Structural and functional changes associated with modification of the ubiquitin methionine

Native chemical ligation at methionine bioisostere norleucine allows for N-terminal chemical protein ligation

γ-Thionorleucine is synthesized and used for N-terminal chemical protein modification by native chemical ligation–desulfurization to prepare linear diubiquitin.

Selective unfolding of one Ribonuclease H domain of HIV reverse transcriptase is linked to homodimer formation

HIV-1 reverse transcriptase (RT), a critical enzyme of the HIV life cycle and an important drug target, undergoes complex and largely uncharacterized conformational rearrangements that underlie its asymmetric folding, dimerization and subunit-selective ribonuclease H domain (RH) proteolysis. In the present article we have used a combination of NMR spectroscopy, small angle X-ray scattering and X-ray crystallography to characterize the p51 and p66 monomers and the conformational maturation of the p66/p66′ homodimer. The p66 monomer exists as a loosely structured molecule in which the fingers/palm/connection, thumb and RH substructures are connected by flexible (disordered) linking segments. The initially observed homodimer is asymmetric and includes two fully folded RH domains, while exhibiting other conformational features similar to that of the RT heterodimer. The RH′ domain of the p66′ subunit undergoes selective unfolding with time constant ∼6.5 h, consistent with destabilization due to residue transfer to the polymerase′ domain on the p66′ subunit. A simultaneous increase in the intensity of resonances near the random coil positions is characterized by a similar time constant. Consistent with the residue transfer hypothesis, a construct of the isolated RH domain lacking the two N-terminal residues is shown to exhibit reduced stability. These results demonstrate that RH′ unfolding is coupled to homodimer formation.

Effects of Fe(II)/H2O2 oxidation on ubiquitin conformers measured by ion mobility-mass spectrometry

Oxidative modifications can have significant effects on protein structure in solution. Here, the structures and stabilities of oxidized ubiquitin ions electrosprayed from an aqueous solution (pH 2) are studied by ion mobility spectrometry-mass spectrometry (IMS-MS). IMS-MS has proven to be a valuable technique to assess gas phase and in many cases, solution structures. Herein, in vitro oxidation is performed by Fenton chemistry with Fe(II)/hydrogen peroxide. Most molecules in solution remain unmodified, whereas ∼20% of the population belongs to an M+16 Da oxidized species. Ions of low charge states (+7 and +8) show substantial variance in collision cross section distributions between unmodified and oxidized species. Novel and previously reported gaussian conformers are used to model cross section distributions for +7 and +8 oxidized ubiquitin ions, respectively, in order to correlate variances in observed gas-phase distributions to changes in populations of solution states. Based on gaussian modeling, oxidized ions of charge state +7 have an A-state conformation which is more populated for oxidized relative to unmodified ions. Oxidized ubiquitin ions of charge state +8 have a distribution of conformers arising from native-state ubiquitin and higher intensities of A- and U-state conformers relative to unmodified ions. This work provides evidence that incorporation of a single oxygen atom to ubiquitin leads to destabilization of the native state in an acidic solution (pH ∼2) and to unfolding of gas-phase compact structures.

Article Commentary: Regulation of Protein Function by Residue Oxidation

A majority of extant life forms require O2 to survive and thrive. Oxidation is inevitably one of the most active cellular processes and one constant challenge that living organisms must face. Generation of oxidants including reactive oxygen species is a natural consequence of cellular metabolism of all biological systems during normal life cycle under different environments. These oxidants oxidize many biological macromolecules such as proteins and affect their functions. Oxidation of specific amino acids in proteins may cause damage to protein structure and impair function, or may also activate protein activities and promote cellular metabolism. As an example, the reversible oxidation of cysteine and methionine residues has a profound impact on protein function and cellular process. A recent study that examines the effect of Met oxidation on Ser phosphorylation in a mitochondrial enzyme, pyruvate dehydrogenase, provides another demonstration that protein oxidation is an important regulatory mechanism for organisms to deal with developmental and environmental challenges throughout life processes.

Stabilization of the N-terminal β-hairpin of ubiquitin by a terminal hydrophobic cluster

Study of model beta-hairpin peptides allows for better understanding of the factors involved in the formation of beta-sheet secondary structure in proteins. It is known that turn sequence, sidechain-sidechain interactions, interstrand hydrogen bonding, and beta-sheet propensity of residues are all important for beta-hairpin stability in aqueous solution. However, interactions of the sidechains of the terminal residues of hairpins are thought to contribute little to overall hairpin stability since these residues are typically frayed. Here, the authors report a stabilizing hydrophobic cluster of residues at the termini of the naturally occurring excised N-terminal beta-hairpin of Ubiquitin that folds autonomously in aqueous solution. Our data show that deletion of Met1 and Val17 from this hairpin destabilized the folded state in both aqueous solution and in aqueous-methanol solutions. These results suggest that interactions of terminal residues which are usually frayed can nonetheless contribute significantly to overall stability of beta-hairpin.

The oxidative environment and protein damage

Proteins are a major target for oxidants as a result of their abundance in biological systems, and their high rate constants for reaction. Kinetic data for a number of radicals and non-radical oxidants (e.g. singlet oxygen and hypochlorous acid) are consistent with proteins consuming the majority of these species generated within cells. Oxidation can occur at both the protein backbone and on the amino acid side-chains, with the ratio of attack dependent on a number of factors. With some oxidants, damage is limited and specific to certain residues, whereas other species, such as the hydroxyl radical, give rise to widespread, relatively non-specific damage. Some of the major oxidation pathways, and products formed, are reviewed. The latter include reactive species, such as peroxides, which can induce further oxidation and chain reactions (within proteins, and via damage transfer to other molecules) and stable products. Particular emphasis is given to the oxidation of methionine residues, as this species is readily oxidised by a wide range of oxidants. Some side-chain oxidation products, including methionine sulfoxide, can be employed as sensitive, specific, markers of oxidative damage. The product profile can, in some cases, provide valuable information on the species involved; selected examples of this approach are discussed. Most protein damage is non-repairable, and has deleterious consequences on protein structure and function; methionine sulfoxide formation can however be reversed in some circumstances. The major fate of oxidised proteins is catabolism by proteosomal and lysosomal pathways, but some materials appear to be poorly degraded and accumulate within cells. The accumulation of such damaged material may contribute to a range of human pathologies.

Mass spectrometric studies of the formation and reactivity of trans-[PtCl2(Am)(piperidinopiperidine)] x HCl complexes with ubiquitin

trans-[PtCl2(Am)(pip-pip)] x HCl complexes, where Am = ammine, methylamine and dimethylamine, react with ubiquitin to form 1:1 covalent adducts. The platinum complexes bind exclusively to Met1 of ubiquitin forming trans-[PtCl(S-Met1-Ub)(Am)(pip-pip)] adducts. These adducts are reactive towards nucleophiles and react with deoxyguanosine (dGMP) to form the ternary trans-[Pt(dGMP)(S-Met1-Ub) (Am)(pip-pip)] complex which is stable in water and even in the presence of excess glutathione (GSH). Reaction of trans-[PtCl(S-Met1-Ub)(Am)(pip-pip)] with GSH resulted in the rapid formation of the ternary complex trans-[Pt(GS)(S-Met1-Ub)(Am)(pip-pip)] which was not stable and slowly lost the platinum moiety; after 7 days the platinum moiety was completely removed and the native ubiquitin was regenerated.

Interactions of cisplatin and transplatin with proteins. Comparison of binding kinetics, binding sites and reactivity of the Pt-protein adducts of cisplatin and transplatin towards biological nucleophiles

In this manuscript we report on the interactions of cis-DDP (cisplatin, cis-diamminedichloroplatinum(II)) and trans-DDP (transplatin, trans-diamminedichloroplatinum(II)) with two model proteins, ubiquitin (Ub) and horse heart myoglobin (Mb), and attempt to answer the question whether proteins that have methionine-Pt adducts can transfer the platinum to biological nucleophiles and particularly to DNA. Our study shows that cisplatin and transplatin form different adducts with ubiquitin: transplatin forms one major adduct, trans-[Pt(Ub)(NH(3))(2)Cl], while cisplatin forms four distinct adducts, [Pt(Ub)(NH(3))(2)Cl], [Pt(Ub)(NH(3))(2)(H(2)O)], [Pt(Ub)(NH(3))(2)], and [Pt(Ub)(NH(3))]. When binding ubiquitin, Met1 is the preferred binding site of cisplatin, but not of transplatin. Cisplatin binds faster than transplatin to both ubiquitin and horse heart myoglobin. Both cisplatin and transplatin adducts form stable ternary adducts when reacted with 5'-guanosine monophosphate (5'-GMP) or a tetranucleotide. No transfer of the Pt moiety from the proteins to the nucleotides was observed. Glutathione efficiently removes the platinum from preformed adducts of both cisplatin and transplatin with ubiquitin.

Ubiquitin and the enigma of intracellular protein degradation

Contrary to widespread belief, the regulation and mechanism of degradation for the mass of intracellular proteins (i.e. differential, selective protein turnover) in vertebrate tissues is still a major biological enigma. There is no evidence for the conclusion that ubiquitin plays any role in these processes. The primary function of the ubiquitin-dependent protein degradation pathway appears to lie in the removal of abnormal, misfolded, denatured or foreign proteins in some eukaryotic cells. ATP/ubiquitin-dependent proteolysis probably also plays a role in the degradation of some so-called 'short-lived' proteins. Evidence obtained from the covalent modification of such natural substrates as calmodulin, histones (H2A, H2B) and some cell membrane receptors with ubiquitin indicates that the reversible interconversion of proteins with ubiquitin followed by concomitant functional changes may be of prime importance.

Synthetic, structural and biological studies of the ubiquitin system: the total chemical synthesis of ubiquitin

The small protein ubiquitin (76 amino acids) has been synthesized under optimized conditions by Merrifield solid-phase methodology using the N alpha-Fmoc protecting group. The crude polypeptide mixture was purified to homogeneity by gel filtration, dialysis and a combination of cation- and anion-exchange chromatography to yield ubiquitin. Amino acid analysis, enzymic digestion and sequencing by automated Edman degradation were used to authenticate the primary structure. Isoelectric focusing and m.s. were used to demonstrate that the final product was greater than 98% pure with a final yield of 93 mg (4.3%) from a single synthesis on a 0.25 nmol scale.

Demonstration of a factor in fraction I of reticulocyte lysates necessary for the steady state accumulation of ubiquitin conjugates of des-75-76-ubiquitin

Addition of des-75-76-ubiquitin (ubiquitin lacking its two C-terminal glycine residues) to reticulocyte lysates leads to the inhibition of proteolysis and the formation of conjugates between it and native ubiquitin, as demonstrated by the incorporation of both 125I-labeled des-75-76-ubiquitin and 125I-labeled ubiquitin into these conjugates. Conjugate formation is blocked by methylation of the amino groups of des-75-76-ubiquitin, consistent with the concept that the conjugates represent attachment of the ubiquitin alpha-carboxyl group to amino groups of des-75-76-ubiquitin. The lack of significant direct competition for conjugate formation by typical ubiquitinatable proteolysis substrates or by des-73-76-ubiquitin, together with differences in conjugate formation between des-73-76-ubiquitin and des-75-76-ubiquitin demonstrated earlier, indicates that the enzyme involved recognizes the ubiquitin sequence as a substrate for ubiquitination. Increasing concentrations of native ubiquitin first increase and then reduce the steady state level of conjugates of the des-75-76-protein, the inhibitory effects of high concentrations consistent with competition by native ubiquitin for conjugate formation. Upon fractionation of reticulocyte lysates, a factor essential to the net synthesis of conjugates of des-75-76-ubiquitin was demonstrated to be present in Fraction I and to behave as a protein of molecular weight 38,000. The role in this system of a factor from Fraction I other than ubiquitin indicates that a novel pathway is involved.