ALBERT

Description: Previous work has demonstrated that precipitated (NM-200) and pyrogenic (NM-203) Amorphous Silica Nanoparticles (ASNPs) elicit the inflammatory activation of murine macrophages, with more pronounced effects observed with NM-203. Here, we compare the effects of low doses of NM-200 and NM-203 on human macrophage-like THP-1 cells, assessing how the pre-exposure to these nanomaterials affects the cell response to lipopolysaccharide (LPS). Cell viability was affected by NM-203, but not by NM-200, and only in the presence of LPS. While NM-203 stimulated mTORC1, neither ASNPs activated NFκB or the transcription of its target genes PTGS2 and IL1B. NM-200 and NM-203 caused a block of the autophagic flux and inhibited the LPS-dependent increase of Glutamine Synthetase (GS) expression. Both ASNPs suppressed the activation of caspase-1, delaying the LPS-dependent secretion of IL-1β. Thus, ASNPs modulate several important pathways in human macrophages, altering their response to LPS. NM-203 had larger effects on autophagy, mTORC1 activity and GS expression than NM-200, confirming the higher biological activity of pyrogenic ASNPs when compared with precipitated ASNPs.

Description: The possibility of counteracting inflammation-related barrier defects with dietary compounds such as (poly)phenols has raised much interest, but information is still scarce. We have investigated here if (+)-catechin (CAT) and procyanidin B2 (PB2), two main dietary polyphenols, protect the barrier function of intestinal cells undergoing inflammatory stress. The cell model adopted consisted of co-cultured Caco-2 and HT29-MTX cells, while inflammatory conditions were mimicked through the incubation of epithelial cells with the conditioned medium of activated macrophages (MCM). The epithelial barrier function was monitored through trans-epithelial electrical resistance (TEER), and ROS production was assessed with dichlorofluorescein, while the expression of tight-junctional proteins and signal transduction pathways were evaluated with Western blot. The results indicated that MCM produced significant oxidative stress, the activation of NF-κB and MAPK pathways, a decrease in occludin and ZO-1 expression, and an increase in claudin-7 (CL-7) expression, while TEER was markedly lowered. Neither CAT nor PB2 prevented oxidative stress, transduction pathways activation, ZO-1 suppression, or TEER decrease. However, PB2 prevented the decrease in occludin expression and both polyphenols produced a huge increase in CL-7 abundance. It is concluded that, under the conditions adopted, CAT and PB2 do not prevent inflammation-dependent impairment of the epithelial barrier function of intestinal cell monolayers. However, the two compounds modify the expression of tight-junctional proteins and, in particular, markedly increase the expression of CL-7. These insights add to a better understanding of the potential biological activity of these major dietary flavan-3-ols at intestinal level.

Description: High glycolitic activity of multiple myeloma (MM) cells is the rationale for the use of Positron Emission Tomography (PET) with 18F-fluorodeoxyglucose ([18F]FDG) to detect both medullary and extramedullary disease. However, FDG-PET has some limitations, since there is a good portion of MM patients who are false-negative. Besides enhanced glycolysis, glutamine (Gln) addiction has been recently described as a metabolic feature of MM by our group. To sustain high Gln demand, MM cells increase the expression of several Gln transporters (ASCT2, SNAT1, LAT1) and are endowed with fast Gln uptake. Yet, at variance with other Gln-addicted cancers, the possible exploitation of Gln as a PET tracer in MM has never been assessed and was investigated in this study. To this purpose, we have firstly synthesized enantiopure (2S,4R)-4-Fluoroglutamine (4-FGln) and validated it as a Gln analogue in human MM cell lines (RPMI8226 and JJN3) comparing its uptake with that of 3H-labelled Gln. The intracellular levels of 4-FGln were determined by HPLC-MS/MS employing a HILIC gradient separation and multiple reaction monitoring (MRM) detection. Both Gln and 4-FGln were actively accumulated by MM cells and exhibited a strong reciprocal competition, pointing to shared transporters. Inhibition analysis revealed that ASCT2 was the major entry route of both compounds, with minor contributions from the other transporters. However, compared with Gln, 4-FGln exhibited higher affinity for both ASCT2 and LAT1 transporters. On the basis of these results, we then tested [18F]4-FGln uptake for MM detection by Positron Emission Tomography (PET) in two different in vivo murine models. Firstly, to investigate sensitivity of human MM to [18F]4-FGln in vivo, JJN3 cells were subcutaneously injected in immunodeficient NSG mice In this xenograft model, [18F]4-FGln- and[18F]FDG-PET scans were performed after plasmacytomas became palpable and repeated after one week. All the tumours were positive for [18F]FDG and displayed [18F]4-FGln uptake with Standard Uptake Values (SUV) of 1.21±1.9 and 0.99±0.07 after 2 weeks, respectively. Thereafter, the effect of bortezomib (BOR) was investigated to evaluate the potential use of [18F]4-FGln to monitor anti-MM treatment. Ten NGS mice were injected with JJN3 cells and, after 14 days, treated twice weekly with BOR, 1mg/kg, or vehicle for two weeks. PET scans were performed before and after 5 and 12 days of BOR treatment. As expected, BOR reduced tumour size as compared to vehicle. At the first post-BOR PET scan, [18F]4-FGln (SUV mean: pre 0.85±0.31; post 0.45±0.10, P

Description: Multiple myeloma (MM) cells are characterized by tight dependence on the bone marrow (BM) microenvironment that exerts a permissive role on cell growth and survival. In turn, MM cells markedly modify their microenvironment leading, in particular, to the development of osteolytic bone lesions. Recently, we demonstrated that metabolic alterations is a major feature of MM cells showing that BM plasma of MM patients is characterized by lower levels of Glutamine (Gln) and higher levels of Glutamate (Glu) and ammonium when compared with patients with smoldering MM (SMM) and Monoclonal Gammopathy of Uncertain Significance (MGUS). In the majority of MM patients MM cells are Gln-addicted since they strictly depend on extracellular Gln, do not express Glutamine Synthetase (GS), the enzyme that synthetizes Gln from Glu and ammonium, and are endowed with high levels of the Gln transporter ASCT2. Based on this evidence, we have hypothesized that the peculiar Gln metabolism of MM cells may have a significant impact on the relationship with the bone microenvironment and contribute to the development of osteolytic lesions. We firstly characterized a panel of human MM cell lines (HMCLs) for their GS expression and response to decreasing levels of Gln. The majority of HMCLs, which did not express GS, consumed large amounts of extracellular Gln but secreted nearly half of the amino acid as Glu. Two HMCLs, MM1.S and U266, with a sizable GS expression, were less sensitive to Gln deprivation and secreted less Glu in the extracellular space compared with GS-negative HMCLs. Consistently, the activity of the Glu exchanger x-CT (the product of SLC7A11 gene) was lower in GS-positive than in GS-negative cells. The response to Gln starvation was then studied in mesenchymal stromal cell line (MSC), as well as in osteoblastic (HOBIT) and pre-osteocytic cells (HOB-01). HOBIT and HOB-01 were more sensitive to Gln depletion than MSC. Indeed, while MSC showed a low EC50 for Gln (0.064mM), which is 10-times lower than the physiological blood Gln concentration (around 0.6 mM), the EC50 values of HOBIT and HOB-01 cells were 0.250 mM and 0.297mM, respectively. Furthermore, L-methionine sulfoximine (MSO), an irreversible inhibitor of GS, emphasized the effects of Gln deprivation on all the cell lines tested. Indeed, Gln deprivation enhanced the expression of GS, suggesting that both stromal and osteoblastic cells exploit the enzyme to counteract Gln deprivation. On the basis of these data, we assessed the effects of Gln and Glu on osteogenic differentiation by incubating MSC, either immortalized or primary, with an osteogenic medium containing different concentrations of Gln and Glu. After 2 weeks, compared with cells differentiated in high Gln/high Glu conditions, MSC incubated in the presence of decreased Gln and increased Glu showed lower osteogenic ability, as assessed by real time PCR and ALP staining. Lastly, MSC co-cultured for 72 hours with GS-negative, but not with GS-positive HMCLs, showed reduced viability and increased GS expression. Lastly, to put in a translational perspective these in vitro observations, we analyzed the BM plasma levels of Gln and Glu in a cohort of 41 patients with newly diagnosed MM, including 9 smoldering MM (SMM) and 32 active MM patients (20 of them with osteolytic bone disease, 12 of them without bone disease). All 20 osteolytic MM patients had more than three osteolytic lesions. We found that MM patients had lower Gln levels and higher Glu levels than SMM patients. Moreover, when compared with MM patients without bone disease, MM patients with bone disease showed lower levels of Gln and higher levels of Glu. The results of these analyses are being continuously updated increasing the number of samples tested. Overall, these results indicate that MM cells are able to create a low-Gln/high-Glu bone marrow microenvironment that sustains GS expression in bone cells and impairs their differentiation and viability. Thus, the peculiar metabolic milieu in the MM bone microenvironment affects the relationship between neoplastic and bone cells and may contribute to the development of osteolytic bone disease in MM patients. Disclosures Aversa: Astellas: Honoraria; Merck: Honoraria; Pfizer: Honoraria, Membership on an entity's Board of Directors or advisory committees; Basilea: Honoraria, Membership on an entity's Board of Directors or advisory committees; Gilead: Honoraria, Membership on an entity's Board of Directors or advisory committees. Giuliani:Takeda Pharmaceutical Co: Research Funding; Celgene Italy: Other: Avisory Board, Research Funding; Janssen Pharmaceutica: Other: Avisory Board, Research Funding.

Description: In cultured human fibroblasts, SNAT transporters (System A) account for the accumulation of non-essential neutral amino acids, are adaptively up-regulated upon amino acid deprivation and play a major role in cell volume recovery upon hypertonic stress. No information is instead available on the expression and activity of SNAT transporters in human bone marrow mesenchymal stromal cells (MSC), although they are increasingly investigated for their staminal and immunomodulatory properties and used for several therapeutic applications. The uptake of glutamine and proline, two substrates of SNAT1 and SNAT2 transporters, was measured in primary human MSC and an MSC line. The amino acid analogue MeAIB, a specific substrate of these carriers, has been used to selectively inhibit SNAT-dependent transport of glutamine and, through its sodium-dependent transport, as an indicator of SNAT1/2 activity. SNAT1/2 expression and localization were assessed with RT-PCR and confocal microscopy, respectively. Cell volume was assessed from urea distribution space. In all these experiments, primary human fibroblasts were used as the positive control for SNAT expression and activity. Compared with fibroblasts, MSC have a lower SNAT1 expression and hardly detectable membrane localization of both SNAT1 and SNAT2. Moreover, they exhibit no sodium-dependent MeAIB uptake or MeAIB-inhibitable glutamine transport, and exhibit a lower ability to accumulate glutamine and proline than fibroblasts. MSC exhibited an only marginal increase in MeAIB transport upon amino acid starvation and did not recover cell volume after hypertonic stress. In conclusion, the activity of SNAT transporters is low in human MSC. MSC adaptation to amino acid shortage is expected to rely on intracellular synthesis, given the absence of an effective up-regulation of the SNAT transporters.

Description: Metabolic alterations of cancer cells, aimed at sustaining their growth, may also influence the behavior of the tumor microenvironment. Our group has recently demonstrated that multiple myeloma (MM) is a highly glutamine(Gln)-addicted tumor that utilize huge amounts of Gln to fuel its metabolism through the enzyme glutaminase (GLS). For this reason, MM cells exhibits increased Gln uptake, mainly through the ASCT2 transporter. Interestingly, lower bone marrow (BM) plasma Gln concentration (down to a median value of 0.4 mM vs. a median value of 0.6 mM) was found in MM patients as compared with smoldering MM (SMM) and Monoclonal Gammopathy of Uncertain Significance (MGUS). The main feature of MM BM microenvironment is the suppression of osteoblastic (OB) differentiation leading to the development of osteolytic bone lesions, the hallmark of MM. Most recently, it has been demonstrated that Gln metabolism is needed to sustain bone mass formation in murine models and that GLS inhibition decreases OB differentiation of human mesenchymal stromal cells (hMSCs). However, no information is yet available on the role of Gln depletion imposed by MM cell metabolism on OB differentiation into the BM. This topic has been investigated in the present study. Firstly, human MM cells were co-cultured with BM hMSCs, and Gln medium concentration was evaluated with mass spectrometry (MS), demonstrating a MM-induced depletion of the amino acid. Upon Gln depletion, MSC exhibited a sustained induction of Glutamine Synthetase (GS). On the contrary, when differentiated in osteogenic medium (D-MEM + 5% Fetal Bovine Serum, supplemented with 2 mM Gln, ascorbic acid and dexamethasone), GS was suppressed. Conversely, GLS (both KGA and GAC isoforms) and SLC38A2, the gene for the concentrative Gln transporter SNAT2, were induced. These data suggest that hMSCs differentiation in OBs is associated with an increased dependence upon extracellular Gln. Consistent with this conclusion, the activity of SNAT2 was absent in undifferentiated hMSCs but well detectable after 14 days of OB differentiation, when total Gln uptake was also increased. Under the same conditions, OB differentiation markers (RUNX2, COL1A1, ALPL expression and ALPL activity or staining) were significantly induced but their expression was blunted by incubation in low-Gln (0.4 mM) medium or in the presence of the SNAT2 inhibitor MeAIB. The incubation in Gln-free D-MEM suppressed the induction of GLS and SLC38A2 along with OB differentiation, which was restored by the supplementation of Non-Essential Amino Acids (NEAA). Among NEAA, only asparagine (Asn) was able to rescue OB differentiation in the absence of Gln. The determination of intracellular amino acids with MS indicated that OB differentiation was associated with the increase of cell Asn, without significant changes of Gln, glutamate (Glu) or aspartate (Asp). Asparagine Synthetase (ASNS), the Gln-dependent enzyme that accounts for Asn synthesis, was also found induced during OB differentiation of hMSCs. Gene Expression Profiles of primary BM hMSCs and OBs from bone biopsies of both healthy donors (n=7) and MM patients (n=16) indicated that GLS, ASNS, and SLC38A2 are more expressed in OBs, while the expression of GLUL, the gene for GS, is higher in undifferentiated hMSCs from healthy donors. Overall, these results indicate that (1) OB differentiation of hMSCs is Gln-dependent; (2) the partial Gln depletion, imposed by Gln-addicted MM cells in the BM microenvironment, contributes to the impairment of osteoblastic differentiation of hMSCs; (3) hindrance of differentiation may depend on the limited availability of intracellular Asn derived from Gln-dependent ASNS. These results support the evidence that Gln addiction of MM cells affects bone microenvironment leading to the inhibition of OB differentiation and, consequently, to the development of MM bone disease. Disclosures Giuliani: Janssen: Research Funding.