Progress in Medical Sciences and Life Sciences, in general, require detailed knowledge of the complex biological processes that underlie the function of a cell, the organization and interplay of multicellular structures, and, eventually, of the whole organism. Such a basic understanding has an enormous impact on our life, as it is necessary to understand diseases and to develop better drugs and therapeutic protocols. The cell, be it a pathogenic bacterium or a motor neuron, could be thought of as the fundamental unit of Life. However, a closer look at its inner workings reveals a hugely complex machinery, made up of a multitude of small and large molecules. Membrane proteins and lipids interact with each other in an orderly manner, to create larger structures─membranes─that segregate the inner aqueous solution in different compartments─organelles─and control the diffusion of soluble components in a selective manner. Other proteins dynamically organize as fibrils, making the cytoskeleton, that ultimately allow the cell to maintain its integrity and to control its shape and motility. Inside, DNA, RNAs, and the ribosomes take care of storing and translating the genetically encoded information, while other associated proteins regulate such processes and define the cellular phenotype. The intracellular aqueous compartments are filled with a plethora of soluble ions, metabolites, and macromolecules, which make up the intricated biochemical and signaling pathways that make the cell self-sustaining and ultimately “alive”...

...NMR spectroscopy is the only one able to obtain information on the structure, the kinetics, and the thermodynamics of biological macromolecules at the atomic level, as it can observe them in native-like environments at physiological temperatures, and it can do so in a nondestructive manner. (6) Such a feature has always made NMR spectroscopy appealing for the study of small and large molecules not only in vitro, isolated from their physiological context, but directly inside intact living cells. Compared to other spectroscopic techniques, NMR suffers from an intrinsically low sensitivity; therefore, its applicability to cells was traditionally restricted to the observation of small, highly abundant molecules. Indeed, in the past century, cellular NMR studies were mostly focused on the analysis of cellular metabolism, for example, by exploiting the observation of phosphorus-containing molecules through 31P NMR, or by introducing 13C-labeled precursors for a metabolic flux analysis. In some cases, very abundant small macromolecules could be studied, often because of peculiar properties that made them stand out against the rest of the milieu, as it is the case for highly shifted signals of paramagnetic metalloproteins. Then, in the early 2000s, it became clear that modern NMR spectrometers, with a higher magnetic field and more sensitive hardware, could detect signals from isotopically labeled proteins inside the bacteria in which they were recombinantly expressed. (7) Shortly after, macromolecules─proteins at first, then nucleic acids─were delivered to eukaryotic cells. The cellular NMR approach, reborn as “in-cell NMR”, soon gained widespread recognition, in a time when the scientific community had realized the importance of performing biochemical and biophysical studies in physiologically relevant contexts, and huge advancements were being made in developing techniques, such as single-molecule Förster resonance energy transfer (FRET) and cryo-electron tomography, that would be able to characterize macromolecules in a cellular environment...

...This work provides a detailed overview of the development and applications of in-cell solution NMR approaches during the first ∼20 years since its inception in the modern sense. We first describe the existing approaches for cell sample preparation, the various types and strategies for isotopic incorporation, and the NMR methods that can be applied to living cells. We then review the application of in-cell NMR to different biological questions: how the cellular environment affects the folding thermodynamics of a protein, its structural and dynamic properties, and its interactions with specific cellular partners; whether the structure of a folded protein in cells differs from that determined in vitro...