Genome analysis of Agrobacterium tumefaciens: linkage map and genetic features of the left region of the linear chromosome

In addition to a unique tumor-inducing (Ti) plasmid, the plant pathogenic bacterium Agrobacterium tumefaciens has an unconventional chromosomal organization. Our previous studies on A. tumefaciens MAFF301001 revealed that it possesses a 2 Mb linear and a 2.8 Mb circular chromosome plus a 206.479 kbp Ti plasmid (pTi-SAKURA). In this study, a linkage map for the left half of its linear chromosome covering a 900 kbp region was constructed and the number of potential genes existing in the region was estimated. The linkage map consists of 31 BAC and 8 lambda phage recombinants without any gaps. It confirmed the size and all the structural landmarks indicated in the corresponding region of our previously constructed physical map for the linear chromosome. Sequencing analysis of the end-regions of each linking clone led to the identification of 6 genes and another 27 potential genes or ORFs, including genes and/or gene clusters responsible for homologous recombination (ruvB), trehalose/maltose sugar transport (thuR, thuG) and alanine catabolism (dadR). Two virulence-related gene homologues (attK and celB), previously reported in the circular chromosome of a different strain of A. tumefaciens were found in this region. These findings will provide a ready-to-use linkage map for further functional analysis of the linear chromosome.     

Leucine-rich repeat receptor-like kinase1 is a key membrane-bound regulator of abscisic acid early signaling in Arabidopsis

Abscisic acid (ABA) is important in seed maturation, seed dormancy, stomatal closure, and stress response. Many genes that function in ABA signal transduction pathways have been identified. However, most important signaling molecules involved in the perception of the ABA signal or with ABA receptors have not been identified yet. Receptor-like kinase1 (RPK1), a Leu-rich repeat (LRR) receptor kinase in the plasma membrane, is upregulated by ABA in Arabidopsis thaliana. Here, we show the phenotypes of T-DNA insertion mutants and RPK1-antisense plants. Repression of RPK1 expression in Arabidopsis decreased sensitivity to ABA during germination, growth, and stomatal closure; microarray and RNA gel analysis showed that many ABA-inducible genes are downregulated in these plants. Furthermore, overexpression of the RPK1 LRR domain alone or fused with the Brassinosteroid-insensitive1 kinase domain in plants resulted in phenotypes indicating ABA sensitivity. RPK1 is involved in the main ABA signaling pathway and in early ABA perception in Arabidopsis.     

The His-Pro-Phe motif of angiotensinogen is a crucial determinant of the substrate specificity of renin

The amino acid sequence His-Pro-Phe as N-terminal residues 6-8 of the natural renin substrate, angiotensinogen, is conserved among species. We investigated whether this His-Pro-Phe motif functions as the determinant of the substrate specificity of renin. Mutant angiotensinogens in which the Ile-His-Pro-Phe-His-Leu sequence at positions 5-10 of wild-type angiotensinogen was replaced by either His-Pro-Phe-His-Leu-Leu or Ala-Ile-His-Pro-Phe-His were cleaved by renin at the C-terminal side of residues 9 and 11, respectively, while wild-type angiotensinogen was cleaved at residue 10. A triple Ala substitution for the His-Pro-Phe motif of angiotensinogen prevented its cleavage by renin. In contrast, triple Ala substitution for residues 9-11, including the natural site of cleavage by renin, allowed cleavage between the two Ala residues at positions 10 and 11. Furthermore, the 33-residue C-terminal peptide of human megsin, which carries a naturally occurring His-Pro-Phe sequence, was cleaved by renin at the C-terminal side of the His-Pro-Phe-Leu-Phe sequence. These results indicate that the His-Pro-Phe motif of angiotensinogen is a crucial determinant of the substrate specificity of renin. By binding to a corresponding pocket on renin, the His-Pro-Phe motif may act as a molecular anchor to recruit the scissile peptide bond to a favorable site for catalysis.     

M-Ras evolved independently of R-Ras and its neural function is conserved between mammalian and ascidian, which lacks classical Ras

The Ras family small GTPases play a variety of essential roles in eukaryotes. Among them, classical Ras (H-Ras, K-Ras, and N-Ras) and its orthologues are conserved from yeast to human. In ascidians, which phylogenetically exist between invertebrates and vertebrates, the fibroblast growth factor (FGF)-Ras-MAP kinase signaling is required for the induction of neural system, notochord, and mesenchyme. Analyses of DNA databases revealed that no gene encoding classical Ras is present in the ascidians, Ciona intestinalis and Halocynthia roretzi, despite the presence of classical Ras-orthologous genes in nematode, fly, amphioxus, and fish. By contrast, both the ascidians contain single genes orthologous to Mras, Rras, Ral, Rap1, and Rap2. A single Mras orthologue exists from nematode to mammalian. Thus, Mras evolved in metazoans independently of other Ras family genes such as Rras. Whole-mount in situ hybridization showed that C. intestinalis Mras orthologue (Ci-Mras) was expressed in the neural complex of the ascidian juveniles after metamorphosis. Knockdown of Ci-Mras with morpholino antisense oligonucleotides in the embryos and larvae resulted in undeveloped tails and neuronal pigment cells, abrogation of the notochord marker brachyury expression, and perturbation of the neural marker Otx expression, as has been shown in the experiments of the FGF-Ras-MAP kinase signaling inhibition. Mammalian Ras and M-Ras mediate nerve growth factor-induced neuronal differentiation in rat PC12 cells by activating the ERK/MAP kinase pathway transiently and sustainedly, respectively. Activated Ci-M-Ras bound to target proteins of mammalian M-Ras and Ras. Exogenous expression of an activated Ci-M-Ras in PC12 cells caused ERK activation and induced neuritogenesis via the ERK pathway as do mammalian M-Ras and Ras. These results suggest that the ascidian M-Ras orthologue compensates for lacked classical Ras and plays essential roles in neurogenesis in the ascidian.     

Simultaneous UPLC MS/MS analysis of endogenous jasmonic acid,salicylic acid,and their related compounds

Jasmonic acid (JA) and salicylic acid (SA) are plant hormones involved in plant growth and development. Recent studies demonstrated that presence of a complex interplay between JA and SA signaling pathways to response to pathogenesis attack and biotic stresses. To our best knowledge, no method has existed for simultaneous analyses of JA, SA, and their related compounds. Especially, the glucosides are thought to be the storages or the inactivated compounds, but their contribution should be considered for elucidating the amount of the aglycons. It is also valuable for measuring the endogenous amount of phenylalanine, cinnamic acid, and benzoic acid that are the biosynthetic intermediates of SA due to the existence of isochorismate pathway to synthesize SA. We established this method using deuterium labeled compounds as internal standards. This is the first report of simultaneous analysis of endogenous JA, SA, and their related compounds. Measuring the endogenous JA, SA, and their related compounds that had been accumulated in tobacco plants proved the practicality of the newly developed method. It was demonstrated that accumulation of JA, SA and their related compounds were induced in both case of TMV infection and abiotic stresses.     

Novel mutations of the LolCDE complex causing outer membrane localization of lipoproteins despite their inner membrane-retention signals

In Gram-negative bacteria, lipoproteins are targeted to either the inner or outer membrane depending on their sorting signals. An ABC transporter LolCDE complex in Escherichia coli releases outer membrane-specific lipoproteins. Inner membrane-specific lipoproteins remain in the inner membrane because they each have a LolCDE-avoidance signal and therefore are not released by LolCDE. Only the LolC(A40P) mutation was previously found to cause outer membrane localization of lipoproteins despite their inner membrane-retention signals. Here, we isolated several new LolCDE mutants that cause outer membrane localization of lipoproteins possessing LolCDE-avoidance signals. Mutations were found in all three subunits of LolCDE, including the cytoplasmic ATPase subunit LolD. However, the extent of outer membrane sorting of inner membrane-specific lipoproteins differed depending on the mutation. Based on these observations, the molecular events underlying the recognition of lipoproteins by the LolCDE complex are discussed.