Omar Ben Mariem scite author profile

NONO and SFPQ are involved in multiple nuclear processes (e.g., pre-mRNA splicing, DNA repair, and transcriptional regulation). These proteins, along with NEAT1, enable paraspeckle formation, thus promoting multiple myeloma cell survival. In this paper, we investigate NONO and SFPQ dimer stability, highlighting the hetero- and homodimer structural differences, and model their interactions with RNA, simulating their binding to a polyG probe mimicking NEAT1guanine-rich regions. We demonstrated in silico that NONO::SFPQ heterodimerization is a more favorable process than homodimer formation. We also show that NONO and SFPQ RRM2 subunits are primarily required for protein–protein interactions with the other DBHS protomer. Simulation of RNA binding to NONO and SFPQ, beside validating RRM1 RNP signature importance, highlighted the role of β2 and β4 strand residues for RNA specific recognition. Moreover, we demonstrated the role of the NOPS region and other protomer’s RRM2 β2/β3 loop in strengthening the interaction with RNA. Our results, having deepened RNA and DBHS dimer interactions, could contribute to the design of small molecules to modulate the activity of these proteins. RNA-mimetics, able to selectively bind to NONO and/or SFPQ RNA-recognition site, could impair paraspeckle formation, thus representing a first step towards the discovery of drugs for multiple myeloma treatment.

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In silico investigation on structure–function relationship of members belonging to the human SLC52 transporter family

Mariem

Saporiti

Guerrini

et al. 2022

Proteins

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Riboflavin is an essential water-soluble vitamin that needs to be provided through the diet because of the conversion into flavin adenine dinucleotide (FAD) and flavin mononucleotide (FMN), important cofactors in hundreds of flavoenzymes. The adsorption and distribution of riboflavin is mediated by transmembrane transporters of the SLC52 family, namely RFVT1-3, whose mutations are mainly associated with two diseases, MADD and the Brown-Vialetto-Van Laere syndrome. Interest in RFVTs as pharmacological targets has increased in the last few years due to their overexpression in several cancer cells, which can be exploited both by blocking the uptake of riboflavin into the cancerous cells, and by performing cancer targeted delivery of drugs with a high affinity for RFVTs. In this work, we propose three-dimensional structural models for all three human riboflavin transporters obtained by state-ofthe-art artificial intelligence-based methods, which were then further refined with molecular dynamics simulations. Furthermore, two of the most notable mutations concerning RFVT2 and RFVT3 (W31S and N21S, respectively) were investigated studying the interactions between the wild-type and mutated transporters with riboflavin.

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Effect of Fc core fucosylation and light chain isotype on IgG1 flexibility

et al. 2023

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N-glycosylation plays a key role in modulating the bioactivity of monoclonal antibodies (mAbs), as well as the light chain (LC) isotype can influence their physicochemical properties. However, investigating the impact of such features on mAbs conformational behavior is a big challenge, due to the very high flexibility of these biomolecules. In this work we investigate, by accelerated molecular dynamics (aMD), the conformational behavior of two commercial immunoglobulins G1 (IgG1), representative of κ and λ LCs antibodies, in both their fucosylated and afucosylated forms. Our results show, through the identification of a stable conformation, how the combination of fucosylation and LC isotype modulates the hinge behavior, the Fc conformation and the position of the glycan chains, all factors potentially affecting the binding to the FcγRs. This work also represents a technological enhancement in the conformational exploration of mAbs, making aMD a suitable approach to clarify experimental results.

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Innovative 3D proteome-wide scale identification of ALKBH5 target for MV1035 small molecule able to reduce migration and invasiveness in U87 glioblastoma cell lines by SPILLO-PBSS

et al. 2021

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The innovative in silico technologies developed at SPILLOproject,1 e.g., the SPILLO potential binding sites searcher (SPILLO-PBSS) software,2,3 allow to identify targets and off-targets of any small molecule on a multiple-organism proteomewide scale, and to perform an accurate multilevel cross-organism transferability analysis (MCOTA) aimed at rationalising animal testing. SPILLO-PBSS has been successfully used in several research projects, such as a study in which a compound (MV1035) was found to reduce migration and invasiveness in U87 glioblastoma (GBM) cell lines: the human structural proteome was analyzed and the RNA demethylase ALKBH5 has been identified as a target responsible for the observed effects (target experimentally validated). Another top-ranked target identified by SPILLO-PBSS, the DNA repair protein AlkB homolog 2 (ALKBH2), abundantly expressed in GBM cell lines, resulted particularly interesting for its pivotal role in the onset of resistance to Temozolomide (TMZ), the standard firstline treatment for GBM.2

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Omar Ben Mariem

Molecular Modelling of NONO and SFPQ Dimerization Process and RNA Recognition Mechanism

In silico investigation on structure–function relationship of members belonging to the human SLC52 transporter family

Effect of Fc core fucosylation and light chain isotype on IgG1 flexibility

Innovative 3D proteome-wide scale identification of ALKBH5 target for MV1035 small molecule able to reduce migration and invasiveness in U87 glioblastoma cell lines by SPILLO-PBSS

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