Deletion of Cysteine Cathepsins B or L Yields Differential Impacts on Murine Skin Proteome and Degradome

Numerous studies highlight the fact that concerted proteolysis is essential for skin morphology and function. The cysteine protease cathepsin L (Ctsl) has been implicated in epidermal proliferation and desquamation, as well as in hair cycle regulation. In stark contrast, mice deficient in cathepsin B (Ctsb) do not display an overt skin phenotype. To understand the systematic consequences of deleting Ctsb or Ctsl, we determined the protein abundances of >1300 proteins and proteolytic cleavage events in skin samples of wild-type, Ctsb^−/−, and Ctsl^−/− mice via mass-spectrometry-based proteomics. Both protease deficiencies revealed distinct quantitative changes in proteome composition. Ctsl^−/− skin revealed increased levels of the cysteine protease inhibitors cystatin B and cystatin M/E, increased cathepsin D, and an accumulation of the extracellular glycoprotein periostin. Immunohistochemistry located periostin predominantly in the hypodermal connective tissue of Ctsl^−/− skin. The proteomic identification of proteolytic cleavage sites within skin proteins revealed numerous processing sites that are underrepresented in Ctsl^−/− or Ctsb^−/− samples. Notably, few of the affected cleavage sites shared the canonical Ctsl or Ctsb specificity, providing further evidence of a complex proteolytic network in the skin. Novel processing sites in proteins such as dermokine and Notch-1 were detected. Simultaneous analysis of acetylated protein N termini showed prototypical mammalian N-alpha acetylation. These results illustrate an influence of both Ctsb and Ctsl on the murine skin proteome and degradome, with the phenotypic consequences of the absence of either protease differing considerably.Cathepsins B and L are ubiquitously expressed papain-like cysteine proteases belonging to the C1a papain family (clan CA), with 11 members in humans (1) and 18 members in mice (2). Most cysteine cathepsins like cathepsin L are endopeptidases, whereas cathepsin B shows both endopeptidase and carboxydipeptidase activity (3). Mainly localized in the endosomal/lysosomal compartment, cathepsins have traditionally been thought to play important roles in lysosomal protein turnover. Additional specific functions have been postulated that link cathepsins to different physiological and pathological processes.Studies using cathepsin L (Ctsl)-gene-deficient mice¹ revealed an important role of Ctsl in cardiac homeostasis (4–6) and a contribution of Ctsl to MHC II-mediated antigen presentation (7, 8) and prohormone processing (9, 10). In a mouse model of pancreatic neuroendocrine cancer, Ctsl promoted tumor growth and invasiveness (11, 12). In stark contrast, Ctsl was found to attenuate tumor progression in mouse models of skin cancer, highlighting the context-specific function of this protease (13, 14).The most prominent phenotype of Ctsl-deficient mice is periodic hair loss together with epidermal hyperplasia, acanthosis, and hyperkeratosis (15). These alterations in skin morphology are assumed to be keratinocyte specific, as controlled re-expression of Ctsl under a keratin 14 promoter results in inconspicuous epidermal proliferation (16). The hair loss phenotype is caused by increased apoptosis and proliferation of hair follicle keratinocytes during the regression phase (catagen) of the hair follicle (17).Cathepsin B (Ctsb)-gene-deficient mice do not display a spontaneous phenotype (18, 19), but if pathologically challenged these mice are less susceptible to disease in pancreatitis (20) and are less affected by TNFα-induced hepatocyte apoptosis (21). In tumor models of metastasizing breast cancer and pancreatic neuroendocrine neoplasias, mice deficient in Ctsb showed delayed cancer progression and reduced invasion (11, 22, 23). As good corroboration, the overexpression of Ctsb in the mouse mammary tumor virus–polyoma middle T breast cancer model promotes a more severe tumor phenotype (24).In contrast to single-gene-deficient mice, mice with a double deficiency in both Ctsb and Ctsl die 4 weeks after birth as a result of pronounced lysosomal storage disease leading to neuron death in the cerebral cortex and the degeneration of cerebellar Purkinje cells (25). Because single-gene-deficient mice do not show autophagolysosomal and lysosomal accumulations in neurons, mutual compensation between Ctsb and Ctsl in vivo has been suggested (26).The present proteomic study focuses on the molecular roles of Ctsb and Ctsl in skin homeostasis. We applied a 2-fold strategy consisting firstly of a gel-free quantitative proteomic approach (27, 28) to investigate protein alterations. Secondly, we performed terminal amine isotopic labeling of substrates (TAILS) (29) to determine changes in the skin proteome cleavage pattern and to identify Ctsb- and Ctsl-dependent cleavage events. Selected proteomic data were corroborated by means of immunodetection and immunohistochemistry. Selected mRNA levels were determined via qPCR in order to discriminate expression changes from posttranslational alterations. We identified specific proteomic and degradomic effects stemming from the deletion of either Ctsb or Ctsl. Our findings highlight the pivotal function of these proteases in maintaining proteome homeostasis and in balancing the proteolytic network. This is one of the first studies investigating how the deletion of individual proteases affects proteolytic processing in vivo.     

The ROCO Kinase QkgA Is Necessary for Proliferation Inhibition by Autocrine Signals in Dictyostelium discoideum

AprA and CfaD are secreted proteins that function as autocrine signals to inhibit cell proliferation in Dictyostelium discoideum. Cells lacking AprA or CfaD proliferate rapidly, and adding AprA or CfaD to cells slows proliferation. Cells lacking the ROCO kinase QkgA proliferate rapidly, with a doubling time 83% of that of the wild type, and overexpression of a QkgA-green fluorescent protein (GFP) fusion protein slows cell proliferation. We found that qkgA⁻ cells accumulate normal levels of extracellular AprA and CfaD. Exogenous AprA or CfaD does not slow the proliferation of cells lacking qkgA, and expression of QkgA-GFP in qkgA⁻ cells rescues this insensitivity. Like cells lacking AprA or CfaD, cells lacking QkgA tend to be multinucleate, accumulate nuclei rapidly, and show a mass and protein accumulation per nucleus like those of the wild type, suggesting that QkgA negatively regulates proliferation but not growth. Despite their rapid proliferation, cells lacking AprA, CfaD, or QkgA expand as a colony on bacteria less rapidly than the wild type. Unlike AprA and CfaD, QkgA does not affect spore viability following multicellular development. Together, these results indicate that QkgA is necessary for proliferation inhibition by AprA and CfaD, that QkgA mediates some but not all of the effects of AprA and CfaD, and that QkgA may function downstream of these proteins in a signal transduction pathway regulating proliferation.Physiological processes that define and maintain the sizes of tissues are poorly understood. Although a number of characterized gene products negatively regulate the sizes of tissues (21, 23), the mechanism by which the activities of such gene products are controlled is unclear. One potential mechanism for tissue size regulation consists of tissue-specific autocrine signals that inhibit proliferation in a concentration-dependent manner (18). Since the extracellular concentration of such factors increases as a function of cell density and/or cell number, the proliferation-inhibiting function of these factors can limit tissue size. Considerable evidence for such factors has been reported. For instance, full hepatectomy in one of two rats with conjoined circulatory systems stimulated proliferation in the intact liver of the conjoined rat, suggesting the existence of a systemic factor produced by the liver that inhibits the proliferation of hepatocytes (16). However, only a small number of factors with analogous functional roles, such as myostatin, which regulates skeletal muscle size (30), and Gdf11, which negatively regulates neurogenesis in the olfactory epithelium (38), have been identified. The mechanisms by which such signals inhibit proliferation are not well understood. As such autocrine signals may serve to limit tumor growth (14, 20), elucidation of the identities of such factors and their associated signal transduction pathways may yield novel cancer therapies.We have identified two such autocrine proliferation-repressing signals in the social amoeba Dictyostelium discoideum, a genetically and biochemically tractable model organism. The proteins AprA and CfaD are secreted by Dictyostelium and inhibit the proliferation of Dictyostelium cells in a concentration-dependent manner (4, 12). Cells in which the genes encoding either AprA or CfaD have been disrupted by homologous recombination proliferate rapidly, and cells overexpressing AprA or CfaD proliferate slowly (4, 11). Adding recombinant AprA (rAprA) or recombinant CfaD (rCfaD) to cells slows proliferation, demonstrating that these proteins function as extracellular signals (4, 12). In addition to exhibiting rapid proliferation, aprA⁻ and cfaD⁻ cells exhibit a multinucleate phenotype, strongly suggesting that AprA and CfaD are negative regulators of mitosis (4, 11). aprA⁻ cells are insensitive to the proliferation-inhibiting effects of CfaD (12), and cfaD⁻ cells are insensitive to AprA (4), indicating the necessity of both genes for proliferation inhibition and suggesting a common proliferation-inhibiting mechanism. The G protein complex subunits Gα8, Gα9, and Gβ are necessary for proliferation inhibition by AprA, and the addition of recombinant AprA to purified cell membranes increases binding of GTP to wild-type and gα9⁻ cell membranes but not gα8⁻ or gβ⁻ membranes, indicating that AprA activates a proliferation-inhibiting signal transduction pathway of which Gα8 and Gβ are components (5). The signal transduction pathway downstream of Gα8 and the associated mechanism of proliferation inhibition are unknown.Although the selective forces that have maintained functional autocrine proliferation inhibitors in proliferating Dictyostelium cells are unclear, AprA and CfaD may provide an advantage during the multicellular portion of the Dictyostelium life cycle. Upon starvation, Dictyostelium cells secrete pulses of the chemoattractant cyclic AMP, leading to cells streaming toward aggregation centers (15, 27). This process causes the formation of multicellular groups regulated in size by a secreted protein complex that stimulates stream breakup (9, 10). These groups develop into multicellular fruiting body structures composed of a mass of stress-resistant spores supported by an approximately 1-mm-high stalk (24). While the stalk cells inevitably die in an act of apparent altruism (31), the presence of nutrients stimulates spore germination and a continuation of proliferation (13). Following development, aprA⁻ and cfaD⁻ cells form fewer viable spores than the wild type (4, 11), suggesting that AprA and CfaD increase the fitness of Dictyostelium during development.Like aprA⁻ and cfaD⁻ cells, Dictyostelium cells lacking the ROCO family kinase QkgA have an abnormally rapid proliferation (1). The ROCO protein family is widely conserved and is defined by the presence of a Ras of complex protein (Roc) domain followed by a C terminus of Roc (Cor) domain, which mediates homodimerization (19). In eukaryotes, these domains are commonly followed C terminally by a kinase domain with similarity to the tyrosine kinase-like (TKL) group of kinases (3, 26, 29). In Dictyostelium, other ROCO proteins function in cyclic GMP signaling (8, 35) and cytokinesis (2), and a total of 11 predicted ROCO proteins are present in the genome, 10 of which, including QkgA, encode kinase domains predicted to be catalytically active (17). The human genome encodes two ROCO kinases, which are expressed in a wide range of tissues (25, 40). Little is known regarding the physiological functions of these proteins, although the ROCO protein LRRK2 is implicated in a dominantly inherited form of Parkinson''s disease (40) and negatively regulates neurite growth in rat cortical cultures (28).In this report, we show that, like aprA⁻ and cfaD⁻ cells, qkgA⁻ cells proliferate to a higher cell density than the wild type and tend to be multinucleate. Additionally, we show that qkgA⁻ cells are insensitive to exogenous AprA and CfaD, indicating that QkgA is required for AprA and CfaD signal transduction.