Author: Dąbrowski, Michał J ; Filip, Adam ; Łapiński, Marcin ; Grynberg, Marcin ; Wlasnowolski, Michal ; Saha, Indrajit ; Agarwal, Abhishek ; Plewczynski, Dariusz ; Ghosh, Nimisha ; Jardanowska-Kotuniak, Marta ; Sengupta, Kaustav ; Pancaldi, Vera ; Dramiński, Michał

Breast cancer affects over 2 million women annually and results in 650,000 deaths. This study aimed to identify epigenetic mechanisms impacting breast cancer-related gene expression, discover potential biomarkers, and present a novel approach integrating feature selection, Natural Language Processing, and 3D chromatin structure analysis. We used The Cancer Genome Atlas database with over 800 samples and multi-omics datasets (mRNA, miRNA, DNA methylation) to select 2701 features statistically significant in cancer versus control samples, from an initial 417,486, using the Monte Carlo Feature Selection and Interdependency Discovery algorithm. Classification of cancer vs. control samples on the selected features returned very high accuracy, depending on feature-type and classifier. The cancer samples generally showed lower expression of differentially expressed genes (DEGs) and increased β-values of differentially methylated sites (DMSs). We identified mRNAs whose expression is explained by miRNA expression and β-values of DMSs. We recognized DMSs affecting NRF1 and MXI1 transcription factors binding, causing a disturbance in NKAPL and PITX1 expression, respectively. Our 3D models showed more loosely packed chromatin in cancer. This study highlights numerous possible regulatory dependencies, and the presented bioinformatic approach provides a robust framework for data dimensionality reduction, enabling the identification of key features for further experimental validation.

01 Jul 2025·JOURNAL OF MOLECULAR GRAPHICS & MODELLING

Mechanistic insights on the antioxidant activity of selected neurotransmitters

Article

Author: Kritik Shai, M P ; Sharanya, J ; Janardanan, Deepa

Antioxidant activity of neurotransmitters such as dopamine, serotonin, and octopamine are studied employing density functional theory at the M062X/6-311+G∗∗ level. The hydroperoxyl radical scavenging activity of these molecules is evaluated based on thermodynamic and kinetic calculations in the gas phase as well as in solvents that mimic physiological environments. The HAT mechanism is predicted to be favored in the gas phase, whereas the SPLET mechanism is preferred in water as well as in the lipid medium. Antioxidant activity of these molecules is attributed to the presence of phenolic OH groups. Dopamine is found to be the most active antioxidant in gas as well as polar medium, whereas Serotonin exhibited higher reactivity in the lipid medium. It is identified that the nature of the environment influences the antioxidant activity of these molecules. H-bonding interaction involving the vicinal OH group of the phenoxide radical is identified to be crucial towards stabilizing the radical generated from the D2 site of dopamine, making it the most reactive site of radical attack as per the HAT mechanism. Kinetic calculations of the HAT mechanism suggest that the D2 site of dopamine has the highest rate constant both in the gas phase (1.32 × 10⁶ L mol^-1 s^-1) as well as in aqueous medium (9.11 × 10³ L mol^-1 s^-1), whereas the S1 site of serotonin is predicted to be the most feasible site of attack in the lipid medium (2.15 × 10⁵ L mol^-1 s^-1). Octopamine is found to be the least reactant molecule among the three.

01 Jun 2025·3 Biotech

Exploring anticancer activity of baicalin, naringenin, and noscapine via binding and inhibition of sphingosine kinase 1

Article

Author: Afzal, Mohammad ; Mohammad, Taj ; Hussain, Afzal ; Hassan, Md Imtaiyaz ; Sohal, Sukhwinder Singh ; AlAjmi, Mohamed F ; Chakrabarty, Anindita ; Haider, Shaista ; Shakeel, Ilma

Sphingosine kinase 1 (SphK1) is an essential enzyme in sphingolipid metabolism, catalyzing the phosphorylation of sphingosine to produce sphingosine-1-phosphate (S1P), a bioactive lipid with diverse roles in cell proliferation, survival, and migration. Dysregulation of the SphK1/S1P axis is implicated in a variety of pathological conditions, including inflammatory, metabolic, and neurodegenerative diseases. Targeting SphK1 represents a promising therapeutic strategy, particularly in oncology and inflammation-related pathologies. In this study, we investigated the potential of three natural compounds, Baicalin (BA), Naringenin (NR), and Noscapine (NS) as SphK1 inhibitors. Through combined molecular docking, molecular dynamics simulations, binding studies and enzyme inhibition assays, we identified these compounds as effective SphK1 inhibitors. BA, NR, and NS exhibited binding affinities characterized by IC50 values of 26.542, 32.157, and 28.134 μM, respectively. These molecules bind to the active site of SphK1 with favorable binding energies with strong non-covalent interactions. This study provides structural and functional insights into potential of BA, NR, and NS to target SphK1 selectively, which can function as lead compounds for developing novel anti-cancer therapy with minimal off-target effects, offering avenues for developing drugs with enhanced specificity and affinity for this enzyme.

News (Medical) associated with Shiv Nadar University

07 Aug 2023

·www.sciencedaily.com

Discovery in nanomachines within living organisms -- cytochromes P450 (CYP450s) unleashed as living soft robots

A new study suggests that Cytochromes P450 (CYP450s) enzymes can sense and respond to stimuli, acting like soft robots in living systems. Study reveals an important discovery in the realm of nanomachines within living systems. Prof. Sason Shaik from the Hebrew University of Jerusalem and Dr. Kshatresh Dutta Dubey from Shiv Nadar University, conducted molecular-dynamics simulations of Cytochromes P450 (CYP450s) enzymes, revealing that these enzymes exhibit unique soft-robotic properties. Cytochromes P450 (CYP450s) are enzymes found in living organisms and play a crucial role in various biological processes, particularly in the metabolism of drugs and xenobiotics. The researchers' simulations demonstrated that CYP450s possess a fourth dimension -- the ability to sense and respond to stimuli, making them soft-robot nanomachines in "living matters." In the catalytic cycle of these enzymes, a molecule called a substrate binds to the enzyme. This leads to a process called oxidation. The enzyme's structure has a confined space that allows it to act like as a sensor and a soft robot. It interacts with the substrate using weak interactions, like soft impacts. These interactions transfer energy, causing parts of the enzyme and the molecules inside it to move. This movement generates ultimately a special substance called oxoiron species, which serves the enzyme to oxidize a variety of different substances. The key takeaway from these molecular-dynamics simulations is that the catalytic cycle of CYP450s is complex but follows a logical sequence. The enzyme's restricted space, strategic residue placements, and channels allow it to be a sensitive sensor of the substrate, its own heme changes, and conformational shifts in the active site. This sensing-response capability creates a soft-robot with a fourth dimension of sensing, something previously unseen in regular 3D matter. "We have discovered that CYP450s act as soft-robot machines in 'living matters,' displaying a remarkable sensing and response-action capability. This is an exciting revelation, and we believe that similar mechano-transduction mechanisms of soft-impact cues might be at work in other soft-robot machines in nature," stated Prof. Sason Shaik, one of the lead researchers. The findings open up new avenues in soft-robotics research, as 4D materials are gaining significance, driven by external triggers. These materials, such as hydrogels produced through 3D printing, resemble enzymes in their ability to sense and induce changes. The implications of this discovery extend beyond the realm of biology and chemistry, potentially revolutionizing fields like artificial intelligence design and self-evolving polymers/gels synthesis. Dr. Kshatresh Dutta Dubey, co-researcher of the study, added, "We are entering an exciting era for chemistry, where soft-robotics and intelligent design of nanomachines can lead to unprecedented advancements. The future may witness the creation of self-evolving polymers and perpetual nanomachines capable of synthesizing new molecules at will." The scientists believe that the integration of the soft-robotic language and machine programming could accelerate progress in the development of 4D materials and unlock the full potential of soft-robotics.

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Drug(Targets)	Indications	Global Highest Phase

KKI-04 ( EGFR L858R x EGFR T790M )	Non-Small Cell Lung Cancer More	Preclinical
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