Contribution of endogenous G-protein-coupled receptor kinases to Ser129 phosphorylation of α-synuclein in HEK293 cells

The majority of α-synuclein (αS) deposited in Lewy bodies, the pathological hallmark of Parkinson’s disease (PD), is phosphorylated at serine 129 (Ser129). Ser129 phosphorylation of αS has been demonstrated to enhance the αS toxicity to dopaminergic neurons in a Drosophila model of PD. Phosphorylation of αS at Ser129 seems to play a crucial role in the pathogenesis of PD. Here, we assessed the contribution of ubiquitously expressing members of the G-protein-coupled receptor kinase family (GRK2, GRK3, GRK5, and GRK6) to Ser129 phosphorylation of αS in HEK293 cells. To selectively reduce the endogenous expression of each member of the GRK family in cells, we used small interfering RNAs. Knockdown of GRK3 or GRK6 significantly decreased Ser129 phosphorylation of αS; however, knockdown of GRK2 or GRK5 did not decrease αS phosphorylation. The results indicate that endogenous GRK3 and GRK6, but not GRK2 or GRK5, contribute to Ser129 phosphorylation of αS in HEK293 cells.     

Identification of aquaporin-5 and lipid rafts in human resting saliva and their release into cevimeline-stimulated saliva

BACKGROUND: It is unknown whether AQP5 and lipid rafts are released into human unstimulated (resting) saliva and saliva in response to secretagogues. METHODS: In order to quantitate the salivary concentration of AQP5, we produced a polyclonal antibody for human AQP5 and developed an enzyme-like immunosorbent assay (ELISA). RESULTS: AQP5 and lipid rafts were identified in human resting saliva. The amount of AQP5 in resting saliva showed a diurnal variation with high levels during waking hours, and an age-related decrease in AQP5 was coincident with the volume of resting saliva. Cevimeline, a muscarinic acetylcholine receptor (mAChR) agonist, induced the release of AQP5 with lipid rafts, amylase, mucin, and lysozyme. Changes in saliva AQP5 levels after cevimeline administration occurred simultaneously with changes in saliva flow rates. Confocal microscopy revealed that AQP5 was located in the apical plasma membrane and showed a diffuse pattern in parotid glands under resting conditions. Following cevimeline administration, AQP5 was predominantly associated with the APM and was localized in the lumen. GENERAL SIGNIFICANCE: AQP5 and lipid rafts were released with salivary proteins from human salivary glands by the stimulation of M3 mAChRs, and that changes in saliva AQP5 levels can be used as an indicator of salivary flow rate and also as a useful index of M3 mAChR agonist's action on human salivary glands.     

Glycosaminoglycan affinity of the complete fibroblast growth factor family

BACKGROUND: Many fibroblast growth factor family proteins (FGFs) bind to the heparan sulfate/heparin (HP) subtypes of sulfated glycosaminoglycans (GAGs), and a few have recently been reported to also interact with chondroitin sulfate (CS), another sulfated GAG subtype. METHODS: To gain additional insight into this interaction, we prepared all currently known FGFs (i.e., FGF1-FGF23) and assessed their affinity for HP, CS-B, CS-D and CS-E. In addition, midkine, hepatocyte growth factor and pleiotrophin were studied as other known HP-binding proteins. RESULTS: We found that members of the FGF19 subfamily (i.e., FGF15, 19, 21 and 23) had little or no affinity for HP; all of the other secretable growth factors tested had strong affinities for HP, as was indicated by the finding that their elution from HP-Sepharose columns required 1.0-1.5 M NaCl. We also found that FGF3, 6, 8 and 22 had strong affinities for CS-E, while FGF5 had a moderate affinity for CS-D. The interactions between FGFs and GAGs thus appear to be more diverse than previously understood. GENERAL SIGNIFICANCE: This is noteworthy, as the differential interactions of these growth factors with GAGs may be key determinants of their specific biological activities.     

Characterization of Three ��-Galactoside Phosphorylases from Clostridium phytofermentans: DISCOVERY OF d-GALACTOSYL-��1��4-l-RHAMNOSE PHOSPHORYLASE*

We characterized three d-galactosyl-β1→3-N-acetyl-d-hexosamine phosphorylase (EC 2.4.1.211) homologs from Clostridium phytofermentans (Cphy0577, Cphy1920, and Cphy3030 proteins). Cphy0577 and Cphy3030 proteins exhibited similar activity on galacto-N-biose (GNB; d-Gal-β1→3-d-GalNAc) and lacto-N-biose I (LNB; d-Gal-β1→3-d-GlcNAc), thus indicating that they are d-galactosyl-β1→3-N-acetyl-d-hexosamine phosphorylases, subclassified as GNB/LNB phosphorylase. In contrast, Cphy1920 protein phosphorolyzed neither GNB nor LNB. It showed the highest activity with l-rhamnose as the acceptor in the reverse reaction using α-d-galactose 1-phosphate as the donor. The reaction product was d-galactosyl-β1→4-l-rhamnose. The enzyme also showed activity on l-mannose, l-lyxose, d-glucose, 2-deoxy-d-glucose, and d-galactose in this order. When d-glucose derivatives were used as acceptors, reaction products were β-1,3-galactosides. Kinetic parameters of phosphorolytic activity on d-galactosyl-β1→4-l-rhamnose were k_cat = 45 s⁻¹ and K_m = 7.9 mm, thus indicating that these values are common among other phosphorylases. We propose d-galactosyl-β1→4-l-rhamnose phosphorylase as the name for Cphy1920 protein.Phosphorylases are a group of enzymes involved in formation and cleavage of glycoside linkage together with glycoside hydrolases and glycosyl-nucleotide glycosyltransferases (synthases). Phosphorylases, which reversibly phosphorolyze oligosaccharides to produce monosaccharide 1-phosphate, are generally intracellular enzymes showing strict substrate specificity. Physiologically, such strict substrate specificity is considered to be closely related to the environment containing bacteria possessing them. For example, d-galactosyl-β1→3-N-acetyl-d-hexosamine phosphorylase (GalHexNAcP²; EC 2.4.1.211) from Bifidobacterium longum, an intestinal bacterium, forms part of the pathway metabolizing galacto-N-biose (GNB; d-Gal-β1→3-d-GalNAc) from mucin and lacto-N-biose I (LNB; d-Gal-β1→3-d-GlcNAc) from human milk oligosaccharides, both of which are present in the intestinal environment, with GNB- and LNB-releasing enzymes and GNB/LNB transporter (1–8). Another example is cellobiose phosphorylase from Cellvibrio gilvus, which is a cellulolytic bacterium. Cellobiose phosphorylase forms an important cellulose metabolic pathway with an extracellular cellulase system producing cellobiose (9, 10).The reversible catalytic reaction of phosphorylases is one of the most remarkable features that make them suitable catalysts for practical syntheses of oligosaccharides. An oligosaccharide can be produced from inexpensive material by combining reactions of two phosphorylases, one for phosphorolyzing the material and the other for synthesizing the oligosaccharide, in one pot. Based on this idea, LNB is synthesized on a large (kg) scale using sucrose phosphorylase and GalHexNAcP (11). Practical synthesis methods of trehalose and cellobiose have also been developed (12, 13). However, only 14 kinds of substrate specificities have been reported among phosphorylases (13), thus restricting their use. Therefore, it would be useful to find a phosphorylase with novel activity.GalHexNAcP phosphorolyzes GNB and LNB to produce α-d-galactose 1-phosphate (Gal 1-P) and the corresponding N-acetyl-d-hexosamine. To date, GalHexNAcP is the only phosphorylase known to act on β-galactoside. This enzyme was first found in the cell-free extract of Bifidobacterium bifidum (14) and then in B. longum (1, 15), Clostridium perfringens (16), Propionibacterium acnes (17), and Vibrio vulnificus (18). These studies revealed that GalHexNAcPs were classified into three subgroups based on substrate preference between GNB and LNB. These subgroups are as follows: 1) galacto-N-biose/lacto-N-biose I phosphorylase (GLNBP), showing similar activity on both GNB and LNB (B. longum and B. bifidum); 2) galacto-N-biose phosphorylase (GNBP), preferring GNB to LNB (C. perfringens and P. acnes); and 3) lacto-N-biose I phosphorylase (LNBP), preferring LNB to GNB (V. vulnificus) (18). The ternary structure of GLNBP from B. longum (GLNBP_Bl) has been revealed recently (19). Based on the similarity in ternary structures between GLNBP_Bl and β-galactosidase from Thermus thermophilus, which belongs to glycoside hydrolase family 42 (19, 20), GalHexNAcP homologs are classified as GH112 (glycoside hydrolase family 112), although phosphorylases are glycosyltransferases (21, 22).Clostridium phytofermentans is an anaerobic cellulolytic bacterium. It is found in soil and grows optimally at 37 °C (23). Its whole genome sequence has been revealed (GenBank^TM accession number {"type":"entrez-nucleotide","attrs":{"text":"CP000885","term_id":"160426828","term_text":"CP000885"}}CP000885). The bacterium possesses three GalHexNAcP homologous genes (cphy0577, cphy1920, and cphy3030 genes; GenBank^TM accession numbers are {"type":"entrez-protein","attrs":{"text":"ABX40964.1","term_id":"160427401","term_text":"ABX40964.1"}}ABX40964.1, {"type":"entrez-protein","attrs":{"text":"ABX42289.1","term_id":"160428726","term_text":"ABX42289.1"}}ABX42289.1, and {"type":"entrez-protein","attrs":{"text":"ABX43387.1","term_id":"160429824","term_text":"ABX43387.1"}}ABX43387.1, respectively). C. phytofermentans has the ability to utilize a wide range of plant polysaccharides (23), and substrate specificities of these three gene products (Cphy0577, Cphy1920, and Cphy3030 proteins) are considered to be responsible for this ability. Furthermore, the three proteins have not been clearly categorized as GLNBP, GNBP, or LNBP, based on the phylogenetic tree shown in Fig. 1.Open in a separate windowFIGURE 1.Phylogenetic tree of GalHexNAcP homologs in GH112. Multiple alignment was performed using ClustalW2 (available on the World Wide Web). A phylogenetic tree was constructed using Treeview version 1.6.6. The proteins characterized in this study are represented with boldface letters in boxes with a heavy outline. The other proteins are numbered serially in boxes. Characterized GLNBP, GNBP, and LNBP are represented with boldface black letters on a gray background, boldface white letters on a gray background, and boldface white letters on a black background, respectively. Organisms and GenBank^TM accession numbers of numbered proteins are as follows: 1, CPF0553 (C. perfringens ATCC13124, {"type":"entrez-protein","attrs":{"text":"ABG83511.1","term_id":"110674524","term_text":"ABG83511.1"}}ABG83511.1) (16); 2, CPE0573 (C. perfringens str.13, {"type":"entrez-protein","attrs":{"text":"BAB80279.1","term_id":"18144232","term_text":"BAB80279.1"}}BAB80279.1); 3, CPR0537 (C. perfringens SM101, {"type":"entrez-protein","attrs":{"text":"ABG86710.1","term_id":"110683340","term_text":"ABG86710.1"}}ABG86710.1); 4, LnpA2 (B. bifidum JCM1254, {"type":"entrez-protein","attrs":{"text":"BAE95374.1","term_id":"107597820","term_text":"BAE95374.1"}}BAE95374.1) (14, 15); 5, LnpA1 (B. bifidum JCM1254, {"type":"entrez-protein","attrs":{"text":"BAD80752.1","term_id":"56676017","term_text":"BAD80752.1"}}BAD80752.1) (14, 15); 6, GLNBP_Bl (B. longum subsp. longum JCM 1217, {"type":"entrez-protein","attrs":{"text":"BAD80751.1","term_id":"56676015","term_text":"BAD80751.1"}}BAD80751.1) (1, 16); 7, Blon_2174 (B. longum subsp. infantis ATCC 15697, {"type":"entrez-protein","attrs":{"text":"ACJ53235.1","term_id":"213524488","term_text":"ACJ53235.1"}}ACJ53235.1); 8, BL1641 (B. longum NCC2705, {"type":"entrez-protein","attrs":{"text":"AAN25428.1","term_id":"23326930","term_text":"AAN25428.1"}}AAN25428.1); 9, BLD_1765 (B. longum DJO10A, {"type":"entrez-protein","attrs":{"text":"ACD99210.1","term_id":"189429062","term_text":"ACD99210.1"}}ACD99210.1); 10, GnpA (P. acnes JCM6473, {"type":"entrez-nucleotide","attrs":{"text":"AB468065","term_id":"219807264","term_text":"AB468065"}}AB468065) (17); 11, GnpA (P. acnes JCM6425, {"type":"entrez-nucleotide","attrs":{"text":"AB468066","term_id":"219807262","term_text":"AB468066"}}AB468066) (17); 12, PPA0083 (P. acnes KPA171202, {"type":"entrez-protein","attrs":{"text":"AAT81843.1","term_id":"50839176","term_text":"AAT81843.1"}}AAT81843.1); 13, VV2_1091 (V. vulnificus CMCP6, {"type":"entrez-protein","attrs":{"text":"AAO07997.1","term_id":"27359049","term_text":"AAO07997.1"}}AAO07997.1) (18); 14, VVA1614 (V. vulnificus YJ016, {"type":"entrez-protein","attrs":{"text":"BAC97640.1","term_id":"37201820","term_text":"BAC97640.1"}}BAC97640.1); 15, Oter_1377 (Opitutus terrae PB90-1, {"type":"entrez-protein","attrs":{"text":"ACB74662.1","term_id":"177840410","term_text":"ACB74662.1"}}ACB74662.1); 16, BCQ_1989 (B. cereus Q1, {"type":"entrez-protein","attrs":{"text":"ACM12417.1","term_id":"221239707","term_text":"ACM12417.1"}}ACM12417.1); 17, BCAH187_A2105 (Bacillus cereus AH187, {"type":"entrez-protein","attrs":{"text":"ACJ78918.1","term_id":"217064668","term_text":"ACJ78918.1"}}ACJ78918.1).In this study, we characterized the three proteins. We reported that two of them were GalHexNAcPs and that the other was a β-galactoside phosphorylase showing unique substrate specificity.     

Gait analysis using gravitational acceleration measured by wearable sensors

A novel method for measuring human gait posture using wearable sensor units is proposed. The sensor units consist of a tri-axial acceleration sensor and three gyro sensors aligned on three axes. The acceleration and angular velocity during walking were measured with seven sensor units worn on the abdomen and the lower limb segments (both thighs, shanks and feet). The three-dimensional positions of each joint are calculated from each segment length and joint angle. Joint angle can be estimated mechanically from the gravitational acceleration along the anterior axis of the segment. However, the acceleration data during walking includes three major components; translational acceleration, gravitational acceleration and external noise. Therefore, an optimization analysis was represented to separate only the gravitational acceleration from the acceleration data. Because the cyclic patterns of acceleration data can be found during constant walking, a FFT analysis was applied to obtain some characteristic frequencies in it. A pattern of gravitational acceleration was assumed using some parts of these characteristic frequencies. Every joint position was calculated from the pattern under the condition of physiological motion range of each joint. An optimized pattern of the gravitational acceleration was selected as a solution of an inverse problem. Gaits of three healthy volunteers were measured by walking for 20 s on a flat floor. As a result, the acceleration data of every segment was measured simultaneously. The characteristic three-dimensional walking could be shown by the expression using a stick figure model. In addition, the trajectories of the knee joint in the horizontal plane could be checked by visual imaging on a PC. Therefore, this method provides important quantitive information for gait diagnosis.     

Cryopreservation and low-temperature storage of seeds of Phaius tankervilleae

In this study we established reliable methods for conservation of seeds of Phaius tankervilleae as an orchid genetic resource. The seeds, which were dehydrated to 5% water content and preserved at 4°C, showed no decrease in viability and germinability after three months. After storage for six months, however, the seeds showed a drastic decrease in germinability, even though survival rate was high. For long-term preservation of seeds of P. tankervilleae, cryopreservation is applied to the freshly harvested seeds. When the seeds were cryopreserved by the vitrification method for up to 12 months there was no apparent deterioration effect of storage time. These results indicate that cryopreservation by the vitrification method is useful for long-term conservation of P. tankervilleae seeds, which are difficult to preserve for more than three months under dry and low-temperature conditions.     

Carboxylation reaction catalyzed by 2-oxoglutarate:ferredoxin oxidoreductases from Hydrogenobacter thermophilus

Hydrogenobacter thermophilus TK-6 is a thermophilic, chemolithoautotrophic, hydrogen-oxidizing bacterium that fixes carbon dioxide via the reductive tricarboxylic acid (rTCA) cycle. 2-Oxoglutarate:ferredoxin oxidoreductase (OGOR) is the key enzyme in this cycle that fixes carbon dioxide. The genome of strain TK-6 encodes at least two distinct OGOR enzymes, termed For and Kor. We report here a method for measuring the carboxylation of succinyl-CoA catalyzed by OGORs. The method involves the in vitro coupling of OGOR with ferredoxin and pyruvate:ferredoxin oxidoreductase from strain TK-6, and glutamate dehydrogenase from Sulfolobus tokodaii. Using this method, we determined both the apparent maximum velocities and the K _m values of For and Kor for the carboxylation of succinyl-CoA. This is the first reported kinetic analysis of carbon fixation catalyzed by OGOR enzymes from the rTCA cycle.     

Distance decay of community dynamics in rocky intertidal sessile assemblages evaluated by transition matrix models

It is well known that the similarity in species composition between two communities decays with the geographic distance that separates them. It is thus likely that the similarity in the dynamics of two communities also decays with distance, because the distance–decay relationship is fundamental in nature. However, the distance–decay relationships of community dynamics have not yet been revealed. We used transition matrix models to evaluate distance–decay relationships of seasonal community dynamics (from spring to summer) in rocky intertidal sessile assemblages along the Pacific coast of Japan between 31°N and 43°N. We evaluated the distance–decay relationships of whole-community dynamics and of three dynamics-related components—recruitment, disturbance, and species interaction (competition and facilitation)—for communities separated by distances ranging from several meters to thousands of kilometers. The similarity of the recruitment dynamics among communities declined rapidly with distance within the fine spatial scale, but only moderately within larger scales. The similarity of the disturbance dynamics was independent of distance, and the similarity of species interaction declined slightly with increasing distance. The similarity of whole-community dynamics declined rapidly with distance at a fine spatial scale and moderately at larger scales. The fact that the distance–decay relationship of whole-community dynamics was similar to that of recruitment may suggest that recruitment processes are the most important determinant of spatial variability of community dynamics at our study sites during the study period.     

The SMALL AND ROUND SEED1 (SRS1/DEP2) gene is involved in the regulation of seed size in rice

The causal gene of a novel small and round seed mutant 1 (srs1) was identified in rice by map-based cloning and named SMALL AND ROUND SEED 1 (SRS1). The SRS1 gene is identical to the previously identified DENSE AND ERECT PANICLE 2 (DEP2). The SRS1/DEP2 gene encodes a novel protein of 1365 amino acids residues without known functional domains. In the longitudinal direction of the lemma, both cell length and cell number are reduced in srs1-1 compared to the wild type, whereas in the lateral cross section of the lemma, cell length in srs1-1 is greater than that in the wild type, but the cell number in srs1-1 is the same as that in wild type. These results suggest that the small and round seed phenotype of srs1-1 is due to the reduction in both cell length and cell number in the longitudinal direction, and the elongation of the cells in the lateral direction of the lemma. The SRS1 mRNA and proteins are abundant in wild type rice specifically in young organs, namely young leaves, internodes and panicles. Interestingly, the tissues expressing SRS1 are closely related to the tissues that exhibit abnormalities in the srs1 mutants.     

Production of wheat-Psathyrostachys huashanica chromosome addition lines

Psathyrostachys huashanica Keng (2n = 14; N(h)N(h)) is an endangered wheat-related species, with a distribution in the Huashan region of central China. It has many agronomically promising characters including resistance to disease and drought and winter hardiness. We produced hybrids between common wheat as the female parent and P. huashanica as the male parent. From the offspring, we selected chromosome addition lines of common wheat carrying each of all seven chromosomes of P. huashanica. Four chromosomes (B, D, E and F) were recovered in disomic lines and three (A, C and G) in monosomic addition lines. These alien chromosomes were distinguished from each other by cytological analyses. Chromosome A was characterized by a 45S rDNA site in the subtelomeric region of the short arm. Chromosome B carried one 5S and one 45S rDNA sites co-localized in an interstitial region of the short arm, and the expression of the alien high-molecular-weight glutenin was observed in the endosperm of line B. Chromosome D had a 45S rDNA signal in the interstitial region of the long arm. Chromosomes C, E, and F were distinguished by the EST-SSR markers Ltc0464, Ltc0096, and Xcfe175, respectively. The homoeologous group of each alien chromosome was implied from the results above, and the utilization of these addition lines for wheat breeding was discussed.