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Category: chemistry

Cellular reprogramming beyond pluripotency

Aging, once viewed as an irreversible process, is now considered a modifiable process. Recent advances in cellular reprogramming reveal that transient expression of reprogramming factors can reverse molecular hallmarks of aging while preserving somatic cell identity. This ‘partial reprogramming’ rejuvenates tissues, restores regenerative capacity, and, in some models, extends lifespan without the tumorigenic risks of full dedifferentiation. In this review, we summarize genetic and chemical strategies for partial reprogramming, discuss their tissue-specific effects in vivo, and evaluate their implications for tissue regeneration and age-related disease. We further examine key challenges for clinical translation, including safety, delivery strategies, and temporal control of reprogramming.

Astronomers discover Andromeda XXXVI, an ultra-faint dwarf satellite galaxy

By analyzing the data from the Pan-Andromeda Archaeological Survey (PandAS), European astronomers have discovered a new satellite of the Andromeda galaxy. The newfound object, which received the designation Andromeda XXXVI, appears to be an ultra-faint dwarf galaxy. The finding is reported in a paper published March 30 on the arXiv preprint server.

The so-called ultra-faint dwarf galaxies (UFDs) are the least luminous, most dark matter-dominated, and least chemically evolved galaxies known. Therefore, they are perceived by astronomers as the best candidate fossils from the universe at its early stages.

Now, a team of astronomers, led by Joanna D. Sakowska of the Institute of Astrophysics of Andalusia in Spain, reports the finding of a new UFD. Andromeda XXXVI was first spotted and classified as a candidate UFD by amateur astronomer Giuseppe Donatiello during a systematic, visual inspection search of public images from the full PAndAS footprint. Sakowska and her colleagues recently performed follow-up deep imaging of Andromeda XXXVI with the Roque de los Muchachos Observatory, which confirmed the UFD nature of this galaxy.

Light-driven method enables sustainable production of porous semiconducting polymers

Researchers at Koç University have developed a light-driven method to produce porous semiconducting polymers under ambient conditions without the need for metal catalysts. The study, led by Prof. Dr. Önder Metin from the Department of Chemistry, in collaboration with Dr. Melek Sermin Özer, Dr. Zafer Eroğlu, and Prof. Dr. Sermet Koyuncu, was published in Nature Communications.

Porous semiconducting organic polymers have attracted growing attention due to their high thermal and chemical stability, as well as their tunable structures. With a high density of molecular-scale pores, these materials exhibit strong charge transport and light-harvesting capabilities, making them promising for applications ranging from gas storage and energy technologies to photocatalysis and optoelectronics.

However, conventional synthesis methods are often complex, costly, and difficult to scale. They typically require high temperatures, expensive metal catalysts, and multi-step reaction processes, limiting their broader applicability.

Martian Dust Storms Create Electric Chemical Reactions

“This research sheds light on an important facet of modern Mars: the interaction of the atmosphere and the surface,” said Dr. Paul Byrne. [ https://www.labroots.com/trending/space/30400/martian-dust-s…eactions-2](https://www.labroots.com/trending/space/30400/martian-dust-s…eactions-2)

How does static electricity shape the surface of Mars? This is what a recent study published in Earth and Planetary Science Letters hopes to address as an international team of scientists investigated atmosphere-surface interactions on Mars, specifically regarding electrostatic discharge, or static electricity. This study has the potential to help scientists better understand atmosphere-surface interactions on planetary bodies and how this could help find life beyond Earth.

For the study, the researchers conducted a series of laboratory experiments to simulate how dust storms and dust devils on Mars could trigger the production of compounds like perchlorates and carbonates within the Martian regolith (often mistakenly called “soil”) and hydrochloric acid (HCl) in the atmosphere. The motivation for the study was to gain insight into how planets work, specifically regarding their geological activity.

In the end, the researchers found that static electricity from Martian dust activities are responsible for producing perchlorates and carbonates in the Martian regolith and HCl in the Martian atmosphere. The study’s results were compared with real-world data obtained from the European Space Agency’s ExoMars Trace Gas Orbiter and NASA’s Curiosity rover for atmospheric and surface data, respectively.

Fluorescence imaging technique reveals hidden magnetic chemistry in living systems

A research team at the University of Tokyo has developed a new microscopy platform that can observe a previously hidden layer of biomolecular chemistry linked to weak magnetic fields. The work, led by Project Researcher Noboru Ikeya and Professor Jonathan R. Woodward at the Graduate School of Arts and Sciences, addresses a long-standing technical gap in life-science measurement: Many important intermediates in spin-dependent reactions are “dark” molecules that do not emit light directly and therefore escape conventional fluorescence imaging.

To solve this, the team combined two precisely timed light pulses with a synchronized nanosecond magnetic pulse. The approach, called pump-field-probe fluorescence microscopy, compares signals as the magnetic field switches at different points in time. This comparison isolates the spin-dependent part of the chemistry and reveals precisely how magnetically sensitive intermediates appear and disappear. The findings are published in the Journal of the American Chemical Society.

The researchers validated the method in flavin-based model systems that are widely used to study biologically relevant photochemistry. They showed that the platform can recover reaction lifetimes and magnetic responses with high sensitivity, including at low concentrations matching cellular conditions. The system was capable of detecting very small signal changes under practical low-damage single-experiment per frame settings, an important step toward future live-cell studies.

Advancing synthetic cells: A more flexible system to replicate cellular functions

Creating artificial systems that mimic the functioning of cells is one of the goals of what is known as synthetic biology. These models, known as synthetic or biomimetic cells, allow some of the basic processes of life to be reproduced in the laboratory to better understand how natural cells work and develop new technologies. In this context, a study involving a team of researchers from the Center for Research in Biological Chemistry and Molecular Materials (CiQUS) of the University of Santiago (USC) proposes a more flexible chemical strategy to create this type of system.

The objective, explain the researchers, is to design structures that mimic certain cellular functions and that can be used as small chemical reactors. The study is published in the Journal of the American Chemical Society.

“The idea is to try to replicate cellular functions at the level of encapsulation of communication enzymes,” explains researcher Lucas García, referring to artificial systems capable of recreating processes that in real cells allow, for example, different reactions to take place within the same compartment.

Stitching precise patterns—with lasers

Just as embroiderers, with needle and thread, can transform plain fabric into an intricate pattern, engineers can use lasers and polymers to create flexible, complex structures that could transform life-saving sensing technology. An interdisciplinary team at the University of Pittsburgh’s Swanson School of Engineering has developed a new manufacturing strategy that reveals where and how laser-induced graphene (LIG) forms on polymers.

The research opens new opportunities for flexible microelectrodes and neurochemical biosensors.

“Miniaturizing Laser-Induced Graphene for Biosensors by Spatial Control of Initiation and Side-Selective Microfabrication on Commercial Polymers” was selected as a cover feature in Issue 7 of the Advanced Materials Technologies, published in April 2026.

New detector triples the speed of electron camera, enabling higher sensitivity

An instrument that uses high-energy electrons to take “snapshots” of ultrafast chemical processes at the atomic and molecular level just got a major upgrade. Researchers have conducted the first experiment using a new detector, installed in the megaelectronvolt ultrafast electron diffraction (MeV-UED) instrument, at the Linac Coherent Light Source (LCLS) at the Department of Energy’s SLAC National Accelerator Laboratory.

This detector is the first to keep pace with the MeV-UED’s maximum electron production rate of 1,080 electron pulses per second. Compared to the previous detector’s maximum rate, the new detector collects three times more data over the same time span, drastically improving the instrument’s efficiency and sensitivity.

“With this new detector, we’re able to read out each individual pulse of electrons from the instrument,” said Alexander Reid, MeV-UED facility director. “That gives us a much more powerful way of examining the experimental data to answer our science questions.”

Advancements in organoid models emulating metastatic niches

Metastatic niche in organoid models.

The mortality rate of cancer patients remains high, mainly due to the lack of metastasis-tailored treatments, highlighting the need for alternative experimental approaches that capture metastatic development in a human context.

Human-induced pluripotent stem cell derived organoids cocultured with cancer cells (‘chimeroids’) have the potential to emulate aspects of colonized organ specific microenvironments and offer an alternative platform for target identification and drug discovery, as these models are amenable to scalable genetic and chemical perturbation screens.

Conceptually, organoid models have progressed from epithelial-only organoids to multilineage, niche enriched systems incorporating stromal, vascular, and tissue-resident immune components, thereby bringing in vitro models closer to organ-specific metastatic microenvironments.

Yet no single organoid model fully recapitulates the entire complexity of an organ in vivo; thus, model selection must be driven by the specific scientific question, ensuring that the relevant stage of metastatic development and organ microenvironment are appropriately represented. ScienceMission sciencenewshighlights https://sciencemission.com/organoid-models-emulating-metastatic-niches

Metastases cause most cancer-related deaths, underscoring the need for therapies targeting metastatic stages, including the tumor microenvironment. Yet translating biological insights into treatments remains difficult. Preclinical metastasis research largely relies on rodent models, which have species-specific limitations and are incompatible with large-scale perturbation screens in a human context. Human organoids aim to emulate organ microenvironments in vitro and, when cocultured with cancer cells, can provide complementary models. These ‘chimeroids’ may enable scalable studies of cancer–microenvironment interactions and support genetic and pharmacological screens to discover new targets, offering insights into the final, often lethal step of metastasis—tissue colonization.

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Restoring mitochondrial function in dendritic cells to treat cancer

To counteract this effect, researchers introduced dendritic cells with high mitochondrial activity into tumors in preclinical mouse models, restoring immunogenic activity and improving tumor control.

Immunotherapies for cancer, such as immune checkpoint blockade, have greatly improved care for many malignancies, but have not been successful in all cancers. To determine if their findings could help make immunotherapy more effective in tumor-bearing mice, the investigators compared the therapeutic effects of administering dendritic cells with high mitochondrial activity in combination with immune checkpoint blockade with those of either treatment alone.

“We saw the most pronounced therapeutic effect in mice treated with the combination of dendritic cells that had high mitochondrial activity and immune checkpoint blockade,” said co-first author. “Those combinations synergistically slowed or stopped tumor growth and extended survival far more than either treatment alone.”

To test one combination therapy’s long-term effects, the researchers exposed treated mice to a new tumor months later. Those mice also stopped the new tumor’s growth, indicating durable, long-term immune memory was successfully established.

To better understand the relationship between mitochondrial function and dendritic cells, the researchers examined key metabolic pathways affected by the tumor microenvironment. They identified a signaling axis composed of two proteins, OPA1 and NRF1, that regulate communication between mitochondria and the nucleus. Their expression was greatly downregulated in dendritic cells during tumor progression. Within tumors, that circuit’s downregulation acts as a metabolic switch, in effect telling the cell that it is in an energy crisis, leading dendritic cells to shut down their nonessential functions, including immunogenic activity. Science Mission sciencenewshighlights.

Scientists have discovered how tumors disable immune “gatekeeper” cells that alert the rest of the immune system to the presence of cancer — and how restoring their energy production can improve immunotherapy. Dendritic cells activate the cytotoxic immune cells that destroy cancer. The researchers found that tumors reduce dendritic cell function by decreasing their mitochondrial fitness, thus preventing formation of the anticancer immune response.

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