Complementation of Escherichia coli ubiF mutation by Caenorhabditis elegans CLK-1, a product of the longevity gene of the nematode worm

Caenorhabditis elegans CLK-1 was identified from long-lived mutant worms, and is believed to be involved in ubiquinone biosynthesis. The protein belongs to the eukaryotic CLK-1/Coq7p family, which is also similar to the bacterial Coq7 family, that hydroxylates demethoxyubiquinone, resulting in the formation of hydroxyubiquinone, a precursor of ubiquinone. In Escherichia coli, the corresponding reaction is catalyzed by UbiF, a member of a distinct class of hydroxylase. Although previous studies suggested that the eukaryotic CLK-1/Coq7 family is a hydroxylase of demethoxyubiquinone, there was no direct evidence to show the enzymatic activity of the eukaryotic CLK-1/Coq7 family. Here we show that the plasmid encoding C. elegans CLK-1 supported aerobic respiration on a non-fermentable carbon source of E. coli ubiF mutant strain and rescued the ability to synthesize ubiquinone, suggesting that the eukaryotic CLK-1/Coq7p family could function as bacterial UbiF.     

Isolation and metabolic characteristics of previously uncultured members of the order aquificales in a subsurface gold mine

Culture-dependent and -independent techniques were combined to characterize the physiological properties and the ecological impacts of culture-resistant phylotypes of thermophiles within the order Aquificales from a subsurface hot aquifer of a Japanese gold mine. Thermophilic bacteria phylogenetically associated with previously uncultured phylotypes of Aquificales were successfully isolated. 16S ribosomal DNA clone analysis of the entire microbial DNA assemblage and fluorescence in situ whole-cell hybridization analysis indicated that the isolates dominated the microbial population in the subsurface aquifer. The isolates were facultatively anaerobic, hydrogen- or sulfur/thiosulfate-oxidizing, thermophilic chemolithoautotrophs utilizing molecular oxygen, nitrate, ferric iron, arsenate, selenate, and selenite as electron acceptors. Their versatile energy-generating systems may reflect the geochemical conditions of their habitat in the geothermally active subsurface gold mine.     

Isolation and identification of novel ADP-ribosylated proteins from Streptomyces coelicolor A3(2)

An important role of protein ADP-ribosylation in bacterial morphogenesis has been proposed (J. Bacteriol. 178, 3785-3790; 178, 4935-4941). To clarify the detail of ADP-ribosylation, we identified a new kind of target protein for ADP-ribosylation in Streptomyces coelicolor A3(2) grown to the late growth phase. All four proteins (MalE, BldKB, a periplasmic protein for binding branched-chain amino-acids, and a periplasmic solute binding protein) were functionally similar and participated in the regulation of transport of metabolites or nutrients through the membrane. ADP-ribosylation was likely to occur on a cysteine residue, because the modification group was removed by mercuric chloride treatment. The modification site may be the site of lipoprotein modification necessary for protein export. This report is the first suggesting that certain proteins involved in membrane transport can be ADP-ribosylated.     

Polyphyletic origin of cultivated rice: based on the interspersion pattern of SINEs

The wild rice species Oryza rufipogon with wide intraspecific variation is thought to be the progenitor of the cultivated rice species Oryza sativa with two ecotypes, japonica and indica. To determine the origin of cultivated rice, subfamily members of the rice retroposon p-SINE1, which show insertion polymorphism in the O. sativa -O. rufipogon population, were identified and used to "bar code" each of 101 cultivated and wild rice strains based on the presence or absence of the p-SINE1 members at the respective loci. A phylogenetic tree constructed based on the bar codes given to the rice strains showed that O. sativa strains were classified into two groups corresponding to japonica and indica, whereas O. rufipogon strains were in four groups, in which annual O. rufipogon strains formed a single group, differing from the perennial O. rufipogon strains of the other three groups. Japonica strains were closely related to the O. rufipogon perennial strains of one group, and the indica strains were closely related to the O. rufipogon annual strains, indicating that O. sativa has been derived polyphyletically from O. rufipogon. The subfamily members of p-SINE1 constitute a powerful tool for studying the classification and relationship of rice strains, even when one has limited knowledge of morphology, taxonomy, physiology, and biochemistry of rice strains.     

Identification of a novel Na+-independent acidic amino acid transporter with structural similarity to the member of a heterodimeric amino acid transporter family associated with unknown heavy chains

We identified a novel Na(+)-independent acidic amino acid transporter designated AGT1 (aspartate/glutamate transporter 1). AGT1 exhibits the highest sequence similarity (48% identity) to the Na(+)-independent small neutral amino acid transporter Asc (asc-type amino acid transporter)-2 a member of the heterodimeric amino acid transporter family presumed to be associated with unknown heavy chains (Chairoungdua, A., Kanai, Y., Matsuo, H., Inatomi, J., Kim, D. K., and Endou, H. (2001) J. Biol. Chem. 276, 49390-49399). The cysteine residue responsible for the disulfide bond formation between transporters (light chains) and heavy chain subunits of the heterodimeric amino acid transporter family is conserved for AGT1. Because AGT1 solely expressed or coexpressed with already known heavy chain 4F2hc (4F2 heavy chain) or rBAT (related to b(0,+)-amino acid transporter) did not induce functional activity, we generated fusion proteins in which AGT1 was connected with 4F2hc or rBAT. The fusion proteins were sorted to the plasma membrane and expressed the Na(+)-independent transport activity for acidic amino acids. Distinct from the Na(+)-independent cystine/glutamate transporter xCT structurally related to AGT1, AGT1 did not accept cystine, homocysteate, and l-alpha-aminoadipate and exhibited high affinity to aspartate as well as glutamate, suggesting that the negative charge recognition site in the side chain-binding site of AGT1 would be closer to the alpha-carbon binding site compared with that of xCT. The AGT1 message was predominantly expressed in kidney. In mouse kidney, AGT1 protein was present in the basolateral membrane of the proximal straight tubules and distal convoluted tubules. In the Western blot analysis, AGT1 was detected as a high molecular mass band in the nonreducing condition, whereas the band shifted to a 40-kDa band corresponding to the AGT1 monomer in the reducing condition, suggesting the association of AGT1 with other protein via a disulfide bond. The finding of AGT1 and Asc-2 has established a new subgroup of the heterodimeric amino acid transporter family whose members associate not with 4F2hc or rBAT but with other unknown heavy chains.     

Chiroptical Studies on Supramolecular Chirality of Molecular Aggregates

The attempts of applying chiroptical spectroscopy to supramolecular chirality are reviewed with a focus on vibrational circular dichroism (VCD). Examples were taken from gels, solids, and monolayers formed by low‐molecular mass weight chiral gelators. Particular attention was paid to a group of gelators with perfluoroalkyl chains. The effects of the helical conformation of the perfluoroalkyl chains on the formation of chiral architectures are reported. It is described how the conformation of a chiral gelator was determined by comparing the experimental and theoretical VCD spectra together with a model proposed for the molecular aggregation in fibrils. The results demonstrate the potential utility of the chiroptical method in analyzing organized chiral aggregates. Chirality 27:659–666, 2015. © 2015 Wiley Periodicals, Inc.     

Two new SINE elements, p-SINE2 and p-SINE3, from rice

p-SINE1 was the first plant SINE element identified in the Waxy gene in Oryza sativa, and since then a large number of p-SINE1-family members have been identified from rice species with the AA or non-AA genome. In this paper, we report two new rice SINE elements, designated p-SINE2 and p-SINE3, which form distinct families from that of p-SINE1. Each of the two new elements is significantly homologous to p-SINE1 in their 5'-end regions with that of the polymerase III promoter (A box and B box), but not significantly homologous in the 3'-end regions, although they all have a T-rich tail at the 3' terminus. Despite the three elements sharing minimal homology in their 3'-end regions, the deduced RNA secondary structures of p-SINE1, p-SINE2 and p-SINE3 were found to be similar to one another, such that a stem-loop structure seen in the 3'-end region of each element is well conserved, suggesting that the structure has an important role on the p-SINE retroposition. These findings suggest that the three p-SINE elements originated from a common ancestor. Similar to members of the p-SINE1 family, the members of p-SINE2 or p-SINE3 are almost randomly dispersed in each of the 12 rice chromosomes, but appear to be preferentially inserted into gene-rich regions. The p-SINE2 members were present at respective loci not only in the strains of the species with the AA genome in the O. sativa complex, but also in those of other species with the BB, CC, DD, or EE genome in the O. officinalis complex. The p-SINE3 members were, however, only present in strains of species in the O. sativa complex. These findings suggest that p-SINE2 originated in an ancestral species with the AA, BB, CC, DD and EE genomes, like p-SINE1, whereas p-SINE3 originated in an ancestral strain of the species with the AA genome. The nucleotide sequences of p-SINE1 members are more divergent than those of p-SINE2 or p-SINE3, indicating that p-SINE1 is likely to be older than p-SINE2 and p-SINE3. This suggests that p-SINE2 and p-SINE3 have been derived from p-SINE1.