Takeshi Matsui

Rho-associated kinase, a novel serine/threonine kinase, as a putative target for small GTP binding protein Rho.

The small GTP binding protein Rho is implicated in cytoskeletal responses to extracellular signals such as lysophosphatidic acid to form stress fibers and focal contacts. Here we have purified a Rho‐interacting protein with a molecular mass of approximately 164 kDa (p164) from bovine brain. This protein bound to GTPgammaS (a non‐hydrolyzable GTP analog).RhoA but not to GDP.RhoA or GTPgammaS.RhoA with a mutation in the effector domain (RhoAA37).p164 had a kinase activity which was specifically stimulated by GTPgammaS.RhoA. We obtained the cDNA encoding p164 on the basis of its partial amino acid sequences and named it Rho‐associated kinase (Rho‐kinase). Rho‐kinase has a catalytic domain in the N‐terminal portion, a coiled coil domain in the middle portion and a zinc finger‐like motif in the C‐terminal portion. The catalytic domain shares 72% sequence homology with that of myotonic dystrophy kinase and the coiled coil domain contains a Rho‐interacting interface. When COS7 cells were cotransfected with Rho‐kinase and activated RhoA, some Rho‐kinase was recruited to membranes. Thus it is likely that Rho‐kinase is a putative target serine/threonine kinase for Rho and serves as a mediator of the Rho‐dependent signaling pathway.

Identification of a Putative Target for Rho as the Serine-Threonine Kinase Protein Kinase N

Rho, a Ras-like small guanosine triphosphatase, has been implicated in cytoskeletal responses to extracellular signals such as lysophosphatidic acid (LPA) to form stress fibers and focal contacts. The form of RhoA bound to guanosine triphosphate directly bound to and activated a serine-threonine kinase, protein kinase N (PKN). Activated RhoA formed a complex with PKN and activated it in COS-7 cells. PKN was phosphorylated in Swiss 3T3 cells stimulated with LPA, and this phosphorylation was blocked by treatment of cells with botulinum C3 exoenzyme. Activation of Rho may be linked directly to a serine-threonine kinase pathway.

Molecular biology and application of plant peroxidase genes

Abstract. Peroxidases are a family of isozymes found in all plants; they are heme-containing monomeric glycoproteins that utilize either H2O2 or O2 to oxidize a wide variety of molecules. These important enzymes are used in enzyme immunoassays, diagnostic assays and industrial enzymatic reactions. Peroxidase genes and their promoters can be used for molecular breeding of useful plants. Transgenic techniques have also been used to investigate the physiological and molecular functions of peroxidase genes in plants. Here, we review transgenic studies of peroxidase genes, including the functional analyses of the enzymes and their promoters. Regarding application of peroxidase genes, it has been reported that overexpression of the tomato TPX2 gene or the sweet potato swpa1 gene conferred increased salt-tolerance or oxidative-stress tolerance, respectively. The growth stimulation effect in transgenic tobacco and hybrid aspen upon overexpression of horseradish peroxidase gene is also discussed.

Vesicular transport route of horseradish C1a peroxidase is regulated by N- and C-terminal propeptides in tobacco cells

Abstract. Peroxidases (PRX, ECxa01.11.1.7) are widely distributed across microorganisms, plants, and animals; and, in plants, they have been implicated in a variety of secondary metabolic reactions. In particular, horseradish (Armoracia rusticana) root represents the main source of commercial PRX production. The prxC1a gene, which encodes horseradish PRX (HRP) C, is expressed mainly in the roots and stems of the horseradish plant. HRP C1a protein is shown to be synthesized as a preprotein with both a N-terminal (NTPP) and a C-terminal propeptide (CTPP). These propeptides, which might be responsible for intracellular localization or secretion, are removed before or concomitant with production of the mature protein. We investigated the functional role of HRP C1a NTPP and CTPP in the determination of the vesicular transport route, using an analytical system of transgenically cultured tobacco cells (Nicotiana tabacum, BY2). Here, we report that NTPP and CTPP are necessary and sufficient for accurate localization of mature HRP C1a protein to vacuoles of the vesicular transport system. We also demonstrate that HRP C1a derived from a preprotein lacking CTPP is shunted into the secretory pathway.

Production of double repeated B subunit of Shiga toxin 2e at high levels in transgenic lettuce plants as vaccine material for porcine edema disease

Pig edema disease is a bacterial disease caused by enterohemorrhagic Escherichia coli. E.xa0coli produces Shiga toxinxa02e (Stx2e), which is composed of one A subunit (Stx2eA) and five B subunits (Stx2eB). We previously reported production of Stx2eB in lettuce plants as a potential edible vaccine (Matsui etxa0al. in Biosci Biotechnol Biochem 73:1628–1634, 2009). However, the accumulation level was very low, and it was necessary to improve expression of Stx2eB for potential use of this plant-based vaccine. Therefore, in this study, we optimized the Stx2eB expression cassette and found that a double repeated Stx2eB (2× Stx2eB) accumulates to higher levels than a single Stx2eB in cultured tobacco cells. Furthermore, a linker peptide between the two Stx2eB moieties played an important role in maximizing the effects of the double repeat. Finally, we generated transgenic lettuce plants expressing 2× Stx2eB with a suitable linker peptide that accumulate as much as 80xa0mg per 100xa0g fresh weight, a level that will allow us to use these transgenic lettuce plants practically to generate vaccine material.

N-glycosylation at noncanonical Asn-X-Cys sequences in plant cells

The vesicular transport pathway in plant cells is often used for higher accumulation of recombinant proteins. In the endoplasmic reticulum, which acts as a gateway to the vesicular transport pathway, N-glycosylation occurs on specific Asn residues. This N-glycosylation in recombinant proteins must be carefully regulated as it can impact their enzymatic activity, half lives in serum when injected, structural stability, etc. In eukaryotic cells, including plant cells, N-glycans were found to be attached to Asn residues in Asn-X-Ser/Thr (X ≠ Pro) sequences. However, recently, N-glycosylations at noncanonical Asn-X-Cys sequences have been found in mammals and yeast. Our laboratory has discovered that N-glycans are attached to Asn residues at Asn-Thr-Cys sequences of double-repeated B subunit of Shiga toxin 2e produced in plant cells, the first reported case of N-glycosylation at a noncanonical Asn-X-Cys sequence in plant cells.

Effect of the sequence context of the AUG initiation codon on the rate of translation in dicotyledonous and monocotyledonous plant cells.

The sequence context around the AUG initiation codon strongly contributes to the translation initiation step in mammalian and plant cells. Here, we investigated the effect of the three nucleotides immediately upstream of the initiating AUG (positions -3 to -1) on the translation efficiency of a reporter gene, beta-glucuronidase, in dicotyledonous and monocotyledonous plant cells.

Transgenic Lettuce Producing a Candidate Protein for Vaccine against Edema Disease

Pig edema disease is a bacterial disease caused by Shiga toxin 2e-producing Escherichia coli belonging mainly to serotypes O138, O139, and O141. The B subunit of Shiga toxin 2e (Stx2eB) is a candidate protein for use in a vaccine against edema disease. We produced this protein in transgenic lettuce (Lactuca sativa), an edible plant that can be cultivated in a factory setting. In a transient expression system, we found that NtADH 5′-untranslated region (5′-UTR) functions as a translational enhancer in lettuce cells, and that Stx2eB accumulates most efficiently in the endoplasmic reticulum (ER) of lettuce cells. Stx2eB was produced in stable transgenic lettuce plants expressing a modified Stx2eB gene fused with the NtADH 5′-UTR and sequence encoding ER localization signals.

Molecular Cloning and Partial Characterization of a Peroxidase Gene Expressed in the Roots of Portulaca oleracea cv., One Potentially Useful in the Remediation of Phenolic Pollutants

Portulaca (Portulaca oleracea cv.) efficiently removes phenolic pollutants from hydroponic solution. In plant roots, peroxidase (PRX) is thought to be involved in the removal of phenolic pollutants by the cross-linking them to cell wall polysaccharides or proteins at the expense of reduction of hydrogen peroxide (H2O2). In this study, we found that portulaca roots secreted an acidic PRX isozyme that had relatively high H2O2 affinity. We isolated five PRX genes, and the recombinant PRX proteins produced in cultured tobacco cells were partially characterized. Among these genes, PoPRX2 probably encoded the acidic PRX isozyme. PoPRX2 had an extra N-terminal region which has not been reported for other PRX proteins. We found that PoPRX2 oxidized phenolic pollutants, including bisphenol A, octylphenol, nonylphenol, and 17β-estradiol. In addition, we found that the Cys261 residue of PoPRX2 played an important role in the determination of affinity for H2O2 and stability toward H2O2.

Floricultural Salvia plants have a high ability to eliminate bisphenol A.

The removal of bisphenol A, an endocrine disruptor, by 25 different kinds of Salvia cultivars was examined with hydroculture experiments. All the Salvia cultivars showed a high BPA-eliminating ability, and 100% to 74% of BPA (50 muM) was eliminated after 3 days.