monocytes, macrophages and dendritic cells.¹⁰ Higher levels of cathepsin X were also found in tumor and immune cells of prostate¹¹ and gastric¹² carcinomas and in macrophages of gastric mucosa, especially after infection by Helicobacter pylori.¹³ Recently it was shown that cathepsin X is abundantly expressed in mouse brain cells, in particular glial cells. Its upregulation was also detected in the brains of patients with Alzheimer disease.¹⁴The involvement of cathepsin X in signal transduction is implied by the integrin-binding motifs, present in its pro-form (RGD: Arg-Gly-Asp) and mature form (ECD: Glu-Cys-Asp).^4,5 Moreover, cathepsin X binds cell surface heparan sulfate proteoglycans¹⁵ which are also involved in integrin regulation. A strong co-localization of pro-cathepsin X with β₃ integrin subunit was demonstrated in our study in pro-monocytic U-937 cells.¹⁶ Further, it was reported that the pro-form of cathepsin X interacts with α_vβ₃ integrin through the RGD motif in lamellipodia of human umbilical vein endothelial cells (HUVECs).¹⁷ However, we showed that the active form of cathepsin X co-localized predominantly with β₂ integrin subunit in various cells of monocytes/macrophage lineage. Active cathepsin X was shown to regulate β₂ integrin-dependent adhesion, phagocytosis and T lymphocyte activation by interaction with macrophage antigen-1 (CD11b/CD18, Mac-1). We showed that inhibitors and monoclonal antibodies, capable to impair cathepsin X enzymatic activity, reduced the binding of differentiated U-937 cells to fibrinogen and polystyrene surface in a dose dependent manner. The co-localization of active cathepsin X with β₂ integrin chain was particularly enhanced in interactions of monocyte/macrophages with endothelial and tumor cells.Besides in monocytes and macrophages the active cathepsin X plays a role in β₂ integrin activation also in dendritic cells (DC), which are crucial for effective antigen presentation and initiation of T cell dependent immune response. Maturation of dendritic cells is accompanied by a range of morphological and cytoskeleton structure changes. In response to maturation stimuli in vitro, DCs rapidly adhere, develop polarity and assemble actin rich structures at the leading edge, known as podosomes.¹⁸ The adhesion of immature DCs to the extracellular matrix, is accompanied by recruitment of Mac-1 integrin receptor, which can be activated by cathepsin X. We have shown that, during maturation, cathepsin X translocates to the plasma membrane of maturing DCs, enabling Mac-1 activation and, consequently, cell adhesion.¹⁹ In mature DCs cathepsin X redistributes from the membrane to the perinuclear region, which coincides with the de-adhesion of DCs, formation of cell clusters and acquisition of the mature phenotype. Again, the inhibition of cathepsin X activity during DC differentiation and maturation reduced the capacity of DCs to stimulate T lymphocytes.β₂ integrin receptors are important also in T lymphocyte functions, such as migration and invasion across the endothelium and tissues. Lymphocyte function-associated antigen-1 (CD11a/CD18, LFA-1), the predominant β₂ integrin receptor in T lymphocytes enables cell-cell interactions and homotypic aggregation via LFA-1-ICAM-1 (intracellular adhesion molecule-1) interactions. LFA-1 can act also as a true signaling receptor, causing F-actin reorganization that leads to cytoskeletal changes of the cell²⁰ and a switch from a spherical to a polarized shape.²¹ Although the concentration of cathepsin X in T lymphocytes is lower compared to monocytes and macrophages, we showed that it interacts with LFA-1 promoting cytoskeleton-dependent morphological changes and migration across 2D and 3D models of ICAM-1 and Matrigel.^22,23 Its co-localization with LFA-1 was particularly evident at the trailing edge protrusion, the uropod, which plays an important role in T lymphocyte migration and cell-cell interactions (Fig. 1). Uropodal active cathepsin X cleaves C-terminal amino acids of β chain in LFA-1 promoting its high affinity conformation and the binding of the cytoskeletal protein talin. This interaction stabilizes the uropod and promotes its elongation (Jevnikar, et al. submitted).Open in a separate windowFigure 1Activation of LFA-1 integrin receptor by cathepsin X at the uropod of T lymphocyte promotes cytoskeleton-dependent morphological changes and cell migration.³⁰We demonstrated that uropods of cathepsin X upregulated T lymphocytes elongate to extreme length and form cell-to-cell connections, the nanotubes (Obermajer, et al. in press). Membrane (or tunneling) nanotubes were recently found as a new principle of cell-to-cell communication enabling transmission of complex and specific messages to distant cells through a physically connected network. Calcium fluxes, vesicles and cell-surface components can all traffic between cells connected by nanotubes. In immune system nanotubes integrate communities of cells for a better coordination of their action in various stages of immune response. We showed that nanotubes of cathepsin X upregulated T lymphocytes could readily transfer cellular organelles such as mitochondria and lysosomes and proposed that nanotube mediated transfer makes possible T lymphocyte activation without the need for direct contact with antigen presenting cells.The exact mechanism of cathepsin X translocation towards plasma membrane and degradation of C-terminal amino acids of β chain remains unclear. In lysosomes cathepsin X can be found as a pro- and active form. After cell activation cathepsin X containing vesicles translocate towards the plasma membrane,¹⁶ as observed also for some other lysosomal proteases.²⁴ During this process it is possible that pro-cathepsin X is activated by the other cysteine protease cathepsin L, as shown already in vitro.⁸ Both proteases were strongly co-localized with β₂ integrin chain at plasma membrane of activated monocytes/macrophages and at uropodes of T lymphocytes. Simultaneous co-localization with the lysosomal markers demonstrates that at least the initial translocation of cathepsin X towards cytoplasmic tail of β₂ integrin chain is vesicular. The interaction of cathepsin X with β₂ integrin subunit was confirmed by immunoprecipitation and FRET.²² According to in vitro experiments we propose that cathepsin X cleaves sequentially C-terminal aminoacids F⁷⁶⁶, A⁷⁶⁷, E⁷⁶⁸ and S⁷⁶⁹ of β₂ integrin subunit (Fig. 2) until reaching proline in penultimate position, confirming previous observation that the proline in S2 position leads to resistance to cathepsin X proteolysis.²⁵ Also, our results are in agreement with the previously mentioned monocarboxypeptidase activity of cathepsin X.^26,27 Since the signaling to and from the integrins is mainly regulated by the short cytoplasmic tail of β₂ subunit,²⁸ cathepsin X mediated β₂ integrin truncation leads to regulation of the receptor signaling. The interaction of cytoplasmic tail with different cytoskeletal and regulatory proteins, such as talin, filamin, radixin and α-actinin is crucial for signal transduction and modulation of cytoskeleton.²⁹Open in a separate windowFigure 2Cathepsin X activates LFA-1 by sequential cleavage of C-terminal amino acids of β₂ integrin subunit.Besides β₂ integrin chain we recently identified isozymes α and γ enolases as another molecular target for cathepsin X carboxypeptidase activity (Obermajer, et al. submitted). We demonstrated that cathepsin X sequentially cleaves C-terminal amino acids of both isozymes, abolishing their neurotrophic activity. On this way the neuronal cell survival and neuritogenesis can be regulated. Inhibition of cathepsin X activity increases the generation of plasmin, essential for neuronal differentiation and changes the length distribution of neurites, especially in the early phase of neurite outgrowth. Moreover, cathepsin X inhibition increases neuronal survival and reduces serum deprivation induced apoptosis, particularly in the absence of nerve growth factor.     

A novel ryanodine receptor expressed in pancreatic islets by alternative splicing from type 2 ryanodine receptor gene

Cyclic ADP-ribose (cADPR), a potent Ca²⁺ mobilizing intracellular messenger synthesized by CD38, regulates the opening of ryanodine receptors (RyRs). Increases in intracellular Ca²⁺ concentrations in pancreatic islets, resulting from Ca²⁺ mobilization from RyRs as well as Ca²⁺ influx from extracellular sources, are important in insulin secretion by glucose. In the present study, by screening a rat islet cDNA library, we isolated a novel RyR cDNA (the islet-type RyR), which is generated from the RyR2 gene by alternative splicing of exons 4 and 75. When the expression vectors for the islet-type and the authentic RyRs were transfected into HEK293 cells, the islet-type RyR2 as well as the authentic one showed high affinity [³H]ryanodine binding. Intracellular Ca²⁺ release in the islet-type RyR2-transfected cells was enhanced in the presence of cADPR but not in the authentic RyR2-transfected cells. The islet-type RyR2 mRNA was expressed in a variety of tissues such as in pancreatic islets, cerebrum, and cerebellum, whereas the authentic RyR2 mRNA was predominantly expressed in heart and aorta. These results suggest that the islet-type RyR2 may be an intracellular target for cADPR signaling.     

Environmental changes affect ecosystem services of the intermittent Lake Cerknica

Lake Cerknica is an intermittent wetland with seasonal water level fluctuations. This paper discusses the possible changes of ecosystem services due to altered ecosystem functions caused by regional climate change. For this purpose, the lake's water regime was analysed and biomass production of common reed (Phragmites australis), the prevailing species, was related to ambient temperatures and water level. The effect of the latter was also examined for reed transpiration rate and plant diversity. The results revealed a gradual loss of seasonality of floods and droughts. High water level in winter months and temperatures at the beginning as well as the end of vegetation period were found to have a significant influence on reed biomass. The plant diversity research in six subsequent years in three different aquatic habitats revealed trends of a decrease due to increased water depth during the vegetation period. The complexity of the system and consequently ecosystem services might also be affected due to changes of other processes, which revealed to be related to water level; namely transpiration rate, plant mycorrhizal colonisation and soil mineralisation.     

In vitro propagation of Asparagus maritimus – A rare Mediterranean salt-resistant species

Asparagus maritimus L. Miller is a rare species growing of the Mediterranean region and is morphologically similar to A. officinalis. In order to establish an efficient in vitro propagation protocol, explants were excised from spear segments and cultured on Murashige and Skoog (1962) medium containing 3% sucrose and various concentrations of growth regulators. The best shoot initiation (3–4 per explant) was achieved on a medium containing 0.88 M N⁶-benzyladenine (BA), 0.93 M kinetin, 1.07 M -naphthaleneacetic acid (NAA) and 3.90 M ancymidol. Shoot initiation could also be achieved without ancymidol but the shoots were thinner and longer. A very high shoot multiplication rate was achieved on media supplemented with 3% sucrose, 1.07 M NAA, 0.93 M kinetin, 0.44 M BA and various concentrations of ancymidol. The lowest concentration of ancymidol (0.39 M) significantly promoted the highest shoot multiplication rate (11.9 shoots/crown). For root formation, media were supplemented with 6% sucrose, 1.07 M NAA and various concentrations of ancymidol. Rooting frequency increased with higher ancymidol concentration up to 5.07 M (82.0% rooting). The number of ex vitro shoots formed was strongly correlated (r=0.66) with the length of roots formed in vitro, which was the highest at a 1.95 M ancymidol.     

Denaturation behavior of α-chymotrypsinogen A in urea and alkylurea solutions: Fluorescence studies

The solvent denaturation of-chymotrypsinogen (-ctg A) in aqueous solution of urea, methyl-,N,N-dimethyl-, ethyl-, propyl- and butylurea was studied by fluorescence measurements. Data were analyzed on the assumption of a two-state approximation to obtain the apparent equilibrium constant,K and the apparent Gibbs free energy of transition G ⁰ . It has been observed that alkylsubstitution of urea significantly lowers the denaturant concentration needed to denature-ctg A at 25°C. Denaturation was accompanied by the red shift of emission maxima, the increase of the half-width of the fluorescence spectra, the increase of the fluorescence intensity, and the decrease of the fluorescence polarization. The differences of these fluorescence parameters observed for-ctg A in alkylureas and urea can be ascribed to different unfolded states of the protein in different denaturant solutions. Minor differences in the extent of unfolding were confirmed by size-exclusion chromatography.     

Identification of a novel Reg family gene, Reg IIIdelta, and mapping of all three types of Reg family gene in a 75 kilobase mouse genomic region

Regenerating gene (Reg), first isolated from a regenerating islet cDNA library, encodes a secretory protein with a growth stimulating effect on pancreatic beta cells that ameliorates the diabetes of 90% depancreatized rats and non-obese diabetic mice. Reg and Reg-related genes have been revealed to constitute a multigene family, the Reg family, which consists of three subtypes (types I, II, III) based on the primary structures of the encoded proteins of the genes. We have isolated three types of mouse Reg family gene (Reg I, Reg II, Reg IIIalpha, Reg IIIbeta and Reg IIIgamma) [Unno et al. (1993) J. Biol. Chem. 268, 15974-15982; Narushima et al. (1997) Gene 185, 159-168]. In the present study, by Southern blot analysis of a mouse bacterial artificial chromosome clone containing the five Reg family genes in combination with PCR cloning of every interspace fragment between adjacent genes, the Reg family genes were mapped to a contiguous 75kb region of the mouse genome according to the following order: 5'-Reg IIIbeta-Reg IIIalpha-Reg II-Reg I-Reg IIIgamma-3'. In the process of ordering the genes, we sequenced the 6.8kb interspace fragment between Reg IIIbeta and Reg IIIalpha and encountered a novel type III Reg gene, Reg IIIdelta. This gene is divided into six exons spanning about 3kb, and encodes a 175 amino acid protein with 40-52% identity with the other five mouse Reg (regenerating gene product) proteins. Reg IIIdelta was expressed predominantly in exocrine pancreas, but not in normal islets, hyperplastic islets, intestine or colon, whereas both Reg I and Reg II were expressed in hyperplastic islets and Reg IIIalpha, Reg IIIbeta and Reg IIIgamma were expressed strongly in the intestinal tract. Possible roles of Reg IIIdelta and the widespread occurrence of the Reg IIIdelta gene in mammalian genomes are discussed.     

Morphological integration and ontogenetic niche shift: a study of crested newt limbs

This study deals with the ontogenetic and evolutionary aspects of integration patterns in the limbs of crested newt species, which, like most amphibians, have a biphasic life history with two morphologically distinct stages (larval vs. juvenile and adult) that occupy different environments (aquatic vs. terrestrial). We analyzed the structure and pattern of correlation between limb skeletal elements at three ontogenetic stages (larval, juvenile, and adult) of four closely related species that differ in their preferences of aquatic habitats (more terrestrial and more aquatic). We found dynamic changes in the pattern of morphological integration between successive ontogenetic stages, as well as changes over the course of crested newt phylogeny. Generally, equivalent ontogenetic stages of different species of crested newts show higher concordance in the correlation pattern than successive ontogenetic stages within species. Among species, two opposing correlation patterns were observed: in more terrestrial species, homologous limb elements are less correlated and within-limb elements are more correlated; in aquatic species, the reverse pattern occurs. These results indicate that the function seems to be the covariance-generating factor, which has shaped the patterns of morphological integration of crested newt limbs.     

A retinoic acid responsive Hoxa3 transgene expressed in embryonic pharyngeal endoderm, cardiac neural crest and a subdomain of the second heart field

A transgenic mouse line harbouring a β-galacdosidase reporter gene controlled by the proximal 2 kb promoter of Hoxa3 was previously generated to investigate the regulatory cues governing Hoxa3 expression in the mouse. Examination of transgenic embryos from embryonic day (E) 8.0 to E15.5 revealed regionally restricted reporter activity in the developing heart. Indeed, transgene expression specifically delineated cells from three distinct lineages: a subpopulation of the second heart field contributing to outflow tract myocardium, the cardiac neural crest cells and the pharyngeal endoderm. Manipulation of the Retinoic Acid (RA) signaling pathway showed that RA is required for correct expression of the transgene. Therefore, this transgenic line may serve as a cardiosensor line of particular interest for further analysis of outflow tract development.