These findings can explain lifelong food allergies observed in human subjects as the consequence of allergen exposures that recurrently activate memory B cells and identify these as a therapeutic target with disease-transforming potential.
Cancer research relies heavily on murine models for evaluating the anti-tumour efficacy of therapies. Here we show that the sensitivity of several pancreatic tumour models to cytotoxic therapies is significantly increased when mice are housed at a thermoneutral ambient temperature of 30 °C compared with the standard temperature of 22 °C. Further, we find that baseline levels of norepinephrine as well as the levels of several anti-apoptotic molecules are elevated in tumours from mice housed at 22 °C. The sensitivity of tumours to cytotoxic therapies is also enhanced by administering a β-adrenergic receptor antagonist to mice housed at 22 °C. These data demonstrate that standard housing causes a degree of cold stress sufficient to impact the signalling pathways related to tumour-cell survival and affect the outcome of pre-clinical experiments. Furthermore, these data highlight the significant role of host physiological factors in regulating the sensitivity of tumours to therapy.
Durable humoral immunity is dependent upon the generation of antigen-specific antibody titers, produced by non-proliferating bone marrow resident long-lived plasma cells (LLPC). Longevity is the hallmark of LLPC, but why and how they survive and function for years after antigen exposure is only beginning to be understood. LLPC are not intrinsically long-lived; they require continuous signals from the LLPC niche to survive. Signals unique to LLPC survival (vs. PC survival in general) most notably include those that upregulate the anti-apoptotic factor Mcl-1 and activation of the CD28 receptor expressed on LLPC. Other potential factors include expression of BCMA, upregulation of the transcription factor ZBTB20, and upregulation of the enzyme ENPP1. Metabolic fitness is another key component of LLPC longevity, facilitating the diversion of glucose to generate pyruvate during times of stress to facilitate long term survival. A third major component of LLPC survival is the microenvironment/LLPC niche itself. Cellular partners such as stromal cells, dendritic cells, and T regulatory cells establish a niche for LLPC and drive survival signaling by expressing ligands such as CD80/CD86 for CD28 and producing soluble and stromal factors that contribute to LLPC longevity. These findings have led to the current paradigm wherein both intrinsic and extrinsic mechanisms are required for the survival of LLPC. Here we outline this diverse network of signals and highlight the mechanisms thought to regulate and promote the survival of LLPC. Understanding this network of signals has direct implications in increasing our basic understanding of plasma cell biology, but also in vaccine and therapeutic drug development to address the pathologies that can arise from this subset.
• CD28 delivers a pro-survival signal to MM cells via regulation of PI3K/Akt, FoxO3a, and Bim.• Blockade of CD28:CD80/ CD86 in vivo resensitizes MM cells to chemotherapy and significantly reduces tumor burden.Chemotherapeutic resistance remains a significant hurdle in the treatment of multiple myeloma (MM) and is significantly mediated by interactions between MM cells and stromal cells of the bone marrow microenvironment. Despite the importance of these interactions, the specific molecules and downstream signaling components involved remain incompletely understood. We have previously shown that the prototypic T-cell costimulatory receptor CD28, which is also expressed on MM cells, is a key mediator of MM survival and apoptotic resistance. Crosslinking CD28 by agonistic antibodies or myeloid dendritic cells (DC; these express the CD28 ligands CD80/CD86) prevents apoptosis caused by chemotherapy or serum withdrawal. We now report that CD28 pro-survival signaling is dependent upon downstream activation of phosphatidyl-inositol 3-kinase/Akt, inactivation of the transcription factor FoxO3a, and decreased expression of the pro-apoptotic molecule Bim. Conversely, blocking the CD28-CD80/CD86 interaction between MM cells and DC in vitro abrogates the DC's ability to protect MM cells against chemotherapyinduced death. Consistent with these observations, in vivo blockade of CD28-CD80/CD86 in the Vk*MYC murine myeloma model sensitizes MM cells to chemotherapy and significantly reduces tumor burden. Taken together, our findings suggest that CD28 is an important mediator of MM survival during stress and can be targeted to overcome chemotherapy resistance. (Blood. 2014;123(24): 3770-3779) IntroductionMultiple myeloma (MM), the bone marrow (BM)-resident plasma cell (PC) neoplasm, is the second most common hematologic malignancy after non-Hodgkin lymphoma.1 Although new therapies have improved survival, MM remains almost uniformly fatal and only curable in a small fraction of patients. 2,3 Initially, patients are responsive to therapy and experience remission; however, relapses result in MM cells that are progressively resistant to therapy. 3,4 Thus, understanding and overcoming resistance mechanisms may lead to development of new therapeutic approaches.Chemotherapies such as the DNA alkylator melphalan and the proteasome inhibitor bortezomib were developed because of their direct apoptotic effects on MM cells. 5,6 However, these agents, thalidomide, and thalidomide derivatives also target the BM microenvironment, pointing to the key role that stroma plays in myeloma survival.6-8 Moreover, primary MM culture in vitro requires stroma, indicating that the BM niche provides essential pro-survival signals.9-11 Thus, identifying key interactions between MM and the microenvironment is essential for understanding and overcoming therapeutic resistance mechanisms.Broadly, MM-stromal interactions fall into 2 categories. The first consists of soluble pro-survival factors induced from stromal niche cells upon MM interaction, and include int...
It is generally accepted that intracellular oxidative stress induced by proteasome inhibitors is a byproduct of endoplasmic reticulum (ER) stress. Here, we report a mechanism underlying the ability of proteasome inhibitors bortezomib (BTZ) and carfilzomib (CFZ) to directly induce oxidative and ER stresses in multiple myeloma (MM) cells via transcriptional repression of a gene encoding mitochondrial thioredoxin reductase (TXNRD2). TXNRD2 is critical for maintenance of intracellular red-ox status and detoxification of reactive oxygen species. Depletion of TXNRD2 to the levels detected in BTZ- or CFZ-treated cells causes oxidative stress, ER stress and death similar to those induced by proteasome inhibitors. Reciprocally, restoration of near-wildtype TXNRD2 amounts in MM cells treated with proteasome inhibitors reduces oxidative stress, ER stress and cell death by ~46%, ~35% and ~50%, respectively, compared to cells with unrestored TXNRD2 levels. Moreover, cells from three MM cell lines selected for resistance to BTZ demonstrate elevated levels of TXNRD2, indirectly confirming its functional role in BTZ resistance. Accordingly, ectopic expression of TXNRD2 in MM cell xenografts in immunocompromised mice blunts therapeutic effects of BTZ. Our data identify TXNRD2 as a potentially clinically relevant target, inhibition of which is critical for proteasome inhibitor-dependent cytotoxicity, oxidative stress, and ER stress.
In health, long-lived plasma cells (LLPC) are essential for durable protective humoral immunity, and conversely in disease are a major source of pathogenic antibodies in autoimmunity, graft rejection and allergy. However, the molecular basis for their longevity is largely unknown. We have recently found that CD28 signaling in plasma cells (PC) is essential for sustaining antibody titers, by supporting the survival of LLPC but not short-lived PC (SLPC). We now find that unlike SLPC, CD28 activation in LLPC induces pro-survival downstream Vav signaling. Knock-in mice with CD28 cytoplasmic tail mutations that abrogate Vav signaling (CD28-AYAA) had significantly fewer LLPC but unaffected SLPC numbers, while mice with mutations that abrogate PI3K signaling (CD28-Y170F) were indistinguishable from WT controls. This was consistent with the loss of CD28’s pro-survival effect in LLPC from CD28-AYAA, but not CD28-Y170F, mice. Furthermore, the CD28 Vav motif in the B lineage was essential for the long-term maintenance of antigen-specific LLPC populations and antibody titers in vivo. Signaling downstream of the CD28 Vav motif induced previously undescribed transcriptional regulation of BLIMP-1, a key mediator of PC differentiation and maintenance. These findings suggest CD28 signaling in LLPC modulates the central BLIMP-1 transcriptional nexus involved in long-term survival and function.
SUMMARY Durable humoral immunity against epidemic infectious disease requires the survival of long-lived plasma cells (LLPCs). LLPC longevity is dependent on metabolic programs distinct from short-lived plasma cells (SLPCs); however, the mechanistic basis for this difference is unclear. We have previously shown that CD28, the prototypic T cell costimulatory receptor, is expressed on both LLPCs and SLPCs but is essential only for LLPC survival. Here we show that CD28 transduces pro-survival signaling specifically in LLPCs through differential SLP76 expression. CD28 signaling in LLPCs increased glucose uptake, mitochondrial mass/respiration, and reactive oxygen species (ROS) production. Unexpectedly, CD28-mediated regulation of mitochondrial respiration, NF-κB activation, and survival was ROS dependent. IRF4, a target of NF-κB, was upregulated by CD28 activation in LLPCs and decreased IRF4 levels correlated with decreased glucose uptake, mitochondrial mass, ROS, and CD28-mediated survival. Altogether, these data demonstrate that CD28 signaling induces a ROS-dependent metabolic program required for LLPC survival.
Vaccines that generate Ag-specific CD8+ T-cell responses of appropriate quality, magnitude and duration are highly desirable. The ability of mTOR to regulate CD8+ T-cell functional differentiation must be exploited for clinical benefit. In a recent paper, we report that varying the regimen of rapamycin administration regulates viral vaccine-induced CD8+ T-cell responses for tumor immunity. These observations validate the use of rapamycin in vaccination strategies and demonstrate the efficacy of memory CD8+ T-cell responses for tumor immunity.
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