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Category: biotech/medical – Page 3

The cytokine TNF is a driver of rheumatoid arthritis, but the signaling-pathway details remain incomplete

Here, Sarah Gaffen & team report on the noncanonical RNA binding protein Arid5a as an activator of TNF signaling that is elevated in human RA tissues. And in mice… its loss results in resistance to collagen-induced arthritis:

The figure shows TNF stimulation causes Arid5a accumulation in the cytoplasm in a murine stromal fibroblast cell line untreated (left) and treated (right); Arid5a (red); RPL7A (green); nuclei (blue).

1Division of Rheumatology & Clinical Immunology, Department of Medicine, University of Pittsburgh, Pittsburgh, Pennsylvania, USA.

2BIOCEV, First Faculty of Medicine, Charles University, Vestec, Czech Republic.

3School of Medicine, Tsinghua Medicine, Tsinghua University, Beijing, China.

An organ-conformal, kirigami-structured bioelectronic patch for precise intracellular delivery

Now online! Organ-level localized delivery is a long-standing challenge, especially for gene therapy. This study establishes a universal conformality theory that enables POCKET—a kirigami-structured bioelectronic patch—to integrate seamlessly with organs and realize precise intracellular electro-delivery of therapeutics without off-target effects.

Bitly: Among adults with treatment-refractory

HER2-positive BiliaryTractCancer, zanidatamab produced sustained, meaningful clinical responses and extended survival compared to prior standards.

In patients with immunohistochemistry (IHC) 3+ tumors, response rates and overall survival were notably higher than those with IHC 2+ tumors, substantiating the use of reflex IHC testing to identify candidates for HER2-targeted therapy.

Safety remained consistent over 33 months of follow-up, and the ongoing HERIZON-BTC-302 phase 3 trial is assessing zanidatamab alongside first-line standard care in this setting.

This is a 404 error, which means you’ve clicked on a bad link or entered an invalid URL. Maybe what you are looking for can be found at Bitly.com. P.S. Bitly links are case sensitive.

Brain Scans Reveal an “Inflamed Brain Type” Across Major Psychiatric Disorders

Individuals with psychiatric disorders exhibiting seemingly similar symptoms often respond very differently to the same treatment, suggesting that distinct biological processes are at work beneath the surface of similar clinical presentations. Researchers have now identified a distinct immuno-inflammatory biomarker across major psychiatric disorders that can be detected using non-invasive brain imaging. Patients exhibiting this brain signature showed systemic inflammation and poorer response to standard treatments. The findings of the new study in Biological Psychiatry, published by Elsevier, lay the foundation for a biology-augmented diagnostic framework in psychiatry and detail the potential for biomarker-guided, anti-inflammatory precision therapies.

Neuroimaging links diverse biological mechanisms to clinical manifestations, providing compelling insights into the neural mechanisms underlying brain function implicated in psychiatric diseases. Through neuroimaging, shared neural correlates have been increasingly identified across major psychiatric disorders such as schizophrenia, major depressive disorder, and bipolar disorder. While subtypes within and across psychiatric diagnoses have been identified, the biological underpinnings remain unclear. This study aimed to uncover these hidden “biotypes,” focusing particularly on brain inflammation—a mechanism thought to drive illness in a subset of patients, but which is difficult to measure directly in the living brain.

The research was conducted in two independent cohorts. In the first stage, brain connectivity scans were combined with blood-based molecular (DNA methylation) data to identify a brain network pattern linked to immune system dysfunction. In the second longitudinal stage, investigators validated that patients with this brain marker had higher blood inflammation indices—such as neutrophil-to-lymphocyte ratios—and showed less improvement with conventional treatments during hospitalization.

Different Autism Mutations Can Lead to Similar Brain Changes

The shared pathways were linked to neuron maturation, synapse formation, and the control of gene activity. Further analysis pointed to a group of genes involved in organizing DNA and regulating which genes are switched on or off. These genes sit high in the regulatory chain, influencing many downstream processes previously linked to autism.

To test whether this network played an active role, the team reduced the activity of several key regulators using CRISPR-based methods in neural cells. This led to downstream changes similar to those seen in the autism models.

However, organoids from individuals with idiopathic autism showed less consistent changes, likely reflecting the complex and distributed genetic risk seen in most autism cases.

CLN3 mediates chloride efflux from lysosomes

Lysosomes degrade damaged organelles and macromolecules to recycle nutrient components. Lysosomal storage diseases (LSDs) are linked to mutations of genes encoding lysosomal proteins and may lead to age-related disorders, including neurodegenerative diseases. But, how lysosomal dysfunction contributes to neurodegenerative diseases is not clear yet…

The researchers identify CLN3 (ceroid lipofuscinosis, neuronal 3), linked to Batten disease as a conserved lysosomal protein that regulates lysosomal chloride homeostasis, pH, and protein degradation.

Curcumin analog C1 is a natural compound with anti-inflammatory properties could enhance CLN3 activity and improve lysosomal function by activating TFEB. sciencenewshighlights ScienceMission https://sciencemission.com/CLN3-n-chloride-efflux-n-lysosomes

Wang et al. identify CLN3 as a conserved lysosomal protein that regulates lysosomal chloride homeostasis, pH, and protein degradation. Transcription factor EB (TFEB) activation enhances CLN3 function, revealing the TFEB-CLN3 signaling axis as a promising therapeutic target for lysosomal storage disorders.

Resolving DNA origami structural integrity and pharmacokinetics in vivo

Impressive leap forwards for DNA origami: an elegant staple strand proximity ligation method for tracking DNA origami pharmacokinetics in vivo! This approach even allows analysis of stability of subregions within a DNA origami nanostructure. I think DNA origami has a lot of therapeutic potential, so it is exciting to see this solution to one of its translational barriers. Link: https://www.nature.com/articles/s41565-025-02091-z Paper title: “Resolving DNA origami structural integrity and pharmacokinetics in vivo”

Using origami samples in test tubes, we sequentially performed ligation, PCR and polyacrylamide gel electrophoresis (PAGE; Fig. 2a). For both Wrod and Lrod, amplification bands appeared only after ligation (Supplementary Fig. 3) and matched the sizes of single-LSP controls (Fig. 2d, g). When the origami was heat denatured before ligation, no LSP bands were detected (Fig. 2e, h), confirming that proximity ligation requires intact structures. By contrast, we showed that scaffold-targeted qPCR or origamiFISH assays37,38 still detected DNA regardless of the structural state (Fig. 2e, h), emphasizing their inability to distinguish intact origami from degraded origami.

Previous studies have shown that the coating of DNA nanostructures with the oligolysine-PEG polymer can protect them against nucleases and denaturation in low-salt environments, potentially increasing their stability in vivo23. Since PEGylation confers a physical barrier for the interaction of enzymes with DNA helices, we hypothesized that the ligase might also have decreased accessibility to PEGylated origamis. However, our in vitro experiments with PEGylated PEG-Lrod showed comparable ligation and amplification efficiencies to the bare Lrod (Supplementary Fig. 4). Another approach to enhance lattice-based origami stability in low-salt buffers and improved resistance to nucleases is sequence-specific covalent UV crosslinking26. We tested the application of the PLASTIQ protocol to a crosslinked version of the Lrod (UV-Lrod) with the same LSPs as Lrod. We observed a similar amplification pattern when compared to the non-crosslinked Lrod after PAGE electrophoresis of the pooled PCR-amplified LSPs (Extended Data Fig. 1).

Together, these results demonstrate that PLASTIQ reliably detects DNA origami integrity at the single-helix level for both wireframe and lattice designs, and that it is compatible with PEGylated or UV-crosslinked nanostructures.

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