Laura Oliva
Vita-Salute San Raffaele University
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Publication
Featured researches published by Laura Oliva.
Nature Immunology | 2013
Niccolò Pengo; Maria Scolari; Laura Oliva; Enrico Milan; Federica Mainoldi; Andrea Raimondi; Claudio Fagioli; Arianna Merlini; Elisabetta Mariani; Elena Pasqualetto; Ugo Orfanelli; Maurilio Ponzoni; Roberto Sitia; Stefano Casola; Simone Cenci
The role of autophagy in plasma cells is unknown. Here we found notable autophagic activity in both differentiating and long-lived plasma cells and investigated its function through the use of mice with conditional deficiency in the essential autophagic molecule Atg5 in B cells. Atg5−/− differentiating plasma cells had a larger endoplasmic reticulum (ER) and more ER stress signaling than did their wild-type counterparts, which led to higher expression of the transcriptional repressor Blimp-1 and immunoglobulins and more antibody secretion. The enhanced immunoglobulin synthesis was associated with less intracellular ATP and more death of mutant plasma cells, which identified an unsuspected autophagy-dependent cytoprotective trade-off between immunoglobulin synthesis and viability. In vivo, mice with conditional deficiency in Atg5 in B cells had defective antibody responses, complete selection in the bone marrow for plasma cells that escaped Atg5 deletion and fewer antigen-specific long-lived bone marrow plasma cells than did wild-type mice, despite having normal germinal center responses. Thus, autophagy is specifically required for plasma cell homeostasis and long-lived humoral immunity.
Blood | 2009
Giada Bianchi; Laura Oliva; Paolo Cascio; Niccolò Pengo; Francesca Fontana; Fulvia Cerruti; Andrea Orsi; Elena Pasqualetto; Alexandre Mezghrani; Valeria Calbi; Giovanni Palladini; Nicola Giuliani; Kenneth C. Anderson; Roberto Sitia; Simone Cenci
Proteasome inhibitors (PIs) are effective against multiple myeloma (MM), but the mechanisms of action and bases of individual susceptibility remain unclear. Recent work linked PI sensitivity to protein synthesis and proteasome activity, raising the question whether different levels of proteasome expression and workload underlie PI sensitivity in MM cells (MMCs). Exploiting human MM lines characterized by differential PI sensitivity, we report that highly sensitive MMCs express lower proteasome levels and higher proteasomal workload than relatively PI-resistant MMCs, resulting in the accumulation of polyubiquitinated proteins at the expense of free ubiquitin (proteasome stress). Manipulating proteasome expression or workload alters apoptotic sensitivity to PI, demonstrating a cause-effect relationship between proteasome stress and apoptotic responses in MMCs. Intracellular immunostaining in primary, patient-derived MMCs reveals that polyubiquitinated proteins hallmark neoplastic plasma cells, in positive correlation with immunoglobulin (Ig) content, both intra- and interpatient. Moreover, overall proteasome activity of primary MMCs inversely correlates with apoptotic sensitivity to PI. Altogether, our data indicate that the balance between proteasome workload and degradative capacity represents a critical determinant of apoptotic sensitivity of MMCs to PI, potentially providing a framework for identifying indicators of responsiveness and designing novel combination therapies.
The EMBO Journal | 2006
Simone Cenci; Alexandre Mezghrani; Paolo Cascio; Giada Bianchi; Fulvia Cerruti; Anna M. Fra; Hugues Lelouard; Silvia Masciarelli; Laura Mattioli; Laura Oliva; Andrea Orsi; Elena Pasqualetto; Philippe Pierre; Elena Ruffato; Luigina Tagliavacca; Roberto Sitia
After few days of intense immunoglobulin (Ig) secretion, most plasma cells undergo apoptosis, thus ending the humoral immune response. We asked whether intrinsic factors link plasma cell lifespan to Ig secretion. Here we show that in the late phases of plasmacytic differentiation, when antibody production becomes maximal, proteasomal activity decreases. The excessive load for the reduced proteolytic capacity correlates with accumulation of polyubiquitinated proteins, stabilization of endogenous proteasomal substrates (including Xbp1s, IκBα, and Bax), onset of apoptosis, and sensitization to proteasome inhibitors (PI). These events can be reproduced by expressing Ig‐μ chain in nonlymphoid cells. Our results suggest that a developmental program links plasma cell death to protein production, and help explaining the peculiar sensitivity of normal and malignant plasma cells to PI.
Journal of Neuroimmunology | 2003
Paolo Confalonieri; Laura Oliva; Francesca Andreetta; Rossella Lorenzoni; Patrizia Dassi; Elisabetta Mariani; Lucia Morandi; Marina Mora; Ferdinando Cornelio; Renato Mantegazza
Muscle inflammation is characteristic of inflammatory myopathies but also occurs in muscular dystrophy with lack of the sarcolemmal protein dysferlin. We quantified inflammatory cells and major histocompatibility complex (MHC) expression in muscle from 10 patients with dysferlinopathy. Infiltrating cells were always present although numbers varied considerably; macrophages were more common than T cells, T cytotoxicity was absent, and MHC class I was overexpressed on muscle fibers. These findings differ from polymyositis (PM) but are closely similar to those in SJL/J mice (which lack dysferlin) and emphasize the relationship between absence of dysferlin and immune system abnormalities in muscle.
Journal of Neuroimmunology | 2006
Francesca Andreetta; Pia Bernasconi; Fulvio Baggi; Paolo Ferro; Laura Oliva; Elisa Arnoldi; Ferdinando Cornelio; Renato Mantegazza; Paolo Confalonieri
Irreversible connective tissue proliferation in muscle is a pathological hallmark of Duchenne muscular dystrophy (DMD), a genetic degenerative muscle disease due to lack of the sarcolemmal protein dystrophin. Focal release of transforming growth factor-beta1 (TGF-beta1) is involved in fibrosis development. Murine muscular dystrophy (mdx) is genetically homologous to DMD and histopathological alterations comparable to those in DMD muscles occur in diaphragm of older mdx mice. To investigate the early development of fibrosis and TGF-beta1 involvement, we assessed diaphragms in 6-36-week-old mdx and C57/BL6 (control) mice for fibrosis, and used real-time PCR and ELISA to determine TGF-beta1 expression. Significantly greater fibrosis and TGF-beta1 expression were found in mdx from the 6th week. Mice treated with neutralizing antibody against TGF-beta1 had lower levels of TGF-beta1 protein, reduced fibrosis, unchanged muscles fiber degeneration/regeneration, but increased inflammatory cells (CD4+lymphocytes). These data demonstrate early and progressive fibrosis in mdx diaphragm accompanied by TGF-beta1 upregulation. Reduction of TGF-beta1 appears promising as a therapeutic approach to muscle fibrosis, but further studies are required to evaluate long term effects of TGF-beta1 immunomodulation on the immune system.
European Journal of Immunology | 2008
Paolo Cascio; Laura Oliva; Fulvia Cerruti; Elisabetta Mariani; Elena Pasqualetto; Simone Cenci; Roberto Sitia
Upon encounter with Ag, B lymphocytes undergo terminal differentiation into plasma cells, highly specialized Ab secretors that mediate humoral immune responses. Profound changes adapt cellular morphology and proteome to the new secretory functions. Although a massive secretory activity is expected to require an efficient ubiquitin‐proteasome degradation system, recent in vitro studies have surprisingly revealed that the proteasome function sharply decreases during plasma cell development, thereby limiting the proteolytic capacity. We challenged this paradigm in mouse models of B cell activation, and observed that following polyclonal activation, proteasome activity decreases more than previously reported in vitro. This decrease is linked to enhanced apoptosis after treatment with the potent anti‐myeloma proteasome inhibitor PS‐341. Accordingly, in vivo treatment with PS‐341 decreases Ab titres in T‐dependent and ‐independent mouse immunization models. This study provides the rationale for limiting the activity of Ab‐secreting cells in vivo by impacting proteasome function.
Journal of Leukocyte Biology | 2012
Simone Cenci; Laura Oliva; Fulvia Cerruti; Enrico Milan; Giada Bianchi; Mary Raule; Alexandre Mezghrani; Elena Pasqualetto; Roberto Sitia; Paolo Cascio
A previously unsuspected, considerable proportion of newly synthesized polypeptides are hydrolyzed rapidly by proteasomes, possibly competing with endogenous substrates and altering proteostasis. In view of the anti‐cancer effects of PIs, we set out to achieve a quantitative assessment of proteasome workload in cells hallmarked by different PI sensitivity, namely, a panel of MM cells, and in a dynamic model of plasma cell differentiation, a process that confers exquisite PI sensitivity. Our results suggest that protein synthesis is a key determinant of proteasomal proteolytic burden and PI sensitivity. In different MM cells and in differentiating plasma cells, the average proteolytic work accomplished per proteasome ranges over different orders of magnitude, an unexpected degree of variability, with increased workload invariably associated to increased PI sensitivity. The unfavorable load‐versus‐capacity balance found in highly PI‐sensitive MM lines is accounted for by a decreased total number of immunoproteasomes/cell coupled to enhanced generation of RDPs. Moreover, indicative of cause‐effect relationships, attenuating general protein synthesis by the otherwise toxic agent CHX reduces PI sensitivity in activated B and in MM cells. Our data support the view that in plasma cells protein synthesis contributes to determine PI sensitivity by saturating the proteasomal degradative capacity. Quantitating protein synthesis and proteasome workload may thus prove crucial to design novel negative proteostasis regulators against cancer.
Autophagy | 2015
Enrico Milan; Tommaso Perini; Massimo Resnati; Ugo Orfanelli; Laura Oliva; Andrea Raimondi; Paolo Cascio; Angela Bachi; Magda Marcatti; Fabio Ciceri; Simone Cenci
Multiple myeloma (MM) is the paradigmatic proteasome inhibitor (PI) responsive cancer, but many patients fail to respond. An attractive target to enhance sensitivity is (macro)autophagy, recently found essential to bone marrow plasma cells, the normal counterpart of MM. Here, integrating proteomics with hypothesis-driven strategies, we identified the autophagic cargo receptor and adapter protein, SQSTM1/p62 as an essential component of an autophagic reserve that not only synergizes with the proteasome to maintain proteostasis, but also mediates a plastic adaptive response to PIs, and faithfully reports on inherent PI sensitivity. Lentiviral engineering revealed that SQSTM1 is essential for MM cell survival and affords specific PI protection. Under basal conditions, SQSTM1-dependent autophagy alleviates the degradative burden on the proteasome by constitutively disposing of substantial amounts of ubiquitinated proteins. Indeed, its inhibition or stimulation greatly sensitized to, or protected from, PI-induced protein aggregation and cell death. Moreover, under proteasome stress, myeloma cells selectively enhanced SQSTM1 de novo expression and reset its vast endogenous interactome, diverting SQSTM1 from signaling partners to maximize its association with ubiquitinated proteins. Saturation of such autophagic reserve, as indicated by intracellular accumulation of undigested SQSTM1-positive aggregates, specifically discriminated patient-derived myelomas inherently susceptible to PIs from primarily resistant ones. These aggregates correlated with accumulation of the endoplasmic reticulum, which comparative proteomics identified as the main cell compartment targeted by autophagy in MM. Altogether, the data integrate autophagy into our previously established proteasome load-versus-capacity model, and reveal SQSTM1 aggregation as a faithful marker of defective proteostasis, defining a novel prognostic and therapeutic framework for MM.
Blood | 2017
Laura Oliva; Ugo Orfanelli; Massimo Resnati; Andrea Raimondi; Andrea Orsi; Enrico Milan; Giovanni Palladini; Paolo Milani; Fulvia Cerruti; Paolo Cascio; Simona Casarini; Paola Rognoni; Thierry Touvier; Magda Marcatti; Fabio Ciceri; Silvia Mangiacavalli; Alessandro Corso; Giampaolo Merlini; Simone Cenci
Systemic light chain (AL) amyloidosis is caused by the clonal production of an unstable immunoglobulin light chain (LC), which affects organ function systemically. Although pathogenic LCs have been characterized biochemically, little is known about the biology of amyloidogenic plasma cells (PCs). Intrigued by the unique response rates of AL amyloidosis patients to the first-in-class proteasome inhibitor (PI) bortezomib, we purified and investigated patient-derived AL PCs, in comparison with primary multiple myeloma (MM) PCs, the prototypical PI-responsive cells. Functional, biochemical, and morphological characterization revealed an unprecedented intrinsic sensitivity of AL PCs to PIs, even higher than that of MM PCs, associated with distinctive organellar features and expression patterns indicative of cellular stress. These consisted of expanded endoplasmic reticulum (ER), perinuclear mitochondria, and a higher abundance of stress-related transcripts, and were consistent with reduced autophagic control of organelle homeostasis. To test whether PI sensitivity stems from AL LC production, we engineered PC lines that can be induced to express amyloidogenic and nonamyloidogenic LCs, and found that AL LC expression alters cell growth and proteostasis and confers PI sensitivity. Our study discloses amyloidogenic LC production as an intrinsic PC stressor, and identifies stress-responsive pathways as novel potential therapeutic targets. Moreover, we contribute a cellular disease model to dissect the biology of AL PCs.
Frontiers in Immunology | 2014
Laura Oliva; Simone Cenci
Plasma cells (PCs) are the effectors responsible for antibody (Ab)-mediated immunity. They differentiate from B lymphocytes through a complete remodeling of their original structure and function. Stress is a constitutive element of PC differentiation. Macroautophagy, conventionally referred to as autophagy, is a conserved lysosomal recycling strategy that integrates cellular metabolism and enables adaptation to stress. In metazoa, autophagy plays diverse roles in cell differentiation. Recently, a number of autophagic functions have been recognized in innate and adaptive immunity, including clearance of intracellular pathogens, inflammasome regulation, lymphocyte ontogenesis, and antigen presentation. We identified a previously unrecognized role played by autophagy in PC differentiation and activity. Following B cell activation, autophagy moderates the expression of the transcriptional repressor Blimp-1 and immunoglobulins through a selective negative control exerted on the size of the endoplasmic reticulum and its stress signaling response, including the essential PC transcription factor, XBP-1. This containment of PC differentiation and function, i.e., Ab production, is essential to optimize energy metabolism and viability. As a result, autophagy sustains Ab responses in vivo. Moreover, autophagy is an essential intrinsic determinant of long-lived PCs in their as yet poorly understood bone marrow niche. In this essay, we discuss these findings in the context of the established biological functions of autophagy, and their manifold implications for adaptive immunity and PC diseases, in primis multiple myeloma.