Mammalian Atg9 (mAtg9) is a multispanning membrane protein that resides in a novel compartment. mAtg9 interacts dynamically with phagophores and forming autophagosomes. It is proposed that mAtg9 function is required to initiate autophagosome formation and increase the number of autophagosomes.
IntroductionMultiple myeloma (MM) is a frequent and still incurable plasma cell malignancy, causing 2% of all cancer deaths. In recent years, treatment of MM has improved remarkably. For example, the proteasome inhibitor (PI) bortezomib (PS-341) proved effective even in the context of heavily pretreated, relapsed, and refractory MM, 1-3 although more than 50% of patients fail to respond to second-line treatment. 4 The molecular bases of different individual responsiveness to bortezomib remain unclear. Age (Ͻ 65 years) and extent of bone marrow plasma cell infiltration (Ͻ 50%) are the conventional factors for successful treatment identified so far. [5][6][7] Identifying the molecular bases underlying PI sensitivity would provide the framework for their improved clinical application.Bortezomib targets the proteasome, a 2.4-MDa multicatalytic protease complex ubiquitously expressed in eukaryotic cells. 1,8 Crucial for degrading proteins involved in cell cycle, angiogenesis, adhesion, cytokine production, and apoptosis, 3,9,10 proteasome inhibition can affect tumor cell growth via direct and indirect mechanisms (eg, by blocking interactions with endothelial and bone cells). 8,11 Proteasomes also dismantle damaged and misfolded/unfolded proteins, which are potentially harmful for the cell. 8 As a result, proteasome impairment causes buildup of polyubiquitinated proteins and eventual cell death. 3 Proteasomes also degrade a significant proportion of newly synthesized proteins in mammalian cells (rapidly degraded polypeptides [RDPs]). 12 Thus, increased protein synthesis or other metabolic unbalances could increase proteasome workload.We recently showed that plasma cell differentiation in vitro, ex vivo, and in vivo entails a dramatic decrease in proteasome expression and activity, correlating with increased sensitivity to PIs. 13,14 Indeed, PIs reduce antibody (Ab) responses in vivo. 14,15 Moreover, inducible expression of orphan Ig-chains sensitizes nonlymphoid tumor cells to PI-induced toxicity. 13 In MM cells (MMCs), the levels of both Ig synthesis and retention correlate with apoptotic sensitivity to PIs, and manipulating Ig synthesis alters sensitivity. 16,17 Altogether, these data suggest that the exquisite sensitivity of certain MMCs to PIs could stem from decreased proteasomal capacity, increased proteasomal workload, or both (ie, an adverse load-versus-capacity ratio).In this study, we exploited MM lines with differential apoptotic sensitivity to PIs to address if proteasome expression and degradative workload vary among different clones, and defined their role in The online version of this article contains a data supplement.The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked ''advertisement'' in accordance with 18 USC section 1734. For personal use only. on May 9, 2018. by guest www.bloodjournal.org From determining apoptotic sensitivity to PIs. Moreover, using primary patient-derived MMCs, we revealed ...
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, IjBa, and Bax), onset of apoptosis, and sensitization to proteasome inhibitors (PI). These events can be reproduced by expressing Ig-l 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.
Insufficient folding capacity of the endoplasmic reticulum (ER) activates the unfolded protein response (UPR) to restore homeostasis. Yet, how the UPR achieves ER homeostatic readjustment is poorly investigated, as in most studies the ER stress that is elicited cannot be overcome. Here we show that a proteostatic insult, provoked by persistent expression of the secretory heavy chain of immunoglobulin M (µs), is well-tolerated in HeLa cells. Upon µs expression, its levels temporarily eclipse those of the ER chaperone BiP, leading to acute, full-geared UPR activation. Once BiP is in excess again, the UPR transitions to chronic, submaximal activation, indicating that the UPR senses ER stress in a ratiometric fashion. In this process, the ER expands about three-fold and becomes dominated by BiP. As the UPR is essential for successful ER homeostatic readjustment in the HeLa-µs model, it provides an ideal system for dissecting the intricacies of how the UPR evaluates and alleviates ER stress.
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