Upregulation of SIRT1 deacetylase in phenylephrine-treated cardiomyoblasts

Deposition of amyloid fibrils consisting of amyloid β (Aβ) protein as senile plaques in the brain is a pathological hallmark of Alzheimer’s disease. However, a growing body of evidence shows that soluble Aβ oligomers correlate better with dementia than fibrils, suggesting that Aβ oligomers may be the primary toxic species. The structure and oligomerization mechanism of these Aβ oligomers are crucial for developing effective therapeutics. Here we investigated the oligomerization of Aβ42 in the context of a fusion protein containing GroES and ubiquitin fused to the N-terminus of Aβ sequence. The presence of fusion protein partners, in combination with a denaturing buffer containing 8 M urea at pH 10, is unfavorable for Aβ42 aggregation, thus allowing only the most stable structures to be observed. Transmission electron microscopy showed that Aβ42 fusion protein formed globular oligomers, which bound weakly to thioflavin T and Congo red. SDS–PAGE shows that Aβ42 fusion protein formed SDS-resistant hexamers and tetramers. In contrast, Aβ40 fusion protein remained as monomers on SDS gel, suggesting that the oligomerization of Aβ42 fusion protein is not due to the fusion protein partners. Cysteine scanning mutagenesis at 22 residue positions further revealed that single cysteine substitutions of the C-terminal hydrophobic residues (I31, I32, L34, V39, V40, and I41) led to disruption of hexamer and tetramer formation, suggesting that hydrophobic interactions between these residues are most critical for Aβ42 oligomerization.     

Purification of the nitrogenase proteins from Clostridium pasteurianum

A method is described for the purification of the nitrogenase proteins from Clostridium pasteurianum by two polyethylene glycol precipitations and chromatography on columns of DEAE-cellulose, Sephadex G-100 and Sephadex G-200. The Mo-Fe protein and the Fe protein have been purified 70–80-fold from the crude extract, and they appear essentially pure when tested by anaerobic polyacrylamide gel electrophoresis.     

Analysis of the local dynamics of human insulin and a rapid-acting insulin analog by hydrogen/deuterium exchange mass spectrometry

Human insulin and insulin lispro (lispro), a rapid-acting insulin analog, have identical primary structures, except for the transposition of a pair of amino acids. This mutation results in alterations in their higher order structures, with lispro dissociating more easily than human insulin. In our previous study performed using hydrogen/deuterium exchange mass spectrometry (HDX/MS), differences were observed in the rates and levels of deuteration among insulin analog products, which were found to be related to their self-association stability. In this study, we carried out peptide mapping of deuterated human insulin and lispro to determine the regions responsible for these deuteration differences and to elucidate the type of structural changes that affect their HDX reactivity. We identified A3–6 and B22–24 as the 2 regions that showed distinct differences in the number of deuterium atoms incorporated between human insulin and lispro. These regions contain residues that are thought to participate in hexamerization and dimerization, respectively. We also determined that over time, the differences in deuteration levels decreased in A3–6, whereas they increased in B22–24, suggesting a difference in the dynamics between these 2 regions. This article is part of a Special Issue entitled: Mass spectrometry in structural biology.     

Zinc binding catalytic domain of human tankyrase 1

Tankyrases are recently discovered proteins implicated in many important functions in the cell including telomere homeostasis and mitosis. Tankyrase modulates the activity of target proteins through poly(ADP-ribosyl)ation, and here we report the structure of the catalytic poly(ADP-ribose) polymerase (PARP) domain of human tankyrase 1. This is the first structure of a PARP domain from the tankyrase subfamily. The present structure reveals that tankyrases contain a short zinc-binding motif, which has not been predicted. Tankyrase activity contributes to telomere elongation observed in various cancer cells and tankyrase inhibition has been suggested as a potential route for cancer therapy. In comparison with other PARPs, significant structural differences are observed in the regions lining the substrate-binding site of tankyrase 1. These findings will be of great value to facilitate structure-based design of selective PARP inhibitors, in general, and tankyrase inhibitors, in particular.     

The three-dimensional structure of VIM-2, a Zn-beta-lactamase from Pseudomonas aeruginosa in its reduced and oxidised form

The crystal structures of the universally widespread metallo-β-lactamase (MBL) Verona integron-encoded MBL (VIM)-2 from Pseudomonas aeruginosa have been solved in their native form as well as in an unexpected oxidised form. This carbapenem-hydrolysing enzyme belongs to the so-called B1 subfamily of MBLs and shares the folding of αβ/βα sandwich, consisting of a core of β-sheet surrounded by α-helices. Surprisingly, it showed a high tendency to be strongly oxidised at the catalytic cysteine located in the Cys site, Cys221, which, in the oxidised structure, becomes a cysteinesulfonic residue. Its native structure was obtained only in the presence of Tris(2-carboxyethyl)phosphine. This oxidation might be a consequence of a lower affinity for the second Zn located in the Cys site that would also explain the observed susceptibility of VIM-2 to chelating agents. This modification, if present in nature, might play a role in catalytic down-regulation. Comparison between native and oxidised VIM-2 and a predicted model of VIM-1 (which shows one residue different in the Cys site compared with VIM-2) is performed to explain the different activities and antibiotic specificities.     

Effect of Metal Loading and Subcellular pH on Net Charge of Superoxide Dismutase-1

The net charge of a folded protein is hypothesized to influence myriad biochemical processes (e.g., protein misfolding, electron transfer, molecular recognition); however, few tools exist for measuring net charge and this elusive property remains undetermined—at any pH—for nearly all proteins. This study used lysine-acetyl “protein charge ladders” and capillary electrophoresis to measure the net charge of superoxide dismutase-1 (SOD1)—whose aggregation causes amyotrophic lateral sclerosis (ALS)—as a function of coordinated metal ions and pH. The net negative charge of apo-SOD1 was similar to predicted values; however, the binding of a single Zn^2 + or Cu^2 + ion reduced the net negative charge by a greater magnitude than predicted (i.e., ~ 4 units, instead of 2), whereas the SOD1 protein underwent charge regulation upon binding 2–4 metal ions. From pH5 to pH8 (i.e., a range consistent with the multiple subcellular loci of SOD1), the holo-SOD1 protein underwent smaller fluctuations in net negative charge than predicted (i.e., ~ 3 units, instead of ~ 14) and did not undergo charge inversion at its isoelectric point (pI = 5.3) but remained anionic. The regulation of SOD1 net charge along its pathways of metal binding, and across solvent pH, provides insight into its metal-induced maturation and enzymatic activity (which remains diffusion-limited across pH5–8). The anionic nature of holo-SOD1 across subcellular pH suggests that ~ 45 different ALS-linked mutations to SOD1 will reduce its net negative charge regardless of subcellular localization.     

Crocetin inhibits beta-amyloid fibrillization and stabilizes beta-amyloid oligomers

Aggregation of a peptide, beta-amyloid (Aβ), is a hallmark molecular process found in Alzheimer’s disease (AD). During Aβ aggregation, oligomeric and fibrillar Aβ are formed, and these molecular self-assembly steps are implicated in generation of toxic effects in AD. Crocetin is a natural carotenoid dicarboxyl acid displaying various pharmaceutical effects and may be co-localized with Aβ mediated by human serum albumin. In the study presented here, we examined the effects of crocetin on Aβ aggregation in three different molecular pathways. Our results demonstrate that crocetin inhibited Aβ fibril formation and destabilized pre-formed Aβ fibrils. Moreover, crocetin caused stabilization of Aβ oligomers and prevented their conversion into Aβ fibrils. Our study reveals potential pathological and pharmaceutical implication of crocetin in AD and suggests possible application of crocetin for currently limited structural studies on unstable Aβ oligomers.     

Tea contains potent inhibitors of tyrosine phosphatase PTP1B

Tea is widely consumed all over the world. Studies have demonstrated the role of tea in prevention and treatment of various chronic diseases including diabetes and obesity, but the underlying mechanism is unclear. PTP1B is a widely expressed tyrosine phosphatase which has been defined as a target for therapeutic drug development to treat diabetes and obesity. In screening for inhibitors of PTP1B, we found that aqueous extracts of teas exhibited potent PTP1B inhibitory effects with an IC50 value of 0.4–4 g dry tea leaves per liter of water. Black tea shows the strongest inhibition activities, followed by oolong and then by green tea. Biochemical fractionations demonstrated that the major effective components in tea corresponded to oxidized polyphenolic compounds. This was further verified by the fact that tea catechins became potent inhibitors of PTP1B upon oxidation catalyzed by tyrosinases. When applied to cultured cells, tea extracts induced tyrosine phosphorylation of cellular proteins. Our study suggests that some beneficial effects of tea may be attributed to the inhibition of PTP1B.     

Reversible heat inactivation of copper sites precedes thermal unfolding of molluscan (Rapana thomasiana) hemocyanin

Hemocyanin (Hc) is a type-3 copper protein, containing dioxygen-binding active sites consisting of paired copper atoms. In the present study the thermal unfolding of the Hc from the marine mollusc Rapana thomasiana (RtH) has been investigated by combining differential scanning calorimetry, Fourier transform infrared (FTIR) and UV–vis absorption spectroscopy. Two important stages in the unfolding pathway of the Hc molecule were discerned. A first event, with nonmeasurable heat absorption, occurring around 60 °C, lowers the binding of dioxygen to the type-3 copper groups. This pretransition is reversible and is ascribed to a slight change in the tertiary structure. In a second stage, with midpoint around 80 °C, the protein irreversibly unfolds with a loss of secondary structure and formation of amorphous aggregates. Experiments with the monomeric structural subunits, RtH1 and RtH2, indicated that the heterogeneity in the process of thermal denaturation can be attributed to the presence of multiple 50 kDa functional units with different stability. In accordance, the irreversible unfolding of a purified functional unit (RtH2-e) occurred at a single transition temperature. At slightly alkaline pH (Tris buffer) the C-terminal β-sheet rich domain of the functional unit starts to unfold before the α-helix-rich N-terminal (copper containing) domain, triggering the collapse of the global protein structure. Even around 90 °C some secondary structure is preserved as shown by the FTIR spectra of all investigated samples, confirming the high thermostability of molluscan Hc.     

Control of the pyridine nucleotide-linked Ca release from mitochondria by respiratory substrates

Oxidation of mitochondrial pyridine nucleotides followed by their hydrolysis promotes Ca²⁺ release from intact liver mitochondria. In most of the previous studies oxidation was achieved with pro-oxidants which were added to mitochondria respiring on succinate in the presence of rotenone, a site I-specific inhibitor of the respiratory chain. Here we investigate pro-oxidant dependent and independent Ca²⁺ release from mitochondria when respiration is supported either by the NAD⁺-linked substrate β-hydroxybutyrate, or by succinate. In the presence, as well as in the absence, of the pro-oxidant t-butylhydroperoxide mitochondria retain Ca²⁺ much better with succinate than with β-hydroxybutyrate, as respiratory substrate. When Ca²⁺ release is induced by t-butylhydroperoxide succinate-supported Ca²⁺ retention is impeded by rotenone. Ca²⁺ release (pro-oxidant dependent or independent) is paralleled by oxidation and hydrolysis of intramitochondrial pyridine nucleotides, and Ca²⁺ retention is paralleled by reduction of pyridine nucleotides. It is concluded that the pyridine nucleotide-linked Ca²⁺ release from mitochondria can be controlled by respiratory substrates which regulate the intramitochondrial hydrolysis of oxidized pyridine nucleotides.     

Starch-binding domain-containing protein 1 (Stbd1) and glycogen metabolism: Identification of the Atg8 family interacting motif (AIM) in Stbd1 required for interaction with GABARAPL1

Glycogen, a branched polymer of glucose, acts as an intracellular carbon and energy reserve in many tissues and cell types. An important pathway for its degradation is by transport to lysosomes in an autophagy-like process. It has been proposed that starch-binding domain-containing protein 1 (Stbd1) may participate in this mechanism by anchoring glycogen to intracellular membranes. In addition, Stbd1 has been reported to interact with a known autophagy protein, GABARAPL1, a member of the Atg8 family. Here, we confirm this interaction and identify an Atg8 interacting motif (AIM) in Stbd1 necessary for GABARAPL1 binding as judged by co-immunoprecipitation from cell extracts and co-localization in cells as evidenced by immunofluorescence microscopy. The AIM sequence of Stbd1 ²⁰⁰HEEWEMV²⁰⁶ lies within a predicted disordered region of the molecule and fits the consensus of other AIM sequences in cargo-specifying proteins such as p62 and Nix. Mutation of the AIM, including single point mutations of either W203 or V206, eliminated the co-localization of Stbd1 with both over-expressed and endogenous GABARAPL1. Stbd1 may therefore function as a novel cargo binding protein that delivers glycogen to lysosomes in an autophagic pathway that could be termed “glycophagy”.     

The effect of diaminodurene on the delayed light and the carotenoid band shift in Rhodopseudomonas spheroides

1. When 2,3,5,6-tetramethyl-p-phenylenediamine (diaminodurene), which is an activator of cyclic electron flow, was added to chromatophores isolated from the photosynthetic bacterium, Rhodopseudomonas spheroides, it caused a large increase in the emission of delayed light measured at 5–10 ms after excitation. This increase was pH dependent, and ranged from 5–100 times the control intensity. Substances that counteract light-induced proton uptake, such as ammonium salts, amines and nigericin, caused a further increase in the delayed light emission. These compounds also markedly slowed a characteristic decline of the delayed light that occurs during sustained illumination. This decline in the delayed light may be related to the quenching of prompt fluorescence that is seen in the presence of diaminodurene. Substances, like valinomycin, that dissipate the membrane potential, almost completely abolish the diaminodurene-catalyzed increase in the delayed light.     

Zinc induced folding is essential for TIM15 activity as an mtHsp70 chaperone

Background

TIM15/Zim17 in yeast and its mammalian ortholog Hep are Zn^2 + finger (Cys4) proteins that assist mtHsp70 in protein import into the mitochondrial matrix.

Methods

Here we characterized the Zn^2 + induced TIM15 folding integrating biophysical and computational approaches.

Results

TIM15 folding occurs from an essentially unstructured conformation to a Zn^2 +-coordinated protein in a fast and markedly temperature-dependent process. Moreover, we demonstrate unambiguously that Zn^2 + induced TIM15 folding is essential for its role as mtHsp70 chaperone since in the unstructured apo state TIM15 does not bind to mtHsp70 and is unable to prevent its aggregation. Molecular dynamics simulations help to understand the crucial role of Zn^2 + in promoting a stable and functional 3D architecture in TIM15. It is shown that the metal ion, through its coordinating cysteine residues, can mediate relevant long-range effects with the interaction interface for mtHsp70 coupling thus folding and function.

Conclusions

Zn^2 + induced TIM15 folding is essential for its function and likely occurs in mitochondrial matrix where high concentrations of Zn^2 + were reported.

General significance

The combination of experimental and computational approaches presented here provide an integrated structural, kinetic and thermodynamic view of the folding of a mitochondrial zinc finger protein, which might be relevant to understand the organelle import of proteins sharing this fold.     

RNase and DNase activities in the alfalfa and lentil grown in iso-osmotic solutions of NaCl and mannitol

Nucleolytic activities from two plants of Leguminosae family were determined in order to consider if the nucleases of plants which belong to the same family or to the same species responded in similar ways to stress conditions during growth. Growth parameters of both plants were examined in parallel. In detail, seedlings from two plants, alfalfa (Medicago sativa L. cv. Luzerne Euver) and lentil (Lens culinaris cv. Thessalia), showed significant differences in response to iso-osmotic solutions of NaCl (100 mmol · L⁻¹ solution equivalent to conductivity 8.0 dS m⁻¹) and mannitol (190 mmol · kg⁻¹). Plant height and dry weight of mannitol/NaCl-treated seeds in both plants were lower in comparison to controls (water). Mannitol stress reduced height and dry weight in alfalfa seedlings more than did NaCl. By contrast, lentil seedling growth was inhibited more by NaCl stress than mannitol. In addition, DNase and RNase response to mannitol stress differed in each plant compared to the controls. Mannitol stress induced a sharp increase in DNase- and RNase-specific activity during the initial stages of alfalfa seedlings' growth, followed by a decrease during subsequent days; in lentil seedlings, these activities were inhibited throughout the entire growth period. NaCl stress inhibited the above activities in both plants. After native electrophoresis on gels polymerized in the presence of DNA/RNA, the overall band intensities confirmed the above quantitative results of alfalfa RNase and DNase activity. In addition, the active gel analysis revealed that the decrease of nucleolytic activities in mannitol-treated alfalfa seedlings was mainly due to the strong reduction of acid nucleases. This is the first report of different non-ionic osmotic response of type I plant nucleases during seedlings' growth. In vitro, the addition of up to 300 mmol/L mannitol did not affect acid and neutral nuclease activity in enzyme preparations extracted, purified, and separated from control and mannitol-treated alfalfa seedlings.Our results suggest that plant nucleases responded in a different way to osmotic stress and ionic stress conditions during seedlings' growth.     

Elastic rotation of Escherichia coli FOF1 having ε subunit fused with cytochrome b562 or flavodoxin reductase

Intra-molecular rotation of F_OF₁ ATP synthase enables cooperative synthesis and hydrolysis of ATP. In this study, using a small gold bead probe, we observed fast rotation close to the real rate that would be exhibited without probes. Using this experimental system, we tested the rotation of F_OF₁ with the ε subunit connected to a globular protein [cytochrome b₅₆₂ (ε-Cyt) or flavodoxin reductase (ε-FlavR)], which is apparently larger than the space between the central and the peripheral stalks. The enzymes containing ε-Cyt and ε-FlavR showed continual rotations with average rates of 185 and 148 rps, respectively, similar to the wild type (172 rps). However, the enzymes with ε-Cyt or ε-FlavR showed a reduced proton transport. These results indicate that the intra-molecular rotation is elastic but proton transport requires more strict subunit/subunit interaction.     

Control of RecBCD Enzyme Activity by DNA Binding- and Chi Hotspot-Dependent Conformational Changes

Faithful repair of DNA double-strand breaks by homologous recombination is crucial to maintain functional genomes. The major Escherichia coli pathway of DNA break repair requires RecBCD enzyme, a complex protein machine with multiple activities. Upon encountering a Chi recombination hotspot (5′ GCTGGTGG 3′) during DNA unwinding, RecBCD's unwinding, nuclease, and RecA-loading activities change dramatically, but the physical basis for these changes is unknown. Here, we identify, during RecBCD's DNA unwinding, two Chi-stimulated conformational changes involving RecC. One produced a marked, long-lasting, Chi-dependent increase in protease sensitivity of a small patch, near the Chi recognition domain, on the solvent-exposed RecC surface. The other change was identified by crosslinking of an artificial amino acid inserted in this RecC patch to RecB. Small-angle X-ray scattering analysis confirmed a major conformational change upon binding of DNA to the enzyme and is consistent with these two changes. We propose that, upon DNA binding, the RecB nuclease domain swings from one side of RecC to the other; when RecBCD encounters Chi, the nuclease domain returns to its initial position determined by crystallography, where it nicks DNA exiting from RecC and loads RecA onto the newly generated 3′-ended single-stranded DNA during continued unwinding; a crevice between RecB and RecC increasingly narrows during these steps. This model provides a physical basis for the intramolecular “signal transduction” from Chi to RecC to RecD to RecB inferred previously from genetic and enzymatic analyses, and it accounts for the enzymatic changes that accompany Chi's stimulation of recombination.