Size of Unfolded and Dissociated Subunits versus that of Native Multimeric Proteins

Metal ion-regulated assembly of designed modular protein cages

Coiled-coil (CC) dimers are versatile, customizable building modules for the design of diverse protein architectures unknown in nature. Incorporation of dynamic self-assembly, regulated by a selected chemical signal, represents an important challenge in the construction of functional polypeptide nanostructures. Here, we engineered metal binding sites to render an orthogonal set of CC heterodimers Zn(II)-responsive as a generally applicable principle. The designed peptides assemble into CC heterodimers only in the presence of Zn(II) ions, reversibly dissociate by metal ion sequestration, and additionally act as pH switches, with low pH triggering disassembly. The developed Zn(II)-responsive CC set is used to construct programmable folding of CC-based nanostructures, from protein triangles to a two-chain bipyramidal protein cage that closes and opens depending on the metal ion. This demonstrates that dynamic self-assembly can be designed into CC-based protein cages by incorporation of metal ion-responsive CC building modules that act as conformational switches and that could also be used in other contexts.

Intrinsically disordered protein regions at membrane contact sites

Membrane contact sites (MCS) are regions of close apposition between membrane-bound organelles. Proteins that occupy MCS display various domain organisation. Among them, lipid transfer proteins (LTPs) frequently contain both structured domains as well as regions of intrinsic disorder. In this review, we discuss the various roles of intrinsically disordered protein regions (IDPRs) in LTPs as well as in other proteins that are associated with organelle contact sites. We distinguish the following functions: (i) to act as flexible tethers between two membranes; (ii) to act as entropic barriers to prevent protein crowding and regulate membrane tethering geometry; (iii) to define the action range of catalytic domains. These functions are added to other functions of IDPRs in membrane environments, such as mediating protein-protein and protein-membrane interactions. We suggest that the overall efficiency and fidelity of contact sites might require fine coordination between all these IDPR activities.

An efficient and quantitative assay for epitope-tagged therapeutic protein development with a capillary western system

Aim: To develop and validate a reliable, robust and efficient assay to detect and quantify biologic compounds in vitro and in vivo during early stage of a biotherapeutic agent discovery. Methodology & results: An enrichment-free immunoassay method was developed to quantify a polyhistidine N- and FLAG C-terminally-tagged recombinant protein of ∼55 kDa. The target proteins were purified by a nickel-based matrix via tag affinity, followed by probing with biotinylated antitag antibody and subsequently detected by streptavidin-horseradish peroxidase conjugate using an automated capillary-based western system. Conclusion: A simple, highly sensitive and efficient immunoassay protocol was established to assess the in vitro stability and pharmacokinetic properties of propitious recombinant proteins in vivo in mouse to support early stage development of a biotherapeutic lead.

A giant amphipathic helix from a perilipin that is adapted for coating lipid droplets

How proteins are targeted to lipid droplets (LDs) and distinguish the LD surface from the surfaces of other organelles is poorly understood, but many contain predicted amphipathic helices (AHs) that are involved in targeting. We have focused on human perilipin 4 (Plin4), which contains an AH that is exceptional in terms of length and repetitiveness. Using model cellular systems, we show that AH length, hydrophobicity, and charge are important for AH targeting to LDs and that these properties can compensate for one another, albeit at a loss of targeting specificity. Using synthetic lipids, we show that purified Plin4 AH binds poorly to lipid bilayers but strongly interacts with pure triglycerides, acting as a coat and forming small oil droplets. Because Plin4 overexpression alleviates LD instability under conditions where their coverage by phospholipids is limiting, we propose that the Plin4 AH replaces the LD lipid monolayer, for example during LD growth.

Lipid droplets are cellular organelles important for cellular homeostasis and their disruption has been implicated in many diseases. Here the authors use a large amphipathic helix from perilipin 4 to uncover parameters important for specific lipid droplet targeting and stabilization of the oil core.

A Combined NMR and SAXS Analysis of the Partially Folded Cataract-Associated V75D γD-Crystallin

A cataract is a pathological condition characterized by the clouding of the normally clear eye lens brought about by deposition of crystallin proteins in the lens fiber cells. These protein aggregates reduce visual acuity by scattering or blocking incoming light. Chemical damage to proteins of the crystallin family, accumulated over a lifetime, leads to age-related cataract, whereas inherited mutations are associated with congenital or early-onset cataract. The V75D mutant of γD-crystallin is associated with congenital cataract in mice and was previously shown to un/fold via a partially folded intermediate. Here, we structurally characterized the stable equilibrium urea unfolding intermediate of V75D at the ensemble level using solution NMR and small-angle x-ray scattering. Our data show that, in the intermediate, the C-terminal domain retains a folded conformation that is similar to the native wild-type protein, whereas the N-terminal domain is unfolded and comprises an ensemble of random conformers, without any detectable residual structural propensities.

Characterization of a dimeric unfolding intermediate of bovine serum albumin under mildly acidic condition

Protein aggregation is a well-known phenomenon related to serious medical implications. Bovine serum albumin (BSA), a structural analogue of human serum albumin, has a natural tendency for aggregation under stress conditions. While following effect of moderately acidic pH on BSA, a state was identified at pH 4.2 having increased light scattering capability at 350 nm. It was essentially a dimer devoid of disulphide linked large aggregates as observed from 'spin column' experiments, gel electrophoresis and ultra-centrifugations. Its surface hydrophobic character was comparable to the native conformer at pH 7.0 as observed by the extraneous fluorescence probes pyrene and pyrene maleimide but its interactions with 1-anilino 8-naphthelene sulphonic acid was more favorable. Dimerization was irreversible between pH 4.2 and 7.0 even after treatment with DTT. The role of the only cysteine-34 residue was investigated where modification with reagents of arm length bigger than 6 A prevented dimerization. Molecular modeling of BSA indicated that cys-34 resides in a cleft of 6 A depth. This indicated that the area surrounding the cleft plays important role in inducing the dimerization.

UDP-galactose 4-epimerase fromKluyveromyces fragilis: existence of subunit independent functional site

UDP-galactose 4-epimerase from Kluyveromyces fragilis is a stable homodimer of 75 kDa/subunit with non-covalently bound NAD acting as cofactor. Partial proteolysis with trypsin in the presence of 5'-UMP, a strong competitive inhibitor, led to a degraded product which was purified. Results from SDS-PAGE, size-exclusion (SE)-HPLC and ultracentrifugation indicated its monomeric status and size between 43 and 45 kDa. 'Two-step assay' with UDP-glucose dehydrogenase as coupling enzyme in the presence of NAD ensured epimerase activity of the monomer. The possibility of transient dimerization of monomeric epimerase during catalysis was excluded by SE-HPLC in the presence of excess substrate and NAD. This truncated enzyme retained catalytic site related properties like Km for UDP-galactose, 'NADH-like coenzyme fluorescence' and 'reductive inhibition' similar to its dimeric counterpart. Reversible reactivation of the monomer was achieved up to 95% within 3 min from 8 M urea induced unfolded state, indicating that the catalytic site could form independent of its quaternary structure. Equilibrium unfolding between 0 and 8 M urea indicated that the monomer was less stable compared to the dimer. Chemical modification of amino acids and reconstitution with etheno-NAD suggested that the architecture around the catalytic site of the monomer was conserved. Specific modification reagents further confirmed that the cysteine residues required for catalysis and coenzyme fluorophore reside exclusively on a single subunit negating a 'subunit sharing model' of its catalytic site.

UDP-galactose 4-epimerase from Kluyveromyces fragilis

UDP-galactose 4-epimerases from the yeast Kluyvero-myces fragilis and Escherichia coli are both homodimers but the molecular mass of the former (75 kDa/subunit) is nearly double that of the latter (39 kDa/subunit). Protein databank sequence homology revealed the possibility of mutarotase activity in the excess mass of the yeast enzyme. This was confirmed by three independent assay protocols. With the help of specific inhibitors and chemical modification reagents, the catalytic sites of epimerase and mutarotase were shown to be distinct and independent. Partial proteolysis with trypsin in the presence of specific inhibitors, 5'-UMP for epimerase and galactose for mutarotase, protected the respective activities. Similar digestion with double inhibitors cleaved the molecule into two fragments of 45 and 30 kDa. After separation by size-exclusion HPLC, they manifested exclusively epimerase and mutarotase activities, respectively. Epimerases from Kluyveromyces lactis var lactis, Pachysolen tannophilus and Schizosaccharomyces pombi also showed associated mutarotase activity distinct from the constitutively formed mutarotase activity. Thus, the bifunctionality of homodimeric yeast epimerases of 65-75 kDa/subunit appears to be universal. In addition to the inducible bifunctional epimerase/mutarotase, K. fragilis contained a smaller constitutive monomeric mutarotase of approximately 35 kDa.

Extended application of gel-permeation chromatography by spin column

Separation of small volumes of proteins from unbound ligands or reequilibration with buffer by passing through a 1-ml Sephadex G-50 column under mild centrifugal force is a popular technique. Here it has been demonstrated that other Sephadex matrix could similarly be used for complete or partial separation of protein molecules. Proteins to be eluted at void volume are recovered near quantitatively, while others are partly or almost completely retained depending on molecular size. Calibration curves using standard proteins of Mw 12.5 to 440 kDa with Sephadex G-50-G-200 representing recovery versus molecular weight show profiles as expected from the fractionation ranges of the column matrix. The procedure may be applied to follow protein association-dissociation reactions if the molecular weights of the species concerned are known and a proper matrix exists for separating them. Equilibrium unfolding transitions constructed with model proteins in presence of 0-8M urea using recovery as an index correspond to profiles obtained from other physical measurements. This may be a convenient approach to follow change of protein hydrodynamic volume quickly when a parallel methodology is not readily available.