The vertebrate eye lens contains high concentrations of crystallins. The dense lenses of fish are particularly abundant in a class called γM-crystallin whose members are characterized by an unusually high methionine content and partial loss of the four tryptophan residues conserved in all γ-crystallins from mammals which are proposed to contribute to protection from UV-damage. Here, we present the structure and dynamics of γM7-crystallin from zebrafish (Danio rerio). The solution structure shares the typical two-domain, four-Greek-key motif arrangement of other γ-crystallins, with the major difference noted in the final loop of the N-terminal domain, spanning residues 65–72. This is likely due to the absence of the conserved tryptophans. Many of the methionine residues are exposed on the surface but are mostly well-ordered and frequently have contacts with aromatic side chains. This may contribute to the specialized surface properties of these proteins that exist under high molecular crowding in the fish lens. NMR relaxation data show increased backbone conformational motions in the loop regions of γM7 compared to those of mouse γS-crystallin and show that fast internal motion of the interdomain linker in γ-crystallins correlates with linker length. Unfolding studies monitored by tryptophan fluorescence confirm results from mutant mouse γS-crystallin and show that unfolding of a βγ-crystallin domain likely starts from unfolding of the variable loop containing the more fluorescently quenched tryptophan residue, resulting in a native-like unfolding intermediate.

RCL is an enzyme that catalyzes the N-glycosidic bond cleavage of purine 2′-deoxyribonucleoside 5′-monophosphates. Recently, the structures of both free wild type and GMP-bound mutant complex have been determined by multidimensional NMR, revealing a doubly wound α/β protein existing in a symmetric homodimer. In this work, we investigated the catalytic mechanism by rational site-directed mutagenesis, steady-state and pre-steady-state kinetics, ITC binding analysis, methanolysis, and NMR study. First, we provide kinetic evidence in support of the structural studies that RCL functions in a dimeric form, with an apparent dissociation constant around 0.5 μM in the presence of substrate dGMP. Second, among the eight residues under investigation, the highly conserved Glu93 is absolutely critical and Tyr13 is also important likely contributing to the chemical step, whereas Ser117 from the neighboring subunit and Ser87 could be the key residues for the phosphate group recognition. Lastly, we demonstrate by methanolysis study that the catalytic reaction proceeds via the formation of a reaction intermediate, which is subsequently hydrolyzed by solvent nucleophile resulting in the formation of normal product deoxyribose monophosphate (dR5P) or methoylated-dR5P. In conclusion, the current study provides mechanistic insights into a new class of nucleotide hydrolase, which resembles nucleoside 2′-deoxyribosyltransferases structurally and functionally but also possesses clear distinction.

Gfi-1 is a crucial transcriptional repressor for the precise regulation of cell proliferation and differentiation in hematopoiesis. Recently, this protein has also been demonstrated to be capable of restricting the proliferation of hematopoietic stem cells, a process that appears to be vital for the long-term competency of hematopoietic stem cells. These two seemingly opposite outcomes of regulation are likely to arise from its interactions with a variety of cellular partners. Such interactions can directly affect the genes that Gfi-1 recognizes through its DNA binding zinc-finger domain. In this work, we report the determination of the solution structure of Gfi-1 zinc fingers 3–5 in complex with a 16-mer consensus DNA using multidimensional NMR method. Unlike a proposed minor-groove binding model based on methylation interference experiments, our structure clearly shows that Gfi-1 zinc fingers 3–5 bind into the major groove of the target DNA reminiscent of canonical C2H2 zinc-finger domains. The fourth and fifth zinc fingers recognize the AATC core sequence by forming base-specific hydrogen bonds between the side chains of Asn382, Gln379, and Asp354 and the bases of the invariant adenines and cytosine. Overall, the current work provides valuable insight into the structural determinants for DNA binding specificity, in particular for the TCA triplet that has not been observed in any other structures of zinc finger–DNA complexes, as well as molecular rationales for a naturally occurring mutation that causes acute myeloid leukemia.

Conformational change and aggregation of native proteins are associated with many serious age-related and neurological diseases. γS-Crystallin is a highly stable, abundant structural component of vertebrate eye lens. A single F9S mutation in the N-terminal domain of mouse γS-crystallin causes the severe Opj cataract, with disruption of cellular organization and appearance of fibrillar structures in the lens. Although the mutant protein has a near-native fold at room temperature, significant increases in hydrogen/deuterium exchange rates were observed by NMR for all the well-protected β-sheet core residues throughout the entire N-terminal domain of the mutant protein, resulting in up to a 3.5-kcal/mol reduction in the free energy of the folding/unfolding equilibrium. No difference was detected for the C-terminal domain. At a higher temperature, this effect further increases to allow for a much more uniform exchange rate among the N-terminal core residues and those of the least well-structured surface loops. This suggests a concerted unfolding intermediate of the N-terminal domain, while the C-terminal domain stays intact. Increasing concentrations of guanidinium chloride produced two transitions for the Opj mutant, with an unfolding intermediate at ∼ 1 M guanidinium chloride. The consequence of this partial unfolding, whether by elevated temperature or by denaturant, is the formation of thioflavin T staining aggregates, which demonstrated fibril-like morphology by atomic force microscopy. Seeding with the already unfolded protein enhanced the formation of fibrils. The Opj mutant protein provides a model for stress-related unfolding of an essentially normally folded protein and production of aggregates with some of the characteristics of amyloid fibrils.

RCL is an enzyme that catalyzes the N-glycosidic bond cleavage of purine 2′-deoxyribonucleoside 5′-monophosphates, a novel enzymatic reaction reported only recently. In this work, we determined the solution structure by multidimensional NMR and provide a structural framework to elucidate its mechanism with computational simulation. RCL is a symmetric homodimer, with each monomer consisting of a five-stranded parallel β-sheet sandwiched between five α-helices. Three of the helices form the dimer interface, allowing two monomers to pack side by side. The overall architecture featuring a Rossmann fold is topologically similar to that of deoxyribosyltransferases, with major differences observed in the putative substrate binding pocket and the C-terminal tail. The latter is seemingly flexible and projecting away from the core structure in RCL, but loops back and is positioned at the bottom of the neighboring active site in the transferases. This difference may bear functional implications in the context of nucleobase recognition involving the C-terminal carboxyl group, which is only required in the reverse reaction by the transferases. It was also noticed that residues around the putative active site show significant conformational variation, suggesting that protein dynamics may play an important role in the enzymatic function of apo-RCL. Overall, the work provides invaluable insight into the mechanism of a novel N-glycosidase from the structural point of view, which in turn will allow rational anti-tumor and anti-angiogenesis drug design.

In many age-related and neurological diseases, formerly native proteins aggregate via formation of a partially unfolded intermediate. γS-Crystallin is a highly stable structural protein of the eye lens. In the mouse Opj cataract, a non-conservative F9S mutation in the N-terminal domain core of γS allows the adoption of a native fold but renders the protein susceptible to temperature- and concentration-dependent aggregation, including fibril formation. Hydrogen/deuterium exchange and denaturant unfolding studies of this mutant protein (Opj) have suggested the existence of a partially unfolded intermediate in its aggregation pathway. Here, we used NMR and fluorescence spectroscopy to obtain evidence for this intermediate. In 3.5 M urea, Opj forms a stable and partially unfolded entity that is characterized by an unstructured N-terminal domain and a largely intact C-terminal domain. Under physiologically relevant conditions, Carr–Purcell–Meiboom–Gill T2-relaxation dispersion experiments showed that the N-terminal domain residues were in conformational exchange with a loosely structured intermediate with a population of 1–2%, which increased with temperature. This provides direct evidence for a model in which proteins of native fold can explore an intermediate state with an increased propensity for formation of aggregates, such as fibrils. For the crystallins, this shows how inherited sequence variants or environmentally induced modifications can destabilize a well-folded protein, allowing the formation of intermediates able to act as nucleation sites for aggregation and the accumulation of light-scattering centers in the cataractous lens.