Thrombin cleaves recombinant soluble thrombomodulin into a lectin-like domain fragment and a fragment with protein C-activating cofactor activity.

Thrombomodulin (TM) is a transmembrane protein that plays an important role in regulating the coagulation system by acting as a cofactor for thrombin in protein C activation. Additionally, TM is involved in inflammation. Previous studies have shown that soluble fragments of TM of varying sizes, which are derived from membrane-bound TM, are present in plasma and urine. Soluble fragments of TM are speculated to exhibit biological activity. Among these, a lectin-like domain fragment (TMD1) is of particular importance. Recombinant TMD1 has previously been shown to attenuate lipopolysaccharide-induced inflammation. Here, we report that thrombin cleaves recombinant soluble TM, which is used for the treatment of disseminated intravascular coagulation associated with sepsis, into TMD1 and a fragment comprising the C-terminal portion of TM (TMD23), the latter of which retains the cofactor activity for activating protein C. Our findings suggest that thrombin not only activates protein C on membrane-bound TM but may also cleave TM to generate TMD1.

Ultrasensitive Change in Nucleosome Binding by Multiple Phosphorylations to the Intrinsically Disordered Region of the Histone Chaperone FACT.

Facilitates chromatin transcription (FACT) is a histone chaperone that functions as a nucleosome remodeler and a chaperone. The two subunits of FACT, Spt16 and SSRP1, mediate multiple interactions between the subunits and components of the nucleosome. Among the interactions, the role of the DNA-binding domain in SSRP1 has not been characterized. We reported previously that the DNA-binding domain in Drosophila SSRP1 (dSSRP1) has multiple casein kinase II phosphorylation sites, and the DNA binding affinity of the domain changes sigmoidally in response to the degree of phosphorylation ("ultrasensitive response"). In this report, we explored the molecular mechanisms for the ultrasensitive response of the DNA-binding domain in dSSRP1 using the shortest fragment (AB-HMG, residues 434-624) responsible for nucleosome binding. AB-HMG contains two intrinsically disordered (ID) regions: the N-terminal part rich in acidic residues (AID) and the C-terminal part rich in basic residues (BID) followed by the HMG box. NMR and coarse-grained molecular dynamics simulations revealed a phosphorylation-dependent change in intramolecular contacts between the AID and BID-HMG, which is mediated by a hinge bending motion of AB-HMG to enable the ultrasensitive response. Ultrasensitivity generates two distinct forms of dSSRP1, which are high- and low-affinity nucleosome-binding forms. Drosophila FACT (dFACT) switches function according to the degree of phosphorylation of the AID in dSSRP1. We propose that dFACT in various phosphorylation states functions cooperatively to facilitate gene regulation in the context of the chromatin.

Target protein-oriented isolation of Hes1 dimer inhibitors using protein based methods.

Natural products isolation using protein based methods is an attractive for obtaining bioactive compounds. To discover neural stem cell (NSC) differentiation activators, we isolated eight inhibitors of Hes1 dimer formation from Psidium guajava using the Hes1-Hes1 interaction fluorescent plate assay and one inhibitor from Terminalia chebula using the Hes1-immobilized beads method. Of the isolated compounds, gallic acid (8) and 4-O-(4"-O-galloyl-α-L-rhamnopyranosyl)ellagic acid (11) showed potent Hes1 dimer formation inhibitory activity, with IC50 values of 10.3 and 2.53 µM, respectively. Compound 11 accelerated the differentiation activity of C17.2 NSC cells dose dependently, increasing the number of neurons with a 125% increase (5 µM) compared to the control.

Phosphorylation-coupled intramolecular dynamics of unstructured regions in chromatin remodeler FACT.

The intrinsically disordered region (IDR) of a protein is an important topic in molecular biology. The functional significance of IDRs typically involves gene-regulation processes and is closely related to posttranslational modifications such as phosphorylation. We previously reported that the Drosophila facilitates chromatin transcription (FACT) protein involved in chromatin remodeling contains an acidic ID fragment (AID) whose phosphorylation modulates FACT binding to nucleosomes. Here, we performed dynamic atomic force microscopy and NMR analyses to clarify how the densely phosphorylated AID masks the DNA binding interface of the high-mobility-group domain (HMG). Dynamic atomic force microscopy of the nearly intact FACT revealed that a small globule temporally appears but quickly vanishes within each mobile tail-like image, corresponding to the HMG-containing IDR. The lifespan of the globule increases upon phosphorylation. NMR analysis indicated that phosphorylation induces no ordered structure but increases the number of binding sites in AID to HMG with an adjacent basic segment, thereby retaining the robust electrostatic intramolecular interaction within FACT even in the presence of DNA. These data lead to the conclusion that the inhibitory effect of nucleosome binding is ascribed to the increase in the probability of encounter between HMG and the phosphorylated IDR.

Exchangeability of the flagellin (FliC) and the cap protein (FliD) among different species in flagellar assembly.

Flagellar filament self-assembles from the component protein, flagellin or FliC, with the aid of the capping protein, HAP2 or FliD. Depending on the helical parameters of filaments, flagella from various species are divided into three groups, family I, II, and III. Each family coincides with the traditional classification of flagella, peritrichous flagella, polar flagella, and lateral flagella, respectively. To elucidate the physico-chemical properties of flagellin to separate families, we chose family I flagella and family II flagella and examined how well the exchangeability of a combination of FliC and/or FliD from different families is kept in filament formation. FliC or FliD of Salmonella enterica serovar Typhimurium (Salty; family I) were exchanged with those of Escherichia coli (Escco; family I) or Pseudomonas aeruginosa (Pseae; family II). In a Salty fliC deletion mutant, Escco FliC formed short filaments, but Pseae FliC did not form filaments. In a Salty fliD deletion mutant, both Escco FliD and Pseae FliD allowed Salty FliC to polymerize into short filaments. In conclusion, FliC can be exchanged among the same family but not between different families, while FliD serves as the cap protein even in different families, confirming that FliC is essential for determining families, but FliD plays a subsidiary role in filament formation.

The hydrophobic core of FliG domain II is the stabilizer in the Salmonella flagellar motor.

The flagellar protein FliG is the major component of the flagellar torque generator, and consists of two separate domains, I and II. Domain I is essential for flagellar assembly, while domain II in the C-terminal region is not essential for flagellar assembly but is dedicated to torque generation. Previously, we found that some fliG mutants were temperature-hypersensitive (hyper-TS) and identified three residues (F236V, D244Y and K273E) on domain II responsible for the temperature-sensitive (TS) phenotype. In this study, we substituted the three residues with all 20 amino acids (X) and analysed the behaviour of the variants at various temperatures. Each group of F236X, D244X and K273X variants gave rise to several hyper-TS mutants. In F236X, only substitution with F and W gave rise to wild-type, while other hydrophobic residues resulted in hyper-TS mutants and hydrophilic residues resulted in non-motile variants. The atomic arrangement around the F236 residue indicated that F236 together with neighbouring residues forms a hydrophobic core in the centre of domain II, which is well conserved among many species. These data suggest that the hydrophobic core may play an essential role in stabilizing the whole structure of domain II, so that changes of physiological conditions in the microenvironment of domain II do not perturb torque generation.

Functional roles of the hook in a rotating tethered cell.

A bacterial cell tethered through a flagellum on a glass slide rotates its cell body in either counter-clockwise or clockwise at around 10 Hz. To analyze the detailed manner of rotation, we have constructed and expressed yellow fluorescent protein (YFP)-FliN fusion protein in a fliN deletion mutant, resulting in the recovery of motility of the Fla(-) mutant cells. The tethered cells that incorporated the fusion protein in the flagellar motor rotate around one of the fluorescent spots. Tracing the center spot of a rotating cell, we have found that the rotating circles of the tethered cells were often distorted, and that the cell has seldom rotated smoothly but gyrated around the center point. The radii of the gyrating circles were 100-200 nm for the wild-type cells, and 50 nm for the cells carrying short hooks, suggesting that the flexibility of the hook is responsible for asymmetrical rotation. These observations indicate that tethered cells almost always interact with the glass surface in one cycle of rotation, where the length and flexibility of the hook have an important role.

Temperature-hypersensitive sites of the flagellar switch component FliG in Salmonella enterica serovar typhimurium.

Three flagellar proteins, FliG, FliM, and FliN (FliGMN), are the components of the C ring of the flagellar motor. The genes encoding these proteins are multifunctional; they show three different phenotypes (Fla(-), Mot(-), and Che(-)), depending on the sites and types of mutations. Some of the Mot(-) mutants previously characterized are found to be motile. Reexamination of all Mot(-) mutants in fliGMN genes so far studied revealed that many of them are actually temperature sensitive (TS); that is, they are motile at 20 degrees C but nonmotile at 37 degrees C. There were two types of TS mutants: one caused a loss of function that was not reversed by a return to the permissive temperature (rigid TS), and the other caused a loss that was reversed (hyper-TS). The rigid TS mutants showed an all-or-none phenotype; that is, once a structure was formed, the structure and function were stable against temperature shifts. All of fliM and fliN and most of the fliG TS mutants belong to this group. On the other hand, the hyper-TS mutants (three of the fliG mutants) showed a temporal swimming/stop phenotype, responding to temporal temperature shifts when the structure was formed at a permissive temperature. Those hyper-TS mutation sites are localized in the C-terminal domain of the FliG molecules at sites that are different from the previously proposed functional sites. We discuss a role for this new region of FliG in the torque generation of the flagellar motor.

Novel metabolism of nitrogen in plants.

Our previous study showed that approximately one-third of the nitrogen of 15N-labeled NO2 taken up into plants was converted to a previously unknown organic nitrogen (hereafter designated UN) that was not recoverable by the Kjeldahl method (Morikawa et al., 2004). In this communication, we discuss metabolic and physiological relevance of the UN based on our newest experimental results. All of the 12 plant species were found to form UN derived from NO2 (about 10-30% of the total nitrogen derived from NO2). The UN was formed also from nitrate nitrogen in various plant species. Thus, UN is a common metabolite in plants. The amount of UN derived from NO2 was greatly increased in the transgenic tobacco clone 271 (Vaucheret et al., 1992) where the activity of nitrite reductase is suppressed less than 5% of that of the wild-type plant. On the other hand, the amount of this UN was significantly decreased by the overexpression of S-nitrosoglutathione reductase (GSNOR). These findings strongly suggest that nitrite and other reactive nitrogen species are involved in the formation of the UN, and that the UN-bearing compounds are metabolizable. A metabolic scheme for the formation of UN-bearing compounds was proposed, in which nitric oxide and peroxynitrite derived from NO2 or endogenous nitrogen oxides are involved for nitrosation and/or nitration of organic compounds in the cells to form nitroso and nitro compounds, including N-nitroso and S-nitroso ones. Participation of non-symbiotic haemoglobin bearing peroxidase-like activity (Sakamoto et al., 2004) and GSNOR (Sakamoto et al., 2002) in the metabolism of the UN was discussed. The UN-bearing compounds identified to date in the extracts of the leaves of Arabidopsis thaliana fumigated with NO2 include a delta2-1,2,3-thiadiazoline derivative (Miyawaki et al., 2004) and 4-nitro-beta-carotene.

Three distinct Arabidopsis hemoglobins exhibit peroxidase-like activity and differentially mediate nitrite-dependent protein nitration.

All plants examined to date possess non-symbiotic hemoglobin whose physiological role remains unclear. The present study explored the catalytic function of three representative classes of the plant hemoglobin from Arabidopsis thaliana: AtGLB1, AtGLB2, and AtGLB3. Purified recombinant proteins of these hemoglobins displayed hydrogen peroxide-dependent oxidation of several peroxidase substrates that was sensitive to cyanide, revealing intrinsic peroxidase-like activity. In the presence of nitrite and hydrogen peroxide, AtGLB1 was the most efficient at mediating tyrosine nitration of its own and other proteins via the formation of reactive nitrogen species as a result of nitrite oxidation. AtGLB1 mRNA significantly accumulated in Arabidopsis seedlings exposed to nitrite, supporting the physiological relevance of its function to nitrite and nitrite-derived reactive nitrogen species.

Functional complementation in yeast reveals a protective role of chloroplast 2-Cys peroxiredoxin against reactive nitrogen species.

The importance of nitric oxide (NO) as a signaling molecule to various plant physiological and pathophysiological processes is becoming increasingly evident. However, little is known about how plants protect themselves from nitrosative and oxidative damage mediated by NO and NO-derived reactive nitrogen species (RNS). Peroxynitrite, the product of the reaction between NO and superoxide anion, is considered to play a central role in RNS-induced cytotoxicity, as a result of its potent ability to oxidize diverse biomolecules. Employing heterologous expression in bacteria and yeast, we investigated peroxynitrite-scavenging activity in plants of 2-Cys peroxiredoxin (2CPRX), originally identified as a hydroperoxide-reducing peroxidase that is ubiquitously distributed among organisms. The putative mature form of a chloroplast-localized 2CPRX from Arabidopsis thaliana was overproduced in Escherichia coli as an amino-terminally hexahistidine-tagged fusion protein. The purified recombinant 2CPRX, which was catalytically active as peroxidase, efficiently prevented the peroxynitrite-induced oxidation of a sensitive compound. We also examined in vivo the ability of the Arabidopsis 2CPRX to complement the 2CPRX deficiency of a Saccharomyces cerevisiae mutant. Functional expression in the mutant strain of the Arabidopsis 2CPRX not only increased cellular tolerance to hydrogen peroxide, but also complemented the hypersensitive growth defect induced by nitrite-mediated cytotoxicity. The complemented cells significantly enhanced the capacity to reduce RNS-mediated oxidative damages. The results presented here demonstrate a new role of plant 2CPRX as a critical determinant of the resistance to RNS, and support the existence of a plant enzymatic basis for RNS metabolism.