Optimizing fluorine labelling for 19F solid-state NMR in oriented biological systems

Organoid development and applications in gynecological cancers: the new stage of tumor treatment

Gynecologic cancers (GCs), including cervical cancer (CC), ovarian cancer (OC), endometrial cancer (EC), as well as vulvar and vaginal cancers, represent major health threats to women, with increasing incidence rates observed globally. Conventional treatments, such as surgery, radiation therapy, and chemotherapy, are often hindered by challenges such as drug resistance and recurrence, contributing to high mortality rates. Organoid technology has emerged as a transformative tool in cancer research, offering in vitro models that closely replicate the tumor cell architecture and heterogeneity of primary cancers. Tumor-derived organoids preserve the histological and molecular characteristics of the original tumors, making them invaluable for studying tumor biology, molecular pathways, and the tumor immune microenvironment. Furthermore, organoids play a crucial role in biomarker discovery, drug screening, and the development of personalized therapeutic strategies. In contrast to traditional cell lines and patient-derived xenograft (PDX) models, gynecologic cancer organoids accurately mirror the genetic mutations and specific gene expression profiles of primary tumors. This review provides an overview of recent advancements in the development of gynecologic cancer organoid models, highlighting their contributions to understanding disease mechanisms, facilitating drug discovery, and advancing precision medicine. It also addresses the potential and challenges of organoid technology, with a focus on its role in advancing personalized treatment approaches for GCs.

Fluorinated Tags to Study Protein Conformation and Interactions Using 19F NMR

The incorporation of fluorine atoms into a biomacromolecule provides a background-free and environmentally sensitive reporter of structure, conformation and interactions using 19F NMR. There are several methods to introduce the 19F reporter - either by synthetic incorporation via solid phase peptide synthesis; by suppressing the incorporation or biosynthesis of a natural amino acid and supplementing the growth media with a fluorinated counterpart during protein expression; and by genetic code expansion to add new amino acids to the amino acid alphabet. This review aims to discuss progress in the field of introducing fluorinated handles into biomolecules for NMR studies by post-translational bioconjugation or 'fluorine-tagging'. We will discuss the range of chemical tagging 'warheads' that have been used, explore the applications of fluorine tags, discuss ways to enhance reporter sensitivity and how the signal to noise ratios can be boosted. Finally, we consider some key challenges of the field and offer some ideas for future directions.

Fluorine labelling for in situ 19F NMR in oriented systems

The focus of this project is to take advantage of the large NMR chemical shift anisotropy of 19F to determine the orientation of fluorine labeled biomolecules in situ in oriented biological systems such as muscle. The difficulty with a single fluorine atom is that the orientation determined from a chemical shift is not singlevalued in the case of a fully anisotropic chemical shift tensor. The utility of a labeling approach with two fluorine labels in a fixed molecular framework where one of the labels has an axially symmetric chemical shift anisotropy such as a CF3 group and the other has a fully asymmetric chemical shift anisotropy such as 5-fluorotryptophan is evaluated. The result is that the orientation of the label can be determined straightforwardly from a single one-dimensional 19F NMR spectrum. The potential applications are widespread and not limited to biological applications.

Small, but powerful and attractive: 19F in biomolecular NMR

Nuclear magnetic resonance (NMR) spectroscopy is a versatile tool for probing structure, dynamics, folding, and interactions at atomic resolution. While naturally occurring magnetically active isotopes, such as ¹H, ¹³C, or ¹⁵N, are most commonly used in biomolecular NMR, with ¹⁵N and ¹³C isotopic labeling routinely employed at the present time, ¹⁹F is a very attractive and sensitive alternative nucleus, which offers rich information on biomolecules in solution and in the solid state. This perspective summarizes the unique benefits of solution and solid-state ¹⁹F NMR spectroscopy for the study of biological systems. Particular focus is on the most recent studies and on future unique and important potential applications of fluorine NMR methodology.