Articles

Consensus guidelines for cellular label-free optical metabolic imaging: ensuring accuracy and reproducibility in metabolic profiling
- Georgakoudi Irene
- Skala Melissa
- Quinn Kyle
- Stringari Chiara
- Sorrells Janet
- Heikal Ahmed
- Li Lin
- Xu He
- You Sixian
- Walsh Alex
- Datta Rupsa
- Samimi Kayvan
- Gillette Amani
- Eliceiri Kevin
- Balu Mihaela
- Boppart Stephen
- Digman Michelle
- Dunning Kylie
- Evans Conor
- Garcia Alba Alfonso
- Houston Jessica
- Hwang Wonsang
- Lindley Matthew
- Li Xingde
- Liu Zhiyi
- Marcu Laura
- Murugkar Sangeeta
- Nichols Michael
- Niesner Raluca
- Parekh Sapun
- Rajaram Narasimhan
- Ranjit Suman
- Shen Keyue
- Shi Lingyan
- Torrado Belén
- Vallmitjana Alexander
- Wang-Evers Michael
- Zemp Roger
Journal of Biomedical Optics, Society of Photo-optical Instrumentation Engineers , 2025, 30 (S2), pp.S23901 . Significance: Cellular metabolism plays a central role in health and disease, making its study critical for advancing diagnostics and therapies. Label-free optical metabolic imaging using endogenous fluorescence from reduced nicotinamide adenine dinucleotide (phosphate) [NAD(P)H] and flavin adenine dinucleotide (FAD) provides nondestructive, high-resolution insights into metabolic function and heterogeneity from the sub-cellular to the tissue level. Standardized approaches are essential to ensure reproducibility and comparability across studies. Aim: We aim to establish a consensus framework for the acquisition, calibration, and reporting of microscopic imaging metabolic function assessments based on fluorescence intensity and lifetime measurements of NAD(P)H and FAD. Approach: We present best practices for calibrating, analyzing, and reporting fluorescence intensity-based optical redox ratios and fluorescence lifetime data using multiexponential fitting and phasor analysis. Guidelines for validation experiments and cross-system standardization are provided to improve accuracy and reproducibility. Results: We demonstrate the importance of calibration procedures and normalization strategies for intensity-based optical redox measurements. We highlight needed calibration, signal-to-noise ratio considerations, and the impact of distinct analytical approaches on fluorescence lifetime-based metabolic function metrics. Conclusion: We recommend a consistent, practical framework for reproducible, label-free, optical metabolic imaging, facilitating robust comparisons across studies and supporting the broader adoption of optical metabolic imaging technologies for biomedical research and clinical translation. (10.1117/1.JBO.30.S2.S23901)
DOI : 10.1117/1.JBO.30.S2.S23901
ViT-based Local Volume Dwarf Galaxy Identification (VIDA) in the CSST survey
- Qu Han
- Yuan Zhen
- Wei Chengliang
- Liu Chao
- Chang Jiang
- Li Guoliang
- Martin Nicolas F
- Tsai Chaowei
- Shao Shi
- Luo Yu
- Li Ran
- Kang Xi
- Xue Xiangxiang
- Fan Zhou
Monthly Notices of the Royal Astronomical Society, Oxford University Press (OUP): Policy P - Oxford Open Option A , 2025, 544, pp.1238 - 1254 . <div><p>Identifying dwarf galaxies within the Local Volume is crucial for constraining the luminosity function of satellite galaxies in the nearby universe. We report the detection capabilities of dwarf galaxies within the Local Volume using the Chinese Space Station Telescope (CSST). Based on the simulated imaging data of CSST, we present VIDA, a ViT-based dwarf galaxy identification Algorithm designed for detecting Local Volume dwarf galaxies. The simulated Local Volume dwarf galaxies can be identified using a pre-processing method for 'extended source detection', followed by classification with a pretrained ViT-Base model. This pipeline achieves a true positive rate exceeding 85 per cent with a false positive rate of only 0.1 per cent. We quantify the detection completeness of Local Volume dwarf galaxies across a three-dimensional parameter space defined by absolute magnitude ( M V ), half-light radius ( R h ), and heliocentric distance, based on simulated single-exposure CSST wide-field imaging survey data. For unresolved or semiresolved dwarf galaxies, our method achieves a significantly deeper absolute magnitude detection limit compared to catalogue-based approaches, reaching M V = -7 within 10 Mpc with a surface brightness threshold μ ∼ 25 mag/arcsec 2 at 2-5 Mpc and ∼26 mag/arcsec 2 at 5-10 Mpc. While traditional matched-filter techniques based on stellar catalogues remain more effective for detecting fully resolved, extremely low surface brightness galaxies within 5 Mpc, our approach offers complementary strengths -particularly in identifying compact or more distant systems -making it a valuable tool for expanding the census of Local Volume dwarf galaxies.</p></div> (10.1093/mnras/staf1586)
DOI : 10.1093/mnras/staf1586
Ultrafast photooxidation of semireduced flavin in fatty acid photodecarboxylase
- Vos Marten
- Balduzzi Elsa
- Sorigué Damien
- Aleksandrov Alexey
Science Advances, American Association for the Advancement of Science (AAAS) , 2025, 11 (38) . The initial photoproduct of the natural photoenzyme fatty acid photodecarboxylase involves the flavin anion radical flavin adenine dinucleotide (FAD •– ). Using spectrally resolved ultrafast transient absorption spectroscopy, we demonstrate that FAD •– photoexcitation in the absence of substrate leads to the formation of the oxidized flavin FAD ox (the resting state in the catalytic cycle) within 100 femtoseconds. While this feature is similar to that occurring in flavoprotein oxidases, the ensuing photocycle is more complex. Upon excitation at the lowest-energy transition, the ejected electron is initially captured as a hydrated electron ( e – H ) before transferring to a secondary acceptor in 2.5 picoseconds and returning to the flavin in 37 picoseconds. This implies that e – H can be generated within a protein environment, an unprecedented finding. This assessment is supported by molecular dynamics simulations showing an expansion of the flavin-binding pocket without substrate, allowing water molecules to fill the void. Our results may pave the way to developing unconventional photocatalytic processes. (10.1126/sciadv.adz1904)
DOI : 10.1126/sciadv.adz1904
A Selective and Sensitive Method for Colistin Detection by G-Quadruplex Ligand Competition
- Wei Shijiong
- Qiu Dehui
- Yan Xinrong
- Liu Bin
- Mergny Jean-Louis
- Monchaud David
- Ju Huangxian
- Zhou Jun
Analytical Chemistry, American Chemical Society , 2025, 97 (31), pp.16805 . Colistin (COL) is a widely used antibiotic and is quite often used as a last-resort treatment option for treating multidrug-resistant Gram-negative bacterial infections. Due to its widespread use, COL accumulates in nature, which represents a novel ecological and health threat. However, there is currently no rapid and specific method available for titrating COL levels in collected samples. Herein, we report a simple chemiluminescence detection method based on the specific interaction between COL and a parallel G-quadruplex (G4). To this end, we exploit the catalytic properties of the G4/hemin DNAzyme, which is able to oxidize substrates to provide a readily monitored readout. The stronger affinity of G4 for COL versus hemin allows for the inactivation of the G4/hemin DNAzyme, which is used herein to quantify COL in solution. Through a series of optimizations, we identified the best G4 sequence (F3TC), oxidation substrate (luminol), and experimental conditions, which allow for the detection of COL over a broad concentration window, from 0.5 to 2,500 ng/mL, with a detection limit of 0.4 ng/mL and excellent selectivity against other antibiotics. Compared with existing methods, the proposed approach provides a simpler and label-free quantification of COL, which might serve as a valuable standard method for antibiotic detection, whose use was validated under real conditions herein (10.1021/acs.analchem.5c01733)
DOI : 10.1021/acs.analchem.5c01733
Design, synthesis, biophysical and biological evaluation of original condensed pyrrolopyrimidine and pyrrolopyridine ligands as anti-SARS-CoV-2 agents targeting G4
- Guillon Jean
- Savrimoutou Solène
- da Rocha Nicolas
- Albenque-Rubio Sandra
- Helynck Olivier
- Durand Cyrielle
- Chiaravalli Jeanne
- Pinaud Noël
- Ronga Luisa
- Moreau Stéphane
- Chirold Simon
- Zangmo Tshering
- Arab Melika
- Lari Lindita
- Mergny Jean‐louis
- Munier-Lehmann Hélène
- Lavigne Marc
European Journal of Medicinal Chemistry, Elsevier , 2025, 292, pp.117655 . The design and synthesis of novel bis[(substituted-aminomethyl)phenyl]phenyl pyrrolopyrimidines, pyrrolopyridines, pyrazolopyrimidines, imidazopyrimidines, and tris[(substituted-aminomethyl)phenyl]phenyl pyrrolopyrimidines are reported here. These original G-quadruplex (G4) ligands have been then subjected to a screening on SARS-CoV-2 using a competition HTRF assay by targeting the SUD-NM/TRF2 RNA G4 interaction. The more promising derivatives have been evaluated in vitro to determine their potential antiviral effect on two different cell lines infected by two SARS-CoV-2 strains. This study revealed a clear correlation between their antiviral property and their efficacy to prevent the SUD/G4 interaction. This correlation supports the choice of SUD/RNA G4 complexes formed during SARS-CoV-2 infection as new antiviral targets (10.1016/j.ejmech.2025.117655)
DOI : 10.1016/j.ejmech.2025.117655
Chromium‐Doped Zinc Gallate Nanoparticles for Enhanced Enzyme‐Linked Immunosorbent Assay Sensitivity: Optimization of Synthesis and Functionalization Strategies for Ultra‐Low IgG Detection
- Ferjaoui Zied
- Liu Jianhua
- Matuszewska Celina
- Chanéac Corinne
- Viana Bruno
- Bouzigues Cédric
- Scherman Daniel
- Mignet Nathalie
- Richard Cyrille
Small Science, Wiley , 2025, 5 (10) . The use of zinc gallate nanoparticles (ZnGa 2 O 4 :Cr 3+ ) (ZGO‐NPs) presents significant potential for improving the sensitivity in enzyme‐linked immunosorbent assays (ELISA). The persistent luminescence signal increase of these nanoparticles in the presence of hydrogen peroxide (H 2 O 2 ) offers advantages for the sensitive detection of biomolecules. Herein, different conditions of ZGO synthesis have been investigated by varying the hydrothermal reaction duration (6, 12, and 24 h) and examining its impact in the presence of H 2 O 2 . These nanoparticles have been integrated into ELISA assays, using as target antigen IgG. The lowest limit of detection (LOD) of 0.2 pg mL −1 is observed for ZGO‐NPs prepared during 12 h (ZGO2), and with a detection range from 1 to 1000 pg mL −1 . The impact of covalently functionalizing these nanoparticles has then been assessed. First using glucose oxidase (GOx) and the detection antibody (Ab D ) linked to PEGylated ZGO‐NPs, named ZGO‐GOx‐Ab D . Alternatively, only the detection antibody is linked to the PEG ZGO‐NPs, named ZGO‐Ab D . The results show a significant lowering of the LOD when using the functionalized ZGO2 NPs and also highlight the impact of the signal amplification by H 2 O 2 . Specifically, when using ZGO2‐GOx‐Ab D incubated with glucose to produce H 2 O 2 , or with ZGO2‐Ab D to which H 2 O 2 was added, the LODs are ≈98 and 56 fg mL −1 respectively, with detection ranges from 0.01 to 100 pg mL −1 . (10.1002/smsc.202500177)
DOI : 10.1002/smsc.202500177
In situ determination and matching of the refractive index of the Human cornea to improve polarization-resolved SHG imaging in depth
- Nyembo Kasongo Poncia
- Mahou Pierre
- Sintès Jean-Marc
- Latour Gaël
- Schanne-Klein Marie-Claire
Biomedical optics express, Optical Society of America - OSA Publishing , 2025, 16 (8), pp.3270-3282 . <div><p>The human cornea is a highly organized tissue, which comprises hundreds of 1-3 µm thick stacked collagen lamellae. However, this microstructure is poorly characterized and requires further investigation. Polarization-resolved second harmonic generation (pSHG) microscopy is a powerful technique for this purpose because of its specificity for collagen and its sensitivity to its orientation. However, pSHG is prone to spatial resolution degradation with depth unless the immersion refractive index is matched to that of the sample, which is critical for corneas that are approximately 600 µm thick. In the absence of experimental data on the refractive index along the entire cornea, we propose a measurement method that applies to the entire cornea directly under the microscope objective. We then use an iodixanol solution to match the refractive index of the immersion medium to that of the cornea. Finally, we carefully characterize the pSHG orientation data obtained under these optimal conditions, and we show that they provide a better resolution along the entire thickness of the cornea and a better determination of the lamellae orientation.</p></div> (10.1364/boe.564209)
DOI : 10.1364/boe.564209
Multiscale characterization of myelin distribution with polarized THG microscopy
- Morizet Josephine
- Olivier Nicolas
- Aigrot Marie-Stephane
- Mahou Pierre
- Martin Elodie
- Desmazieres Anne
- Stankoff Bruno
- Stringari Chiara
- Beaurepaire Emmanuel
Optica, Optical Society of America - OSA Publishing , 2025, 12 (7), pp.1122 . Myelin is essential for axonal conduction and metabolic support. To better understand its role in health and disease, it is necessary to establish accurate methods for in situ mapping of myelin at scales ranging from submicrometer to centimeters. Third-harmonic generation (THG) microscopy has recently been proposed as an efficient label-free method to visualize myelin in thick and living tissue. However, the contrast mechanism of THG from myelinated axons is complex and poorly described, which has limited the development of THG as a quantitative probe of myelin distribution. Here, we present a systematic characterization and modeling of polarization-resolved THG (pTHG) signals from individual axons as a function of their diameter and myelin thickness, and we show that pTHG can be used to derive myelin scores in several biological systems. First, we confirm the sensitivity and specificity of the THG contrast for myelinated axons in mouse brain tissue and its ability to detect isolated micrometer-sized axons oriented both in-plane and out-of-plane. We then present a detailed characterization of the pTHG contrast of small and large axons in live zebrafish larvae at different developmental stages, and we demonstrate that pTHG detects early axon development in vivo. We show that classical models of coherent multiphoton microscopy fail to reproduce pTHG profiles of axons because they neglect myelin-induced optical aberrations, and we establish a numerical strategy based on finite-difference time-domain calculations that can accurately relate pTHG signal profiles to axonal diameter and myelin thickness. Finally, we illustrate the relevance of pTHG microscopy for characterizing myelin distribution at different scales in fixed mouse and human brain tissue. (10.1364/optica.562091)
DOI : 10.1364/optica.562091
Editorial: The metabolic pathways of archaea
- Myllykallio Hannu
- Qin Wei
- Berg Ivan
Frontiers in Microbiology, Frontiers Media , 2025, 16 . (10.3389/fmicb.2025.1648560)
DOI : 10.3389/fmicb.2025.1648560
IgG detection in human serum employing non-functionalized chromium doped zinc gallate nanoparticles
- Ferjaoui Zied
- Zimmer Capucine
- Matuszewska Celina
- Chanéac Corinne
- Viana Bruno
- Bouzigues Cédric
- Scherman Daniel
- Mignet Nathalie
- Richard Cyrille
Next Nanotechnology, Elsevier , 2025, 8, pp.100199 . Chromium-doped zinc gallate (ZnGa2O4:Cr3 +) nanoparticles (ZGO) show promising potential for antigen immunodetection using persistent luminescence, thereby reducing autofluorescence interference. Recently, we have shown that ZGO prepared by hydrothermal treatment at 120°C for 24 h can be used for in vitro biodetection in simple media such as phosphate-buffered saline. In this study, we investigated the effect of the protocol used to synthesize these ZGO nanoparticles, using a hydrothermal treatment at 220°C for different durations (6 h, 12 h, and 24 h), followed by calcination at 500°C. The nanoparticle size determined by transmission electron microscopy after grinding and centrifugation was found to be around 15 nm. The persistent luminescence signal of the ZGO nanoparticles varied with the hydrothermal synthesis conditions. Moreover, in the presence of H2O2, these nanoparticles show a signal enhancement dependent on the hydrothermal duration, with a 12 h treatment showing the highest 8-fold luminescence increase in the presence of H2O2 produced by glucose oxidase mediated glucose degradation. Based on these results, these non-functionalized nanoparticles were successfully used to develop a persistent luminescence-based sandwich immunoassay for autofluorescence-free detection of antigens in undiluted human serum samples, using rabbit IgG as a model antigen. This study highlights the promising potential for biosensing applications of persistent ZGO nanophosphors for IgG detection in a complex medium (undiluted human serum), with a linear range from 1 ng mL−1 to 104 ng mL−1 and a limit of detection of 0.01 ng mL−1. The present optimization of ZGO nanophosphor synthesis offers promising prospects for medical diagnostics due to their increased sensitivity and ability to eliminate autofluorescence interference, as well as their ease of use, since no functionalization of the ZGO NPs is required before use. (10.1016/j.nxnano.2025.100199)
DOI : 10.1016/j.nxnano.2025.100199
Laser driven FLASH radiobiology using a high dose and ultra high dose rate single pulse proton source
- Flacco A
- Bayart E.
- Romagnani L
- Cavallone M.
- de Marzi L.
- Fouillade C
- Giaccaglia C.
- Heinrich S.
- Lamarre-Jouenne I.
- Monzac J.
- Parodi K.
- Patriarca A
- Rösch T
- Schreiber J
- Tischendorf L
Scientific Reports, Nature Publishing Group , 2025, 15, pp.16511 . Laser-driven proton sources have long been developed with an eye on their potential for medical application to radiation therapy. These sources are compact, versatile, and show peculiar characteristics such as extreme instantaneous dose rates, short duration and broad energy spectrum. Typical temporal modality of laser-driven irradiation, the so-called fast-fractionation, results from the composition of multiple, temporally separated, ultra-short dose fractions. In this paper we present the use of a high-energy laser system for delivering the target dose in a single nanosecond pulse, for ultra-fast irradiation of biological samples. A transport line composed by two permanent-magnet quadrupoles and a scattering system is used to improve the dose profile and to control the delivered dose-per-pulse. A single-shot dosimetry protocol for the broad-spectrum proton source using Monte Carlo simulations was developed. Doses as high as 20 Gy could be delivered in a single shot, lasting less than 10 ns over a 1 cm diameter biological sample, at a dose-rate exceeding 10 9 Gy s -1 . Exploratory application of extreme laser-driven irradiation conditions, falling within the FLASH irradiation protocol, are presented for irradiation in vitro and in vivo. A reduction of radiation-induced oxidative stress in vitro and radiation-induced developmental damage compatible with the onset of FLASH effect were observed in vivo, whereas anti-tumoral efficacy was confirmed by cell survival assay. (10.1038/s41598-025-01105-z)
DOI : 10.1038/s41598-025-01105-z
Genome wide analyses reveal the role of mutator phenotypes in Mycobacterium tuberculosis drug resistance emergence
- Zein-Eddine R.
- Le Meur Adrien
- Skouloubris S.
- Jelsbak L.
- Refrégier Guislaine
- Myllykallio Hannu Hannu
npj Antimicrobials and Resistance, Springer Nature , 2025, 3 (1), pp.35 . Antimicrobial combination therapy is widely used to combat Mycobacterium tuberculosis (Mtb), yet resistance rates continue to rise. Mutator strains, with defects in DNA repair genes, drive resistance in other bacterial infections, but their role in Mtb remains unclear. Here, we study the contribution of single nucleotide polymorphisms (SNPs) in DNA Repair, Replication, and Recombination (3 R) genes to Mtb resistance. Through large-scale bioinformatics analysis of 53,589 whole-genomes, we identified 18 novel SNPs in lineages 2 and 4 linked to genotypic drug resistance in 3 R genes, covering 12.5% of clinical isolates with available genome sequences. Notably, a number of the detected SNPs were positively selected during Mtb evolution. Experimental tests showed that mutM, fpgg2, xthA, and nucS mutants had increased the mutation frequency compared to the wild type. Our findings highlight the role of 3 R gene mutations in resistance, emphasizing the need for surveillance to improve early detection and control strategies. (10.1038/s44259-025-00107-1)
DOI : 10.1038/s44259-025-00107-1
Ultra-Specific G-Quadruplex–Colistin Interaction for Efficient Transcriptome-Wide G4 Mapping
- Wei Shijiong
- Zhang Xiaobo
- Feng Yilong
- Tao Shentong
- Qiu Dehui
- Yan Xinrong
- Li Guangming
- Guittat Lionel
- Zhang Wenli
- Monchaud David
- Mergny Jean-Louis
- Ju Huangxian
- Zhou Jun
Journal of the American Chemical Society, American Chemical Society , 2025, 147, pp.9962 - 9971 . G-quadruplexes (G4s) are challenging targets for chemical biology interventions, notably because of their dynamic topological polymorphism. We found that the antibiotic smallmolecule colistin (COL) interacts specifically with a single subtype of G4 structures, the so-called parallel G4s. This interaction triggers the aggregation of the G4/COL complexes in a structure-specific manner, which can thus be separated from the bulk solution by centrifugation. This unprecedented mode of affinity-precipitation was exploited here to design the COL-induced RNA G4 precipitation and sequencing (CoRP-seq) protocol, which allows for the assessment of the prevalence of RNA G4s in the transcriptome of human cells in a straightforward manner. CoRP-seq shines by its ultraspecificity, simplicity, and practical convenience, which thus advances G4 mapping further and addresses unmet needs in the field of G4omics. (10.1021/jacs.5c01172)
DOI : 10.1021/jacs.5c01172
Increasing the Accuracy and Robustness of the CHARMM General Force Field with an Expanded Training Set
- Croitoru Anastasia
- Kumar Anmol
- Lambry Jean-Christophe
- Lee Jihyeon
- Sharif Suliman
- Yu Wenbo
- Mackerell Alexander
- Aleksandrov Alexey
Journal of Chemical Theory and Computation, American Chemical Society , 2025, 21 (6), pp.3044-3065 . <div><p>Small molecule empirical force fields (FFs), including the CHARMM General Force Field (CGenFF), are designed to have wide coverage of organic molecules and to rapidly assign parameters to molecules not explicitly included in the FF. Assignment of parameters to new molecules in CGenFF is based on a trained bond-angledihedral charge increment linear interpolation scheme for the partial atomic charges along with bonded parameters assigned based on analogy using a rules-based penalty score scheme associated with atom types and chemical connectivity. Accordingly, the accuracy of CGenFF is related to the extent of the training set of available parameters. In the present study that training set is extended by 1,390 molecules selected to represent connectivities new to CGenFF training compounds. Quantum mechanical (QM) data for optimized geometries, bond, valence angle, and dihedral angle potential energy scans, interactions with water, molecular dipole moments, and electrostatic potentials were used as target data. The resultant bonded parameters and partial atomic charges were used to train a new version of the CGenFF program, v5.0, which was used to generate parameters for a validation set of molecules, including drug-like molecules approved by the FDA, which were then benchmarked against both experimental and QM data. CGenFF v5.0 shows overall improvements with respect to QM intramolecular geometries, vibrations, dihedral potential energy scans, dipole moments and interactions with water. Tests of pure solvent properties of 216 molecules show small improvements versus the previous release of CGenFF v2.5.1 reflecting the high quality of the Lennard-Jones parameters that were explicitly optimized during the initial optimization of both the CGenFF and the CHARMM36 force field. CGenFF v5.0 represents an improvement that is anticipated to more accurately model intramolecular geometries and strain energies as well as non-covalent interactions of drug-like and other organic molecules.</p></div> (10.1021/acs.jctc.5c00046)
DOI : 10.1021/acs.jctc.5c00046
Nance-Horan-Syndrome-like 1b controls mesodermal cell migration by regulating protrusion and actin dynamics during zebrafish gastrulation.
- Escot Sophie
- Hassanein Yara
- Elouin Amélie
- Torres-Paz Jorge
- Mellottee Lucille
- Ignace Amandine
- David Nicolas B
Communications Biology, Nature Publishing Group , 2025, 8 (1), pp.328 . Cell migrations are crucial for embryonic development, wound healing, the immune response, as well as for cancer progression. In most cells, the RAC1/Arp2/3/WAVE signalling pathway induces branched actin polymerisation, which protrudes the membrane and allows migration. Fine-tuning the activity of the RAC1/Arp2/3/WAVE complex modulates protrusion lifetime and migration persistence. Recently, NHSL1, a novel interactor in this complex has been identified as a negative regulator of cell migration in vitro. We here analysed its function in vivo, during zebrafish gastrulation, as nhsl1b is specifically expressed in migrating mesodermal cells. Loss and gain of function experiments revealed that nhsl1b is required for the proper migration of the mesoderm, controlling cell speed and migration persistence. Consistent with a role in regulating actin dynamics, Nhsl1b localises to the tip of actin-rich protrusions. However, in contrast to the in vitro situation, it appears to be a positive regulator of migration, with its loss of function reducing the length and lifetime of protrusions, whereas overexpression has the opposite effect. These results reveal that the effects of actin modulators depend on the cellular context, and highlight the importance of analysing their function in physiological contexts. (10.1101/2023.01.28.526006)
DOI : 10.1101/2023.01.28.526006
Fast and Efficient Red‐absorbing Photoswitching Proteins Based on Flavin–Ligand Charge Transfer Complexes
- Zhuang Bo
- Liebl Ursula
- Vos Marten
- Sliwa Michel
ChemPhotoChem, Wiley , 2025 . Recently a novel class of reversible protein photoswitches has been discovered that is based on a charge transfer (CT) complex composed of the flavin cofactor and a substrate‐analogue inhibitor molecule in the family of sarcosine oxidase flavoproteins. Here, excitation of the CT band results in barrierless dissociation of the CT complex on the femtosecond timescale followed by its thermally activated reformation, on the timescale of a few nanoseconds at ambient temperature. The photoreaction is thought to involve a well‐defined isomerization of the inhibitor without its dissociation from the protein. This reaction occurs with an unusually high quantum yield (~80%), is initiated by absorption in the red part of the visible absorption spectrum, and leads to a photoproduct absorbing in the blue spectral region (negative photochromism). Therefore, this class of photoswitches can be considered a promising template for developing a new class of fast negative photochromic compounds for Life Science applications provided the lifetime of the photoproducts (‘light state’) can be prolonged. Potential future developments will be discussed. (10.1002/cptc.202500012)
DOI : 10.1002/cptc.202500012
Understanding the key challenges in tuberculosis drug discovery: what does the future hold?
- Zein-Eddine Rima
- Ramuz Masoud
- Refrégier Guislaine
- Lutzeyer Johannes F
- Aleksandrov Alexey
- Myllykallio Hannu
Expert Opinion on Drug Discovery, Informa Healthcare , 2025, 20 (9), pp.1115-1130 . Introduction: Tuberculosis (TB), caused by Mycobacterium tuberculosis (Mtb), remains a major global health concern. It spreads through airborne droplets and has a high mortality rate, particularly without treatment. Drug resistance is rising, with treatments against multidrug-resistant TB (MDR-TB) showing poor treatment success rates. The thick, lipid-rich wall of Mtb and its slow growth reduce antibiotic effectiveness, requiring long treatment courses of 4-6 months. Current therapies often fail against drugresistant strains, highlighting the urgent need for new, short-course treatment, affordable, and combination-friendly drugs. Areas covered: Within this perspective, the authors review and comment on the following topics regarding Mtb resistance emergence and treatment strategies: i) Existing treatment ii) Resistance evolution in Mtb; iii) Key challenges in drug discovery targeting Mtb; iv) emerging strategies and recent advances in Mtb drug discovery, and v) Next-generation approaches. Literature was identified through a search of PubMed, google scholar, and web of science, from January 2010 to March 2025. Expert opinion: AI is accelerating the discovery of bioavailable and safe preclinical drug candidates for TB, though data limitations and biological complexity remain challenging. Future progress requires multi-modal models, open-access datasets, and interdisciplinary collaboration. (10.1080/17460441.2025.2531229)
DOI : 10.1080/17460441.2025.2531229
G-quadruplexes are promoter elements controlling nucleosome exclusion and RNA polymerase II pausing
- Esnault Cyril
- Zine El Aabidine Amal
- Robert Marie-Cécile
- Cucchiarini Anne
- Magat Talha
- Pigeot Alexia
- Bouchouika Soumya
- Garcia-Oliver Encar
- Gawron Kevin
- Basyuk Eugénia
- Karpinska Magdalena A
- Kozulic-Pirher Alja
- Luo Yu
- Verga Daniela
- Mourad Raphael
- Radulescu Ovidiu
- Mergny Jean-Louis
- Bertrand Edouard
- Andrau Jean-Christophe
Nature Genetics, Nature Publishing Group , 2025, 57 (8), pp.1981-1993 . Despite their central role in transcription, it has been difficult to define universal sequences associated to eukaryotic promoters. Within chromatin context, recruitment of the transcriptional machinery requires promoter opening but how DNA elements could contribute to this process is unclear. Here, we show that G-quadruplex (G4) secondary DNA structures are highly enriched at mammalian promoters. G4s are located at the deepest point of nucleosome exclusion at promoters and correlate with maximum promoter activity. We found that experimental G4s exclude nucleosomes in vivo and in vitro while favouring strong positioning. At model promoters, impairing G4s affected both transcriptional activity and chromatin opening. G4 destabilization also resulted in an inactive promoter state and affected transition to effective RNA production. Finally, G4 stabilization resulted in global reduction of proximal promoter pausing. Altogether, our data introduce G4s as bona fide promoter elements allowing nucleosome exclusion and facilitating pause release by the RNA Polymerase II. (10.1038/s41588-025-02263-6)
DOI : 10.1038/s41588-025-02263-6
The Mappa mundi of Albi: Insight into the manufacturing, life and conservation state of an 8th century world map
- Robinet Laurianne
- Heu-Thao Sylvie
- Galante Giulia
- Latour Gaël
- Tournié Aurélie
- Daher Céline
- Dan Anca
- Schanne-Klein Marie-Claire
- Michelin Anne
- Deschaux Jocelyne
Journal of Cultural Heritage, Elsevier , 2025, 74, pp.341-352 . The Mappa mundi of Albi is one of the oldest examples of spatial representation of the Western world. The small map conserved on the verso of folio 57 in manuscript 29 of the Médiathèque Pierre Amalric in Albi (France) was drawn on parchment, probably made in the second half of the 8th century, somewhere between south-western France and northern Spain, maybe in Albi itself. Because of its exceptional importance for the history of space representation, the map, together with the Index of seas and winds facing it, on the recto of folio 58, was recorded in the UNESCO Memory of the World Register in 2015. The detailed study published here has examined the manuscript’s structure and characterised the different constitutive materials. Observations and physicochemical analyses were performed on the map and the index, from the micro to the macroscale, combining optical microscopy, XRF, FORS, FTIR, and micro-Raman spectroscopy, hyperspectral imaging, proteomic analysis, and non-linear optical microscopy. Three manuscripts conserved at the same library or suspected to have been produced in the scriptorium of Albi have also been examined for comparisons. This material investigation complements the historical studies of the map by shedding new light on the manufacturing, life, and conservation state of this exceptional document. (10.1016/j.culher.2025.05.013)
DOI : 10.1016/j.culher.2025.05.013
A Chimeric Photo-Controllable CRISPR/Cas12a System for Universal and Fast Diagnostics
- Yan Xinrong
- Liu Bin
- Zhou Shuguang
- Fan Yanjun
- Wei Shijiong
- Qiu Dehui
- Xiang Henglong
- Zhou Jiahang
- Mergny Jean-Louis
- Monchaud David
- Ju Huangxian
- Zhou Jun
Analytical Chemistry, American Chemical Society , 2025, 97 (44), pp.24634 - 24642 . The potential of clustered regularly interspaced short palindromic repeats (CRISPR) and corresponding CRISPR-associated (Cas) protein systems (CRISPR/Cas) systems for biomedical applications is tremendous; however, precise control of their activity is essential to better harness this potential and, beyond this, to develop reliable diagnostic reagents. Herein, we report on such a strategy by controlling the CRISPR/Cas12a activity using a photo-controllable CRISPR RNA (crRNA). To this end, the 3′ end of crRNA was conjugated to a G-quadruplex (G4) block through a photocleavable linker: upon photo irradiation, the G4 trigger is removed, thus allowing for the DNA target to access and hybridize with the crRNA, and thus be processed by the CRISPR/Cas12a system. The efficiency of this approach was demonstrated by the detection of human papillomavirus 16 DNA in 50 clinical samples: our one-pot strategy was found to be as efficient as the routinely implemented method (qPCR), with 95.7% sensitivity and 100% specificity, in addition to be faster (25 versus 60 min) and both simpler and less expensive (being implementable as lateral flow test strips). Collectively, this new and fully controllable CRISPR/Cas system holds great potential for next-generation clinical diagnostics. (10.1021/acs.analchem.5c04782)
DOI : 10.1021/acs.analchem.5c04782
Intrinsic variation of the polarization-resolved SHG from collagen: Multiscale analysis and application to parchments
- Galante Giulia
- Robinet Laurianne
- Heu-Thao Sylvie
- Caporal Clément
- Latour Gaël
- Schanne-Klein Marie-Claire
APL Photonics, AIP Publishing LLC , 2025, 10 (5), pp.056106 . Second harmonic generation (SHG) microscopy is nowadays the gold standard technique for collagen structural imaging in intact tissues with sub-micrometer resolution. This multiphoton modality can be combined with polarimetry to provide key information about the 3D hierarchical organization of collagen. Notably, the so-called anisotropy parameter processed from polarization-resolved SHG (P-SHG) has been shown to vary with the orientational disorder of the fibrils within the focal volume and with their out-of-plane orientation. However, analytical equations describing both effects within the same formalism are still lacking. In this work, we present a unified multiscale theoretical approach of the intrinsic variations of the anisotropy parameter. We then measure these variations in the very same collagen samples to ensure reliable comparisons. To that end, we use parchments, which are materials made from animal skins and which contain almost exclusively collagen. These parchments are manufactured in different ways to obtain different collagen distributions. Our series of measurements exhibit a good agreement with our theoretical approach, which shows the relevance of P-SHG measurements to probe collagen multiscale organization in tissues. (10.1063/5.0250484)
DOI : 10.1063/5.0250484
Synthesis of new 1,3-bis[(4-(substituted-aminomethyl)phenyl)methyl]benzene and 1,3-bis[(4-(substituted-aminomethyl)phenoxy)methyl]benzene derivatives, designed as novel potential G-quadruplex antimalarial ligands
- Albenque-Rubio Sandra
- Guillon Jean
- Agnamey Patrice
- Damiani Céline
- Savrimoutou Solène
- Ronga Luisa
- Hanot Marie
- Zangmo Tshering
- Pinaud Noël
- Moreau Stéphane
- Mergny Jean-Louis
- Marchivie Mathieu
- Moukha Serge
- Estela Fabienne
- Dozolme Pascale
- Cohen Anita
- Sonnet Pascal
Drugs and Drug Candidates, MDPI , 2025, 4 (3), pp.39 . Background: Based on our previously reported series of novel 1,3,5-tris[(4-(substituted-aminomethyl)phenyl)methyl]benzene and 1,3,5-tris[(4-(substituted-aminomethyl)phenoxy)methyl]benzene derivatives, we have now designed, synthesized, and tested a new series of novel restricted and simplified structural analogues of these compounds against Plasmodium falciparum in vitro; i.e., the 1,3-bis[(4-(substituted-aminomethyl)phenyl)methyl]benzene and 1,3-bis[(4-(substituted-aminomethyl)phenoxy)methyl]benzene compounds. Methods & results: The pharmacological results revealed significant antimalarial activity, with IC50 values in the submicromolar to micromolar range. Additionally, the in vitro cytotoxicity of these new nitrogen-containing polyphenyl- or -phenoxymethylbenzene compounds was evaluated on human HepG2 cells. The compound 1f, the 1,3-bis[(4-(3-(morpholin-1-yl)propyl)aminomethyl)phenoxy)methyl]benzene derivative, emerged as one of the most potent and promising antimalarial candidates, demonstrating a cytotoxicity/antiprotozoal activity ratio of 594 against the chloroquine-sensitive Plasmodium falciparum 3D7 strain. Additionally, the 1,3-bis[((substituted aminomethyl)phenyl)methyl]benzene compound 1j and the 1,3-bis[((substituted aminomethyl)phenoxy)methyl]benzenes 2p and 2q also showed strong antimalarial potential, with selectivity indexes (SI) of over 303, 280, and 217, respectively, against the 3D7 strain, which has mefloquine-reduced sensitivity. Furthermore, the 1,3-bis[(4-(pyridin-2-ylethylaminomethyl)phenyl)methyl]benzene 2k was identified as the most noteworthy antimalarial compound, exhibiting a selectivity index (SI) that was superior to 178 against the chloroquine-resistant Plasmodium falciparum W2 strain. It has previously been suggested that the telomeres of P. falciparum may serve as potential targets for these polyaromatic compounds; thus, we assessed the ability of our novel derivatives to stabilize parasitic telomeric G-quadruplexes using a FRET melting assay. Conclusions: However, regarding the stabilization of the protozoan G-quadruplex, it was noted that the few substituted derivatives, which showed interesting stabilization profiles, were not necessarily the most effective antimalarial compounds against both Plasmodium strains. Moreover, these new compounds did not show promising stabilizing effects on the different G4 sequences. Therefore, no correlation arises between their antimalarial activity and the selectivity of their binding to G-quadruplexes. (10.3390/ddc4030039)
DOI : 10.3390/ddc4030039
Mechanism of Ultrafast Flavin Photoreduction in the Active Site of Flavoenzyme LSD1 Histone Demethylase
- Zhuang Bo
- Ramodiharilafy Rivo
- Aleksandrov Alexey
- Liebl Ursula
- Vos Marten H
Chemical Science, The Royal Society of Chemistry , 2025, 16, pp.338 - 344 . Photoreduction of oxidized flavins has a functional role in photocatalytic and photoreceptor flavoproteins. In flavoproteins without light-dependent physiological functions, ultrafast, reversible flavin photoreduction is supposedly photoprotective by nature, and holds potential for nonnatural photocatalytic applications. In this work, we combine protein mutagenesis, ultrafast spectroscopy, molecular dynamics simulations and quantum mechanics calculations to investigate the nonfunctional flavin photoreduction in a flavoenzyme, lysine-specific demethylase 1 (LSD1) which is pivotal in DNA transcription. LSD1 harbors an oxidized flavin adenine dinucleotide (FAD) cofactor and multiple electron-donating residues in the active site. Upon photoexcitation, the FAD cofactor is photoreduced in < 200 fs by electron transfer (ET) from nearby residue(s), and the charge pairs recombine in ca. 2 ps. Site-directed mutagenesis pinpoints a specific tryptophan residue, W751, as the primary electron donor, whereas a tyrosine residue, Y761, despite being located closer to the flavin ring, does not effectively contribute to the process. Based on a hybrid quantum–classical computational approach, we characterize the W751–FAD and Y761–FAD charge-transfer states (CTW751 and CTY761, respectively), as well as the FAD locally excited state (LEFAD), and demonstrate that the coupling between LEFAD and CTW751 is larger than those involving CTY761 by an order of magnitude, rationalizing the experimental observations. More generally, this work highlights the role of the intrinsic protein environment and details of donor–acceptor molecular configurations on the dynamics of short-range ET involving a flavin cofactor and amino acid residue(s). (10.1039/D4SC06857B)
DOI : 10.1039/D4SC06857B
Ultrafast dynamics of the UV-induced electronic relaxation in DNA guanine-thymine dinucleotides: from the Franck-Condon states to the minima of the potential energy surfaces
- Petropoulos Vasilis
- Martinez-Fernandez Lara
- Uboldi Lorenzo
- Maiuri Margherita
- Cerullo Giulio
- Balanikas Evangelos
- Markovitsi Dimitra
Physical Chemistry Chemical Physics, Royal Society of Chemistry , 2025 . We study the DNA dinucleotide 5’-dGpdT-3’ (abbreviated as GT) as a model system for the relaxation of the electronic excited states in stacked nucleobases. Quantum chemistry calculations determine the Franck-Condon... (10.1039/D5CP00788G)
DOI : 10.1039/D5CP00788G
Factors Affecting the Population of Excited Charge Transfer States in Adenine/Guanine Dinucleotides: A Joint Computational and Transient Absorption Study
- Petropoulos Vasilis
- Martinez-Fernandez Lara
- Uboldi Lorenzo
- Maiuri Margherita
- Cerullo Giulio
- Balanikas Evangelos
- Markovitsi Dimitra
Biomolecules, MDPI , 2024, 14 (12), pp.1548 . There is compelling evidence that the absorption of low-energy UV radiation directly by DNA in solution generates guanine radicals with quantum yields that are strongly dependent on the secondary structure. Key players in this unexpected phenomenon are the photo-induced charge transfer (CT) states, in which an electric charge has been transferred from one nucleobase to another. The present work examines the factors affecting the population of these states during electronic relaxation. It focuses on two dinucleotides with opposite orientation: 5′-dApdG-3′ (AG) and 5′-dGpdA-3′ (GA). Quantum chemistry calculations determine their ground state geometry and the associated Franck–Condon states, map their relaxation pathways leading to excited state minima, and compute their absorption spectra. It has been shown that the most stable conformer is anti-syn for AG and anti-anti for GA. The ground state geometry governs both the excited states populated upon UV photon absorption and the type of excited state minima reached during their relaxation. Their fingerprints are detected in the transient absorption spectra recorded with excitation at 266 nm and a time resolution of 30 fs. Our measurements reveal that in the large majority of dinucleotides, chromophore coupling is already operative in the ground state and that the charge transfer process occurs within ~120 fs. The competition among various relaxation pathways affects the quantum yields of the CT state formation in each dinucleotide, which are estimated to be 0.18 and 0.32 for AG and GA, respectively. (10.3390/biom14121548)
DOI : 10.3390/biom14121548