Over five decades of research have yielded a large body of information on how purified proteins attain their native state when refolded in the test tube, starting from a chemically or thermally denatured state. Nevertheless, we still know little about how proteins fold and unfold in their natural biological habitat: the living cell. Indeed, a variety of cellular components, including molecular chaperones, the ribosome, and crowding of the intracellular medium, modulate folding mechanisms in physiologically relevant environments. This review focuses on the current state of knowledge in protein folding in the cell with emphasis on the early stage of a protein’s life, as the nascent polypeptide traverses and emerges from the ribosomal tunnel. Given the vectorial nature of ribosome-assisted translation, the transient degree of chain elongation becomes a relevant variable expected to affect nascent protein foldability, aggregation propensity and extent of interaction with chaperones and the ribosome.
Background:The ribosome is a highly charged complex comprising RNAs and proteins. Results: Ribosomal proteins exhibit low hydrophobicity and a significant degree of intramolecular charge segregation. Conclusion: The majority of ribosomal proteins from all organisms, particularly halophiles, use intramolecular charge segregation to minimize electrostatic repulsion with rRNA. Significance: The electrostatic properties of ribosomal proteins are important for ribosome stability, assembly, and interaction with translation factors and nascent proteins.
This work explores the effect of long-range tertiary contacts on the distribution of residual secondary structure in the unfolded state of an alpha-helical protein. N-terminal fragments of increasing length, in conjunction with multidimensional nuclear magnetic resonance, were employed. A protein representative of the ubiquitous globin fold was chosen as the model system. We found that, while most of the detectable alpha-helical population in the unfolded ensemble does not depend on the presence of the C-terminal region (corresponding to the native G and H helices), specific N-to-C long-range contacts between the H and A-B-C regions enhance the helical secondary structure content of the N terminus (A-B-C regions). The simple approach introduced here, based on the evaluation of N-terminal polypeptide fragments of increasing length, is of general applicability to identify the influence of long-range interactions in unfolded proteins.
Here, we report a
nanoparticle-based probe that affords facile
cell labeling with cholesterol in cholesterol efflux (CE) assays.
This probe, called ezFlux, was optimized through a screening of multiple
nanoformulations engineered with a Förster resonance energy
transfer (FRET) reporter. The physicochemical- and bio-similarity
of ezFlux to standard semi-synthetic acetylated low-density lipoprotein
(acLDL) was confirmed by testing uptake in macrophages, the intracellular
route of degradation, and performance in CE assays. A single-step
fast self-assembly fabrication makes ezFlux an attractive alternative
to acLDL. We also show that CE testing using ezFlux is significantly
cheaper than that performed using commercial kits or acLDL. Additionally,
we analyze clinical trials that measure CE and show that ezFlux has
a place in many research and clinical laboratories worldwide that
use CE to assess cellular and lipoprotein function.
A structural-dynamic study of one of the chimeric proteins (SHA) belonging to the SH3-Bergerac family and containing the KATANGKTYE sequence instead of the N47D48 beta-turn in the spectrin SH3 domain was carried out by high resolution NMR spectroscopy. The spatial structure of the protein was determined and its dynamics in solution was investigated on the basis of the NMR data. The elongation of the SHA polypeptide chain in comparison with the WT-SH3 original protein (by ~17%) exerts practically no effect on the general topology of the molecule. The presence of a stable beta-hairpin in the region of insertion was confirmed. This hairpin was shown to have a higher mobility in comparison with other regions of the protein.
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