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The immunosuppressive effect of Wharton's jelly stromal cells depends on the timing of their licensing and on lymphocyte activation
No full textBACKGROUND: Mesenchymal stromal cells (MSC) have been proven to have potent immunosuppressive action and hence have been proposed for the treatment of severe Graft Versus Host Disease. However, in most models, MSC were added at the same time of lymphocyte stimulation, which is quite different from what occurs in vivo. AIMS: To investigate how the timing of lymphocyte activation and the exposure to activation-related cytokines (licensing) can influence the immunosuppressive action of Wharton's jelly stromal cells (WJSC). METHODS: WJSC, licensed or not with activation-related cytokines, were added lymphocytes the same time or 24 hours after their stimulation with phytohaemoagglutinin. Proliferation of lymphocytes and cytokines production was measured after three days co-culture. RESULTS: Lymphocytes stimulated in the presence of WJSC displayed a dramatic decrease in proliferation and production of cytokines, in spite of normal expression of activation markers. The suppression was weakened when targeted lymphocytes were seperated by a membrane and partially rescued by the addition of exogenous l-tryptophan, suggesting a major role for indoleamine 2,3-dioxigenase with a probable paracrine effect. Licensing of WJSC increased the immunosuppressive effect, in both contact and non-contact settings. The timing of WJSC licensing was crucial for the immunosuppressive action. Lymphocytes pre-stimulated alone for 24 h, and added afterwards to non-licensed WJSC, showed normal or even increased proliferation. On the other hand, their proliferation was strongly inhibited by licensed WJSC. CONCLUSIONS: WJSC have a potent immunosuppressive function best realized with direct contact, and increased by licensing signals before and during lymphocyte stimulation. Our results could contribute to the set up of new WJSC-based therapies for severe autoimmuno disorders
Knockdown of MVK does not lead to changes in NALP3 expression or activation
Full text linkMutations in the Mevalonate Kinase gene (MVK) are causes of a rare autoinflammatory disease: Mevalonate Kinase Deficiency and its more acute manifestation, Mevalonic Aciduria. The latter is characterized, among other features, by neuroinflammation, developmental delay and ataxia, due to failed cerebellar development or neuronal death through chronic inflammation. Pathogenesis of neuroinflammation in Mevalonate Kinase Deficiency and Mevalonic Aciduria has not yet been completely clarified, however different research groups have been suggesting the inflammasome complex as the key factor in the disease development. A strategy to mimic this disease is blocking the mevalonate pathway, using HMG-CoA reductase inhibitors (Statins), while knock-out mice for Mevalonate Kinase are non-vital and their hemyzygous (i.e only one copy of gene preserved) littermate display almost no pathological features
Microglia activation and interaction with neuronal cells in a biochemical model of mevalonate kinase deficiency
No full textMevalonate kinase deficiency is a rare disease whose worst manifestation, characterised by severe neurologic impairment, is called mevalonic aciduria. The progressive neuronal loss associated to cell death can be studied in vitro with a simplified model based on a biochemical block of the mevalonate pathway and a subsequent inflammatory trigger. The aim of this study was to evaluate the effect of the mevalonate blocking on glial cells (BV-2) and the following effects on neuronal cells (SH-SY5Y) when the two populations were cultured together. To better understand the cross-talk between glial and neuronal cells, as it happens in vivo, BV-2 and SH-SY5Y were co-cultured in different experimental settings (alone, transwell, direct contact); the effect of mevalonate pathway biochemical block by Lovastatin, followed by LPS inflammatory trigger, were evaluated by analysing programmed cell death and mitochondrial membrane potential, cytokines' release and cells' morphology modifications. In this experimental condition, glial cells underwent an evident activation, confirmed by elevated pro-inflammatory cytokines release, typical of these disorders, and a modification in morphology. Moreover, the activation induced an increase in apoptosis. When glial cells were co-cultured with neurons, their activation caused an increase of programmed cell death also in neuronal cells, but only if the two populations were cultured in direct contact. Our findings, being aware of the limitations related to the cell models used, represent a preliminary step towards understanding the pathological and neuroinflammatory mechanisms occurring in mevalonate kinase diseases. Contact co-culture between neuronal and microglial cells seems to be a good model to study mevalonic aciduria in vitro, and to contribute to the identification of potential drugs able to block microglial activation for this orphan disease. In fact, in such a pathological condition, we demonstrated that microglial cells are activated and contribute to neuronal cell death. We can thus hypothesise that the use of microglial activation blockers could prevent this additional neuronal death
Reappraisal of Antimalarials in Interferonopathies: New Perspectives for Old Drugs
Full text linkThe story of antimalarials as antinflammatory drugs dates back several centuries. Chinin, the extract of the Cinchona bark, has been exploited since the 18th century for its antimalarial and antifebrile properties. Later, during the Second World War, the broad use of antimalarials allowed arguing their antirheumatic effect on soldiers. Since then, these drugs have been broadly used to treat Systemic Lupus Erythematosus, but, only recently, have the molecular mechanisms of action been partly clarified. Inhibitory action on vacuole function and trafficking has been considered for decades the main mechanism of the action of antimalarials, affecting the activation of phagocytes and dendritic cells. In addition, chloroquine is also known as a potent inhibitor of autophagy, providing another possible explanation of its antinflammatory action. However, much attention has been recently devoted to the action of antimalarials on the so-called cGAS-STING pathway leading from the sensing of cytoplasmic nucleic acids to the production of type I interferons. This pathway is a fundamental mechanism of host defence, since it is able to detect microbial DNA and induce the type I interferon-mediated immune response. Of note, genetic defects in the degradation of nucleic acids lead to inappropriate cGAS-STING activation and inflammation. These disorders, called type I interferonopathies, represent a valuable model to study the antinflammatory potential of antimalarials. We will discuss possible development of antimalarials to improve the treatment of type I interferonopathies and likely multifactorial disorders characterised by interferon inflammation, such as Systemic Lupus Erythematosus
Is autophagy an elective strategy to protect neurons from dysregulated cholesterol metabolism?
Full text linkThe balance of autophagy, apoptosis and necroptosis is crucial to determine the outcome of the cellular response to cholesterol dysregulation. Cholesterol plays a major role in regulating the properties of cell membranes, especially as regards their fluidity, and the regulation of its biosynthesis influences the shape and functions of these membranes. Whilst dietary cholesterol can easily be distributed to most organs, the central nervous system, whose membranes are particularly rich in cholesterol, mainly relies on de novo synthesis. For this reason, defects in the biosynthesis of cholesterol can variably affect the development of central nervous system. Moreover, defective synthesis of cholesterol and its intermediates may reflect both on structural cell anomalies and on the response to inflammatory stimuli. Examples of such disorders include mevalonate kinase deficiency, and Smith-Lemli-Opitz syndrome, due to deficiency in biosynthetic enzymes, and type C Niemann-Pick syndrome, due to altered cholesterol trafficking across cell compartments. Autophagy, as a crucial pathway dedicated to the degradation of cytosolic proteins and organelles, plays an essential role in the maintenance of homeostasis and in the turnover of the cytoplasmic material especially in the presence of imbalances such as those resulting from alteration of cholesterol metabolism. Manipulating the process of autophagy can offer possible strategies for improving neuronal cell viability and function in these genetic disorders
Lovastatin induces apoptosis through the mitochondrial pathway in an undifferentiated SH-SY5Y neuroblastoma cell line
No full textApoptosis in SH-SY5Y Lova-treated cells follows the mitochondrial pathway; that is, it is caspase-9 and caspase-3 dependent; however, we also demonstrated that caspase-1 plays a role in this still unclear mechanism.
As statins induce the translocation of cytosolic Bax to the
mitochondria and allow to permeabilize the mitochondrial
outer membrane during apoptosis, further studies will be
carried out on the expression of proapoptotic genes, such as
Bax or Bcl2.
These findings, even if obtained in an SH-SY5Y undifferentiated
cell line, surely represent a first step towards the
understanding of the neuronal damage caused by inflammation
processes in MA
Selective resistance to different glucocorticoids in severe autoimmune disorders
No full textResistance to glucocorticoids often occurs in patients with severe inflammatory disorders. Occasionally, this resistance could be overcome by switching to a different glucocorticoid, but the mechanisms of this selectivity are not clear. We studied this condition in three patients with severe inflammatory disorders, who responded satisfactorily to betamethasone, but could not be switched to equipotent doses of methylprednisolone or prednisone. While betamethasone displayed similar activity on lymphocyte proliferation in cells obtained from the three patients and controls, higher concentrations of methylprednisolone were needed to inhibit proliferation in patients' cells. In a competition study, the concentration of methylprednisolone that inhibited 50\% of specific [(3)H]dexamethasone binding was increased in patients' lymphocytes. Higher Rhodamine-123 efflux was demonstrated in CD4 T cells from two patients, suggesting that an increased activity of membrane transporters could be responsible for the selective response to different glucocorticoids, even if P-glycoprotein and MRP1 expression was not increased
Mevalonate kinase deficiency: therapeutic targets, treatments, and outcomes
Full text linkIntroduction: Mevalonate Kinase Deficiency (MKD) is a rare inborn disease caused by the mutation of mevalonate kinase gene. The clinical phenotype encompasses recurrent fever episodes in combination with gastrointestinal,
immunological, rheumatological and neurological complaints. No specific treatment is available, apart from the newly approved biologics (canakinumab), but MKD can be still considered an orphan-drug disease, since the identification of a reliable therapeutic target needs an improved knowledge on the pathogenesis of the disease, which is so far controversial.
Areas covered: On one hand, shortage of isoprenoid compounds downstream of mevalonate led to a defective geranylgeranylation of RhoA/Rac proteins and increased caspase-1-dependent inflammation. On the other hand, recent studies pointed the attention to the pathogenic role of the mitochondrial dysfunction and to defective production of 25-hydroxycholesterol. These mechanisms are not exclusive of each other, as they can contribute to different pathogenic features of MKD.
Expert opinion: Innovative therapeutic approaches to MKD may count upon various medicaments, such as isoprenoid compounds that can enter the metabolic pathway, specific enzyme inhibitors and mitochondria-
targeted drugs. Some of these compounds have already passed the clinical phase for other uses and may be repositioned to the treatment of MKD, fostering the development of clinical trials
Differential action of 3-hydroxyanthranilic acid on viability and activation of stimulated lymphocytes.
No full textLymphocytes proliferation after antigen-driven activation leads to an increase in cell count, which could last some week, until apoptosis mechanisms allow the homeostatic control of the system. During the first days of this stimulation, activated lymphocytes display high resistance to apoptosis and to most immunosuppressive drugs. According to the literature, few compounds have been described to kill recently activated cells, by inhibiting metabolic processes fundamental to proliferation.
The aim of our work was to evaluate comparatively these different compounds, in order to identify the best strategy to kill cells that have undergone proliferation, while sparing the repertoire of resting cells.
After preliminary experiments, 3-HAA and bortezomib were selected as the most suitable compounds for our purposes. The possible synergic effect of 3-HAA with bortezomib or with manganese ions was also assessed.
3-HAA was confirmed to be the most reliable pharmacologic approach to inhibit proliferation with acceptable toxicity on resting cells. While in the case of PHA stimulation 3-HAA led to death of most lymphocytes, only a minor percentage of cells were killed after allo-stimulation, suggesting that the effect is proportional to the percentage of stimulated lymphocytes. Manganese ions further enhanced this effect, while results with bortezomib seemed to be less consistent.
These results deserve further investigations to develop new procedures for targeting activated cells with pharmacological approaches
The complex interplay between lipids, immune system and interleukins in cardio-metabolic diseases
Full text linkLipids and inflammation regulate each other. Early studies on this topic focused on the systemic effects that the acute inflammatory response—and interleukins—had on lipid metabolism. Today, in the era of the obesity epidemic, whose primary complications are cardio-metabolic diseases, attention has moved to the effects that the nutritional environment and lipid derangements have on peripheral tissues, where lipotoxicity leads to organ damage through an imbalance of chronic inflammatory responses. After an overview of the effects that acute inflammation has on the systemic lipid metabolism, this review will describe the lipid-induced immune responses that take place in peripheral tissues and lead to chronic cardio-metabolic diseases. Moreover, the anti-inflammatory effects of lipid lowering drugs, as well as the possibility of using anti-inflammatory agents against cardio-metabolic diseases, will be discussed
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