Local Anesthetic Bupivacaine Inhibits Melanoma Proliferation and Metastasis by Targeting PAPSS2.

BACKGROUND: Melanoma is a highly invasive skin cancer with limited treatment strategies. Bupivacaine, a commonly used local anesthetic recognized for its safety, has shown promise in combating tumors. 3'-phosphoadenosine 5'-phosphosulfate synthase 2 (PAPSS2) is a key enzyme in the sulfation process and is associated with the development and metastasis of various tumors. This study aimed to explore the mechanism by which bupivacaine inhibits melanoma proliferation and metastasis by targeting PAPSS2. METHODS: The effects of bupivacaine on the proliferation of A375 and A2058 melanoma cells were evaluated using Cell Counting Kit-8 (CCK-8), 5-Ethynyl-2'-deoxyuridine (EdU) labeling, and clonogenic assays. Cell migration, invasion, and PAPSS2 expression were evaluated using Transwell experiments and Quantitative Reverse Transcription Polymerase Chain Reaction (qRT-PCR) analysis. Additionally, an in vivo melanoma tumor model in nude mice was constructed to evaluate the impact of bupivacaine on melanoma growth and metastasis. Immunohistochemistry was used to assess tumor metastasis and PAPSS2 expression levels in the nude mouse model. RESULTS: Experimental results demonstrated that bupivacaine significantly inhibited melanoma proliferation and invasion compared to the control group. Notably, this inhibitory effect was partially reversed by PAPSS2 overexpression. In vivo experiments demonstrated that bupivacaine-treated nude mice exhibited reduced tumor volumes, weights, and fewer lung metastatic foci. Molecular analysis via qRT-PCR and immunohistochemistry analysis further indicated that bupivacaine significantly reduced PAPSS2 in tumor tissues. CONCLUSION: This study confirms that bupivacaine, a local anesthetic, can inhibit melanoma proliferation and metastasis by targeting the PAPSS2 signaling pathway. These findings suggest its potential as an anti-tumor medication and present new treatment strategies for melanoma.

Oriented docking of the template for improved imprinting efficiency toward peptide with modifications.

Molecular imprinting polymers (MIPs) are synthetic receptors as biomimetic materials for various applications ranging from sensing to separation and catalysis. However, currently existing MIPs are stuck to some of the issues including the longer preparation steps and poor performance. In this report, a facile and one-pot strategy by integrating the in-situ growth of magnetic nanoparticles and reversed phase microemulsion oriented molecularly imprinting strategy to develop magnetic molecular imprinted nanocomposites was proposed. Through self-assembling of the template, it brought up highly ordered and uniform arrangement of the imprinting structure, which offered faster adsorption kinetic as adsorption equilibrium was achived within 15 min, higher adsorption capacity (Qmax = 48.78 ± 1.54 µmol/g) and high affinity (Kd = 127.63 ± 9.66 µM) toward paradigm molecule-adenosine monophosphate (AMP) compared to the conventional bulk imprinting. The developed MIPs offered better affinity and superior specificity which allowed the specific enrichment toward targeted phosphorylated peptides from complex samples containing 100-fold more abundant interfering peptides. Interestingly, different types of MIPs can be developed which could targetly enrich the specific phosphorylated peptides for mass spectrometry analysis by simply switching the templates, and this strategy also successfully achieved imprinting of macromolecular peptides. Collectively, the approach showed broad applicability to target specific enrichment from metabolites to phosphorylated peptides and providing an alternative choice for selective recognition and analysis from complex biological systems.

Epitope Imprinting of Phospholipids by Oriented Assembly at the Oil/Water Interface for the Selective Recognition of Plasma Membranes.

Phospholipids, as fundamental building blocks of the cell membrane, play important roles for molecule transportation, cell recognition, etc. However, due to the structural diversity and amphipathic nature, there are few methods for the specific recognition of lipids as compared to other biomolecules such as proteins and glycans. Herein, we developed a molecular imprinting strategy for controllable imprinting toward the polar head of phospholipid exposed on the surface of cellular membranes for recognition. Phosphatidylserine, as unique lipid on the outer membrane leaflet of exosome and also hallmark for cell apoptosis, was imprinted with the developed method. The phosphatidylserine imprinted materials showed high efficiency and specific targeting capability not only for apoptotic cell imaging but also for the isolation of exosomes. Collectively, the synthesized molecularly imprinted materials have great potential for selective plasma membrane recognition for targeted drug delivery and biomarker discovery.