Differences in muscle function during walking and running at the same speed

Individual muscle contributions to body segment mechanical energetics and the functional tasks of body support and forward propulsion in walking and running at the same speed were quantified using forward dynamical simulations to elucidate differences in muscle function between the two different gait modes. Simulations that emulated experimentally measured kinesiological data of young adults walking and running at the preferred walk-to-run transition speed revealed that muscles use similar biomechanical mechanisms to provide support and forward propulsion during the two tasks. The primary exception was a decreased contribution of the soleus to forward propulsion in running, which was previously found to be significant in walking. In addition, the soleus distributed its mechanical power differently to individual body segments between the two gait modes from mid- to late stance. In walking, the soleus transferred mechanical energy from the leg to the trunk to provide support, but in running it delivered energy to both the leg and trunk. In running, earlier soleus excitation resulted in it working in synergy with the hip and knee extensors near mid-stance to provide the vertical acceleration for the subsequent flight phase in running. In addition, greater power output was produced by the soleus and hip and knee extensors in running. All other muscle groups distributed mechanical power among the body segments and provided support and forward propulsion in a qualitatively similar manner in both walking and running.     

The Listeria monocytogenes DnaK chaperone is required for stress tolerance and efficient phagocytosis with macrophages

Listeria monocytogenes is a facultative intracellular pathogen which can escape bactericidal mechanisms and grow within macrophages. The intracellular environment of macrophages is one of the most stressful environments encountered by an invading bacterium during the course of infection. To study the role of the major stress protein, DnaK, of L. monocytogenes in survival under intracellular stress induced by macrophage-phagocytosis as well as under extracellular environmental stresses, we cloned, sequenced, and analyzed the dnaK locus from L. monocytogenes. Then we constructed an insertional mutation in the dnaK gene by homologous recombination and characterized it. Sequencing has revealed that the dnaK locus consists of four open reading frames in the order hrcA-grpE-dnaK-dnaJ. The mutant grows neither at temperatures above 39 degrees C nor under acidic conditions e.g. pH 3.0. Using the macrophage cell line JA-4, the ability of the dnaK mutant to grow intracellularly was examined. Immediately after phagocytosis, the number of viable dnaK mutant bacteria found within macrophages was significantly lower compared to that of intracellular wild type bacteria. However, following a 1-3 h latency period, the mutant multiplied in a similar fashion to the wild type within macrophage cells. A quantitative analysis of intracellular bacteria in macrophage cells by microscope and a binding assay of bacteria to the surface of macrophages by ELISA revealed that the lower number of viable dnaK mutant in macrophages after phagocytosis is due to the low efficiency of phagocytosis resulting from the reduced binding capacity of the dnaK mutant. These results demonstrate that DnaK of L. monocytogenes is essentially required for survival under high temperatures and acidic conditions. Though it does not largely contribute to the survival of L. monocytogenes in macrophage cells, it is essential for efficient phagocytosis. This is the first evidence that DnaK is required for the efficient phagocytosis of a facultative intracellular pathogen with macrophages.     

Laccase-type phenoloxidase in salivary glands and watery saliva of the green rice leafhopper, Nephotettix cincticeps

The activity and composition of leafhopper saliva are important in interactions with the host rice plant, and it may play a physiological role in detoxifying toxic plant substances or ingesting sap. We have characterized diphenoloxidase in the salivary glands of Nephotettix cincticeps, its activity as a laccase, and its presence in the watery saliva with the objective of understanding its function in feeding on rice plants. Nonreducing SDS-PAGE of salivary gland homogenates with staining by the typical laccase substrate 2,2'-azino-bis (3-ethylbenzthiazoline-6-sulfonic acid) (ABTS), hydroquinone or syringaldazine revealed a band at a molecular mass of approximately 85 kDa at pH 5. A band also appeared at a molecular mass of approximately 200 kDa when the gels were treated with dopamine, L-3,4-dihydroxyphenylalanine (DOPA) or catechol at pH 7. The ABTS-oxidizing activity of the homogenates was drastically inhibited by N-hydroxyglycine, a specific inhibitor of laccase. However, the dopamine-oxidizing activity was not inhibited by N-hydroxyglycine, while it was inhibited by phenylthiourea (PTU). Thus, the salivary glands of N. cincticeps contain two types of phenoloxidases: a laccase (85 kDa) and a phenoloxidase (200 kDa). Laccase activity was detected in a holidic sucrose diet that was fed on for 16 h by two females, but only a trace of catechol oxidase activity was observed, suggesting that the laccase-type phenoloxidase was the predominant phenoloxidase secreted in watery saliva. The laccase exhibited an optimum pH of 4.75-5 in McIlvaine buffer and had a PI of 4.8. Enzyme activity was histochemically localized in V cells of the posterior lobe of the salivary glands. It remained at the same level throughout the adult stage from 2 days after eclosion. A possible function of N. cincticeps salivary laccase may be rapid oxidization of potentially toxic monolignols to nontoxic polymers during feeding on the rice plant. This is the first report proving that laccase occurs in the salivary glands of Hemiptera species and is secreted in the watery saliva.     

Synthesis and biological activities of a pH-dependently activated water-soluble prodrug of a novel hexacyclic camptothecin analog

CH0793076 (1) is a novel hexacyclic camptothecin analog showing potent antitumor activity in various human caner xenograft models. To improve the water solubility of 1, water-soluble prodrugs were designed to generate an active drug 1 nonenzymatically, thus expected to show less interpatient PK variability than CPT-11. Among the prodrugs synthesized, 4c (TP300, hydrochloride) having a glycylsarcosyl ester at the C-20 position of 1 is highly water-soluble (>10 mg/ml), stable below pH 4 and rapidly generates 1 at physiological pH in vitro. The rapid (ca. <1 min) generation of 1 after incubation of TP300 with plasma (mouse, rat, dog and monkey) was also demonstrated. TP300 showed a broader antitumor spectrum and more potent antitumor activity than CPT-11 in various human cancer xenograft models.     

Overexpression of salicylate hydroxylase and the crucial role of lys(163) as its NADH binding site

Expression systems for the sal gene encoding salicylate hydroxylase from Pseudomonas putida S-1 were examined and some constructs were expressed in these systems. By cultivation of Escherichia coli BL21 (DE3)/pSAH8 in LB medium at 37 degrees C with isopropyl-b-D-thiogalactopyranoside as the inducer, salicylate hydroxylase was overexpressed mainly in the form of inclusion bodies. Lower temperature cultivation at 20 degrees C after induction resulted in a large amount of the enzyme in the soluble form. The E. coli clone harboring the recombinant plasmid produced a 45 kDa protein that appeared to be electrophoretically and immunochemically identical to the P. putida enzyme and contained the same N-terminal amino acid sequence. This recombinant DNA product also exhibited properties characteristic of a flavoprotein and was fully functional as salicylate hydroxylase. Based on chemical modification of the salicylate hydroxylase from P. putida, Lys163 was previously proposed to be the NADH binding site. In this study, to obtain a better understanding of the predicted role of Lys163, this residue in the active center of salicylate hydroxylase was replaced with Arg, Gly, or Glu by conventional site-directed mutagenesis. Kinetic studies using these mutant enzymes and the recombinant enzyme revealed increases in apparent K(m) values for NADH in the order of wild-type enzyme > K163R > K163G > K163E, with some decreases in V(max). Examination of the recombinant enzyme and K163G indicated that the pH dependency of K(m) on NADH with pK(a) 10.5 is lost by mutation despite the lack of changes in V(max) values, suggesting a requirement for the lysine residue as the NADH binding site. Based on these results, Lys163 is proposed to play a role in the binding of NADH at the active site through an ionic bond rather than playing a role in catalysis.     

Protocol for the production of viable bimaternal mouse embryos

A reliable nuclear transfer method was first reported in 1983; it provided definite evidence that parthenogenetic embryos are lethal at early postimplantation in mammals. Subsequently, nuclear transfer has been extensively used as an important and versatile tool for investigating embryo and somatic-cell cloning and nucleo-cytoplasmic interactions. Further development of this technique has enabled the generation of bimaternal embryos containing two haploid sets of maternal genomes from female germ cells of different origins. By using a 2-d nuclear transfer system for oocyte reconstruction, viable mice can be produced solely from maternal genomes, without the participation of the paternal genome. This oocyte reconstruction system, as described in this protocol, could provide valuable guidelines for exploring the potential endowments of gametes and for conferring novel properties to them.     

Environmental DNA enables detection of terrestrial mammals from forest pond water

Terrestrial animals must have frequent contact with water to survive, implying that environmental DNA (eDNA) originating from those animals should be detectable from places containing water in terrestrial ecosystems. Aiming to detect the presence of terrestrial mammals using forest water samples, we applied a set of universal PCR primers (MiMammal, a modified version of fish universal primers) for metabarcoding mammalian eDNA. The versatility of MiMammal primers was tested in silico and by amplifying DNAs extracted from tissues. The results suggested that MiMammal primers are capable of amplifying and distinguishing a diverse group of mammalian species. In addition, analyses of water samples from zoo cages of mammals with known species composition suggested that MiMammal primers could successfully detect mammalian species from water samples in the field. Then, we performed an experiment to detect mammals from natural ecosystems by collecting five 500‐ml water samples from ponds in two cool‐temperate forests in Hokkaido, northern Japan. MiMammal amplicon libraries were constructed using eDNA extracted from water samples, and sequences generated by Illumina MiSeq were subjected to data processing and taxonomic assignment. We thereby detected multiple species of mammals common to the sampling areas, including deer (Cervus nippon), mouse (Mus musculus), vole (Myodes rufocanus), raccoon (Procyon lotor), rat (Rattus norvegicus) and shrew (Sorex unguiculatus). Many previous applications of the eDNA metabarcoding approach have been limited to aquatic/semiaquatic systems, but the results presented here show that the approach is also promising even for forest mammal biodiversity surveys.