Structure of D-DNA: 8-fold or 7-fold helix?

We have shown that both right- and left-handed uniform helical models (RU and LU models) could be built to give satisfactory agreement with the fibre diffraction data of poly[d(I-C)] in the D-form. Atomic coordinates of these two models are reported in the present work. Molecular transforms of these two models, as well as of the recently published Hoogsteen base-paired 7-fold helical structure of Drew and Dickerson, are given. In view of the work of Drew and Dickerson, attention is drawn to the presence of clear 004 and 008 reflections in the diffraction patterns of poly[d(I-C)] and poly[d(A-T)]. The available data strongly suggest an 8-fold helical structure for the D-form of DNA.     

The H50Q Mutation Induces a 10-fold Decrease in the Solubility of α-Synuclein

The conversion of α-synuclein from its intrinsically disordered monomeric state into the fibrillar cross-β aggregates characteristically present in Lewy bodies is largely unknown. The investigation of α-synuclein variants causative of familial forms of Parkinson disease can provide unique insights into the conditions that promote or inhibit aggregate formation. It has been shown recently that a newly identified pathogenic mutation of α-synuclein, H50Q, aggregates faster than the wild-type. We investigate here its aggregation propensity by using a sequence-based prediction algorithm, NMR chemical shift analysis of secondary structure populations in the monomeric state, and determination of thermodynamic stability of the fibrils. Our data show that the H50Q mutation induces only a small increment in polyproline II structure around the site of the mutation and a slight increase in the overall aggregation propensity. We also find, however, that the H50Q mutation strongly stabilizes α-synuclein fibrils by 5.0 ± 1.0 kJ mol⁻¹, thus increasing the supersaturation of monomeric α-synuclein within the cell, and strongly favors its aggregation process. We further show that wild-type α-synuclein can decelerate the aggregation kinetics of the H50Q variant in a dose-dependent manner when coaggregating with it. These last findings suggest that the precise balance of α-synuclein synthesized from the wild-type and mutant alleles may influence the natural history and heterogeneous clinical phenotype of Parkinson disease.     

A single amino acid substitution in soybean VSPα increases its acid phosphatase activity nearly 20-fold

Soybean [Glycine max (L.) Merr.] contains two proteins called vegetative storage proteins (VSPs) that function as temporary storage reserves, but are also closely related to plant acid phosphatases of the haloacid dehalogenase (HAD) superfamily. This study examined the biochemical basis for the relatively low catalytic activity previously reported for these VSPs. The specific activity of purified recombinant VSP on GMP was about 40-fold lower than for a related soybean root nodule acid phosphatase (APase), which had a specific activity of 845 U mg^–1 protein. Conversion of Ser¹⁰⁶ to Asp increased VSP activity about 20-fold. This Asp residue is present in nodule APase and is a highly conserved nucleophile in the HAD superfamily. Related VSPs from cultivated soybean and from three wild perennial soybeans, as well as a pod storage protein (PSP) from Phaseolus vulgaris L. all lack the catalytic Asp, suggesting they too are catalytically inefficient. Phylogenetic analysis showed the VSPs and PSP are more closely related to each other than to 21 other VSP-like proteins from several plant species, all of which have the nucleophilic Asp. This study suggests that loss of catalytic activity may be a requirement for the VSPs and PSP to function as storage proteins in legumes.Abbreviations APase Acid phosphatase - GST Glutathione S-transferase - HAD Haloacid dehalogenase - pNPP Para-nitrophenol phosphate - PSP Pod storage protein - RIP Ribosome inactivating protein - VSP Vegetative storage protein Accession numbers for the VSP sequences reported in this paper are from G. falcata, AY523602; G. tomentella, AY523603; G. curvata, AY523604     

Beryllium is an inhibitor of cellular GSK-3β that is 1,000-fold more potent than lithium

Glycogen synthase kinase 3β (GSK-3β) is a key regulator in signaling networks that control cell proliferation, metabolism, development, and other processes. Lithium chloride is a GSK-3 family inhibitor that has been a mainstay of in vitro and in vivo studies for many years. Beryllium salt has the potential to act as a lithium-like inhibitor of GSK-3, but it is not known whether this agent is effective under physiologically relevant conditions. Here we show that BeSO₄ inhibits endogenous GSK-3β in cultured human cells. Exposure to 10 µM Be²⁺ produced a decrease in GSK-3β kinase activity that was comparable to that produced by 10 mM Li⁺, indicating that beryllium is about 1,000-fold more potent than the classical inhibitor when treating intact cells. There was a statistically significant dose-dependent reduction in specific activity of GSK-3β immunoprecipitated from cells that had been treated with either agent. Lithium inhibited GSK-3β kinase activity directly, and it also caused GSK-3β in cells to become phosphorylated at serine-9 (Ser-9), a post-translational modification that occurs as part of a well-known positive feedback loop that suppresses the kinase activity. Beryllium also inhibited the kinase directly, but unlike lithium it had little effect on Ser-9 phosphorylation in the cell types tested, suggesting that alternative modes of feedback inhibition may be elicited by this agent. These results indicate that beryllium, like lithium, can induce perturbations in the GSK-3β signaling network of treated cells.     

Improvement (5-fold) of enantioselectivity for lipase-catalyzed esterification of a bulky substrate at 57°c in organic solvent

Summary A reaction temperature at 57° C produced an improvement of lipase's enantioselectivity for an esterification of a bulky substrate, such as 2-(2-methyl- or 4-tert-butyl-phenoxy) propionic acid, in organic solvent with a suitable amount of water added, although the poor enantioselectivity was observed for its bulky substrate under ordinary reaction conditions.     

A synthetic gene increases TGFβ3 accumulation by 75-fold in tobacco chloroplasts enabling rapid purification and folding into a biologically active molecule

Human transforming growth factor-β3 (TGFβ3) is a new therapeutic protein used to reduce scarring during wound healing. The active molecule is a nonglycosylated, homodimer comprised of 13-kDa polypeptide chains linked by disulphide bonds. Expression of recombinant human TGFβ3 in chloroplasts and its subsequent purification would provide a sustainable source of TGFβ3 free of animal pathogens. A synthetic sequence (33% GC) containing frequent chloroplast codons raised accumulation of the 13-kDa TGFβ3 polypeptide by 75-fold compared to the native coding region (56% GC) when expressed in tobacco chloroplasts. The 13-kDa TGFβ3 monomer band was more intense than the RuBisCO 15-kDa small subunit on Coomassie blue-stained SDS-PAGE gels. TGFβ3 accumulated in insoluble aggregates and was stable in leaves of different ages but was not detected in seeds. TGFβ3 represented 12% of leaf protein and appeared as monomer, dimer and trimer bands on Western blots of SDS-PAGE gels. High yield and insolubility facilitated initial purification and refolding of the 13-kDa polypeptide into the TGFβ3 homodimer recognized by a conformation-dependent monoclonal antibody. The TGFβ3 homodimer and trace amounts of monomer were the only bands visible on silver-stained gels following purification by hydrophobic interaction chromatography and cation exchange chromatography. N-terminal sequencing and electronspray ionization mass spectrometry showed the removal of the initiator methionine and physical equivalence of the chloroplast-produced homodimer to standard TGFβ3. Functional equivalence was demonstrated by near-identical dose-response curves showing the inhibition of mink lung epithelial cell proliferation. We conclude that chloroplasts are an attractive production platform for synthesizing recombinant human TGFβ3.     

Iron Translocation into and out of Listeria innocua Dps and Size Distribution of the Protein-enclosed Nanomineral Are Modulated by the Electrostatic Gradient at the 3-fold ��Ferritin-like�� Pores

Elucidating pore function at the 3-fold channels of 12-subunit, microbial Dps proteins is important in understanding their role in the management of iron/hydrogen peroxide. The Dps pores are called “ferritin-like” because of the structural resemblance to the 3-fold channels of 24-subunit ferritins used for iron entry and exit to and from the protein cage. In ferritins, negatively charged residues lining the pores generate a negative electrostatic gradient that guides iron ions toward the ferroxidase centers for catalysis with oxidant and destined for the mineralization cavity. To establish whether the set of three aspartate residues that line the pores in Listeria innocua Dps act in a similar fashion, D121N, D126N, D130N, and D121N/D126N/D130N proteins were produced; kinetics of iron uptake/release and the size distribution of the iron mineral in the protein cavity were compared. The results, discussed in the framework of crystal growth in a confined space, indicate that iron uses the hydrophilic 3-fold pores to traverse the protein shell. For the first time, the strength of the electrostatic potential is observed to modulate kinetic cooperativity in the iron uptake/release processes and accordingly the size distribution of the microcrystalline iron minerals in the Dps protein population.The widely distributed bacterial Dps proteins (1, 2) belong to the ferritin superfamily and are characterized by strong similarities (3) but also distinctive differences with respect to “canonical” ferritins, the ubiquitous iron storage, and detoxification proteins found in biological systems. The structural resemblance is apparent in the overall molecular assemblage because both Dps proteins and ferritins are shell-like oligomers constructed from four-helix bundle monomers. However, Dps proteins are 12-mers of identical subunits that assemble with 23 symmetry, whereas ferritins are built by 24 highly similar or identical subunits related by 432 symmetry. The functional similarities consist in the common capacity to remove Fe(II) from cytoplasm, catalyze its oxidation, and store Fe(III) thus produced in the protein cavity, wherefrom the metal can be mobilized when required by the organism. However, ferritins use molecular oxygen as iron oxidant with the production of hydrogen peroxide, whereas Dps proteins prefer hydrogen peroxide, which is typically about 100-fold more efficient than molecular oxygen (1). This difference is of major importance because it renders Dps proteins capable of removing concomitantly Fe(II) and H₂O₂ whose combination leads to the production of reactive oxygen species via Fenton chemistry (4). This capacity confers H₂O₂ resistance and hence may be a virulence factor in certain pathogens (e.g. Campylobacter jejuni, Streptococcus mutans, and Porphyromonas gingivalis) because the H₂O₂ burst represents one of the first defense lines of the host during infection (5–7).Key to a full understanding of the iron uptake and release processes at a molecular level is the route by which iron enters and exits the protein shell. In both 24-subunit ferritins and 12-subunit Dps proteins, the subunit assemblage creates pores across the protein shell that put the internal cavity in communication with the external medium. In ferritins there are two types of pores: largely hydrophobic ones along the axes with 4-fold symmetry and hydrophilic ones along the axes with 3-fold symmetry. The latter channels are funnel-shaped, with the smaller opening toward the protein cavity, and are lined with conserved glutamic and aspartic residues located in the narrow region of the funnel (8). These 3-fold pores were recognized to provide the route for iron entry into the protein cavity soon after resolution of the horse ferritin x-ray crystal structure (9). Later site-directed mutagenesis studies defined the role of specific residues (Asp¹³¹ and Glu¹³⁴) that line the pore (10, 11), whereas electrostatic calculations related the passage of iron to the existence of a gradient that drives metal ions toward the protein interior cavity (12, 13). More recently, the 3-fold symmetry pores were shown to be involved also in the exit process of iron from the protein cavity. Thus, in H-frog ferritin used as model system, iron exit is affected by local protein unfolding promoted by site-specific mutagenesis of individual amino acid residues (14, 15), by the use of chaotropes (16), and by means of selected peptides designed to bind at these channels (17).In Dps proteins, the protein shell is breached by two types of pores along the 3-fold axes, one type is formed by the N-terminal portion of the monomers and bears a strong similarity to the typical 3-fold channels of 24-subunit ferritins in that it is funnel-shaped, hydrophilic, and lined by conserved, negatively charged residues. It was therefore named “ferritin-like” and assumed to be involved in iron entry into the protein cavity upon resolution of the Listeria innocua x-ray crystal structure (18). The other type of pore is formed by the C-terminal ends of the monomers and was called “Dps type” because it is created at a subunit interface that is unique to Dps proteins. Although somewhat variable in length and in the size of the openings, the Dps type pore is mainly hydrophobic in nature (19).The present paper investigates the role of the ferritin-like pores in the iron uptake and release processes in Dps proteins using the well characterized L. innocua Dps (LiDps) as a model system (18, 20–22). In LiDps, the ferritin-like pores contain a set of three aspartate residues, Asp¹²¹, Asp¹²⁶, and Asp¹³⁰ that would be encountered in succession by a metal ion that is attracted by the electrostatic gradient they create and moves down the funnel-shaped pore toward the protein cavity (Fig. 1). Asp¹³⁰, which is located in the narrowest part of the funnel, is conserved significantly among Dps proteins (∼ 80%), whereas Asp¹²¹ and Asp¹²⁶ are less conserved (Fig. 1). Such considerations were used in the design of site-specific variants D121N, D126N, D130N, and D121N/D126N/D130N to elucidate the function of the ferritin-like pores in Dps proteins.Open in a separate windowFIGURE 1.Dps proteins sequences and conservation of the aspartate residues that line the 3-fold ferritin-like pores in L. innocua Dps. A, alignment of multiple Dps sequences from different bacteria: LiDps, non-heme iron-binding ferritin (L. innocua Clip11262]; EcDps, DNA-binding protein Dps (E. coli); HpDps, neutrophil-activating protein (Helicobacter pylori); YpDps, ferritin family protein (Yersinia pestis Angola); GtDps, DNA-protecting protein (Geobacillus thermodenitrificans NG80–2); RmDps, ferritin, and Dps (Ralstonia metallidurans CH34); AtDps, DNA protection during starvation conditions (Agrobacterium tumefaciens str. C58); TeDps Dps family DNA-binding stress response protein (Thermosynechococcus elongatus BP-1); PaDps, putative DNA-binding protein, Dps (Psychrobacter arcticus 273-4); TfDps, hypothetical protein Tfu_0799 (Thermobifida fusca YX); PhDps, DNA-binding DPS protein (Pseudoalteromonas haloplanktis TAC125); SoDps, Dps family protein (Shewanella oneidensis MR-1); BaDps1, general stress protein 20U (Bacillus anthracis str. Ames); BaDps2 general stress protein (B. anthracis str. Ames); LlDps, non-heme iron-binding ferritin (Lactococcus lactis subsp. lactis Il1403); VcDps, DPS family protein (Vibrio cholerae MZO-3); and StDps, DNA-binding ferritin-like protein (oxidative damage protectant) (Streptococcus thermophilus LMD-9). Residues forming the Dps catalytic center are highlighted in pale blue (His³¹, His⁴³, Asp⁵⁸, and Glu⁶² in LiDps); 3-fold pores aspartate residues are highlighted in yellow and marked in bold type. Alignment has been created with ClustalW2 (34). B, view of the junction of three monomers forming the 3-fold ferritin-like pore. C, Asp¹²¹, Asp¹²⁶, and Asp¹³⁰ aspartate residues comprised the pore area. D, three-dimensional view of the pore colored by charge. Red, negatively charged residues; blue, positively charged residues; white, uncharged residues. E, schematic representation of the vertical section of the pore. The images were created with PyMol (35).The results demonstrate that iron uses the LiDps ferritin-like pores to enter and leave the protein shell and hence that these pores have the same role as the structurally similar 3-fold channels in 24-subunit ferritins. LiDps residue Asp¹³⁰ is the most important determinant of the negative electrostatic gradient because of its location in the narrow part of the pores. Importantly, the data show for the first time that the electrostatic gradient at the pores modulates cooperativity in the iron uptake process and influences the size distribution of the iron core (23). The effect of the electrostatic gradient can be explained in terms of the electrostatic interaction effects between the fixed negative charges of the aspartate residues at the pores and the mobile positive charges of iron ions.