Microbial Degradation of a Macrotetrolide Miticide in Soil

Macrotetrolide, a miticide consisting of tetranactin, trinactin, and dinactin, was readily biodegradable and hence did not accumulate in soil. [U-¹⁴C]macrotetrolide was rapidly degraded via its constituent hydroxycarboxylic acids to carbon dioxide and water. In culture media, however, the mixture was hydrolyzed to homononactic and nonactic acids by three strains of Bacillus sp. and two of Micrococcus sp. The latter strains were able to hydrolyze 500 μg of the antibiotic per ml within a few days and to grow in the presence of 4,000 μg of the antibiotic per ml. However, they were unable to assimilate the constituent acids which accumulated in the culture medium.     

Glucosylglycerol,a compatible solute,sustains cell division under salt stress

The cyanobacterium Synechocystis sp. PCC 6803 accumulates the compatible solute glucosylglycerol (GG) and sucrose under salt stress. Although the molecular mechanisms for GG synthesis including regulation of the GG-phosphate synthase (ggpS) gene, which encodes GgpS, has been intensively investigated, the role of GG in protection against salt stress remains poorly understood. In our study of the role of GG in the tolerance to salt stress, we found that salt stress due to 450 mM NaCl inhibited cell division and significantly increased cell size in DeltaggpS mutant cells, whereas the inhibition of cell division and increase in cell size were observed in wild-type cells at high concentrations of NaCl, such as 800 mM. Electron microscopy revealed that, in DeltaggpS cells, separation of daughter cells was incomplete, and aborted division could be recognized by the presence of a structure that resembled a division ring. The addition of GG to the culture medium protected DeltaggpS cells against salt stress and reversed the adverse effects of NaCl on cell division and cell size. These observations suggest that GG is important for salt tolerance and thus for the proper division of cells under salt stress conditions.     

Mechanical and chemical properties of cysteine-modified kinesin molecules.

To probe the structural changes within kinesin molecules, we made the mutants of motor domains of two-headed kinesin (4-411 aa) in which either all the five cysteines or all except Cys45 were mutated. A residual cysteine (Cys45) of the kinesin mutant was labeled with an environment-sensitive fluorescent probe, acrylodan. ATPase activity, mechanical properties, and fluorescence intensity of the mutants were measured. Upon acrylodan-labeled kinesin binding to microtubules in the presence of 1 mM AMPPNP, the peak intensity was enhanced by 3.4-fold, indicating the structural change of the kinesin head by the binding. Substitution of cysteines decreased both the maximum microtubule-activated ATPase and the sliding velocity to the same extent. However, the maximum force and the step size were not affected; the force produced by a single molecule was 6-6.5 pN, and a step size due to the hydrolysis of one ATP molecule by kinesin molecules was about 10 nm for all kinesins. This step size was close to a unitary step size of 8 nm. Thus, the mechanical events of kinesin are tightly coupled with the chemical events.     

Cold Stress Stimulates Intracellular Calcification by the Coccolithophore, Emiliania huxleyi (Haptophyceae) Under Phosphate-Deficient Conditions

Intracellular calcification by the coccolith-producing haptophyte Emiliania huxleyi (NIES 837) is regulated by various environmental factors. This study focused on the relationship between cold and phosphate-deficient stresses to elucidate how those factors control coccolith production. (45)Ca incorporation into coccoliths was more than 97% of the total (45)Ca incorporation by whole cells. In a batch culture, orthophosphate in the medium (final concentration, 28.7 muM) was rapidly depleted within 3 days, and then extracellular alkaline phosphatase (AP) activity, an indicator of phosphate deprivation, increased during the stationary growth phase. The increase in AP activity was slightly higher at 20 degrees C than at 12 degrees C. The calcification started to increase earlier than AP activity, and the increase was much higher at 12 degrees C than at 20 degrees C. Such enhancement of calcification was suppressed by the addition of phosphate, while AP activity was also suppressed after a transient increase. These results suggest that phosphate deprivation is a trigger for calcification and that a rather long induction period is needed for calcification compared to the increase in AP activity. While calcification was greatly stimulated by cold stress, other cellular activities such as growth, phosphate utilization, and the induction of AP activity were suppressed. The stimulation of coccolith production by cold stress was minimal under phosphate-sufficient conditions. The high calcification activity estimated by (45)Ca incorporation was confirmed by morphological observations of coccoliths on the cell surface under bright-field and polarization microscopy. These results indicate that phosphate deprivation is the primary factor for stimulating coccolith production, and cold stress is a secondary acceleration factor that stimulates calcification under conditions of phosphate deprivation.     

Cargo-binding makes a wild-type single-headed myosin-VI move processively

Class VI myosin is an intracellular vesicle and organelle transporter that moves along actin filaments in a direction opposite to most other known myosin classes. The myosin-VI was expected to form a dimer to move processively along actin filaments with a hand-over-hand mechanism like other myosin organelle transporters. Recently, however, wild-type myosin-VI was demonstrated to be monomer and single-headed, casting a doubt on its processivity. By using single molecule techniques, we show that green-fluorescent-protein-tagged single-headed, wild-type myosin-VI does not move processively. However, when coupled to 200-nm polystyrene beads (comparable to intracellular vesicles in size) at a ratio of one head per bead, single-headed myosin-VI moves processively with large (40-nm) steps. The characteristics of this monomer-driven movement were different to that of artificial dimer-driven movement: Compared to the artificial dimer, the monomer-bead complex had a reduced stall force (1 pN compared to 2 pN), an average run length 2.5-fold shorter (91 nm compared to 220 nm) and load-dependent step size. Furthermore, we found that a monomer-bead complex moved more processively in a high viscous solution (40-fold higher than water) similar to cellular environment. Because the diffusion constant of the bead is 60-fold lower than myosin-VI heads alone in water, we propose a model in which the bead acts as a diffusional anchor for the myosin-VI, enhancing its rebinding following detachment and supporting processive movement of the bead-monomer complexes. Although a single-headed myosin-VI was able to move processively with a large cargo, the travel distance was rather short. Multiple molecules may be involved in the cargo transport for a long travel distance in cells.     

Influence of a 3‐month training program on muscular damage and neutrophil function in male university freshman judoists

We studied the effects of a high intensity and high frequency 3‐month training program on muscle damage and neutrophil function in male judoists. The study included 15 male judoists who started intensive judo training program after a 6‐month break. Creatine kinase (CK), neutrophil counts and reactive oxygen species (ROS) production capability as well as phagocytic activity (PA) of neutrophils were measured at 2 stages; entering university (pre‐training) and after 3‐month training (post‐training). At both points, we investigated parameters three times: just before, immediately after and 24 h after a 2‐h practice session. Practice‐mediated change in CK was lower at post‐training than at pre‐training. Neutrophil count significantly increased after 2‐h practice but recovered 24 h later whereas it showed no subsequent and further increased at 24 h post‐practice. Although neutrophil ROS production capability and PA both decreased (breakdown) after practice session, ROS production capability increased and PA decreased (well‐adapted) at the post‐training. Long‐term training strengthened muscular function and improved neutrophil reaction against practice‐mediated stress. Copyright © 2012 John Wiley & Sons, Ltd.     

The relationship between exhaled carbon monoxide and human neutrophil function in the Japanese general population

We have evaluated the relationship between exhaled carbon monoxide (CO) level and neutrophil‐related functions such as reactive oxygen species (ROS) production capability, phagocytic activity and serum opsonic activity in the general population. Serum opsonic activity was determined by measuring the effects of serum on neutrophil ROS production capability using lucigenin‐ and luminol‐dependent chemiluminescence (LgCL, LmCL). LgCL is associated with the detection of O₂^?, whereas LmCL mainly detects H₂O₂ and HOCl, which are higher reactive oxygen radicals. In females, exhaled CO level was found to have positive associations with ROS production capability and LgCL. However, the opposite tendency was seen between exhaled CO level and LmCL in both genders. This result suggests that neutrophil ROS production in females may have contributed to oxidative stress, which led to the increases in intrinsic CO and exhaled CO consequently. Such changes then may have inhibited the process of changing reactive oxygen radicals into higher oxidizing potential levels. Copyright © 2010 John Wiley & Sons, Ltd.     

Uniform affinity-tuning of N-methyl-aminoacyl-tRNAs to EF-Tu enhances their multiple incorporation

In ribosomal translation, the accommodation of aminoacyl-tRNAs into the ribosome is mediated by elongation factor thermo unstable (EF-Tu). The structures of proteinogenic aminoacyl-tRNAs (pAA-tRNAs) are fine-tuned to have uniform binding affinities to EF-Tu in order that all proteinogenic amino acids can be incorporated into the nascent peptide chain with similar efficiencies. Although genetic code reprogramming has enabled the incorporation of non-proteinogenic amino acids (npAAs) into the nascent peptide chain, the incorporation of some npAAs, such as N-methyl-amino acids (^MeAAs), is less efficient, especially when ^MeAAs frequently and/or consecutively appear in a peptide sequence. Such poor incorporation efficiencies can be attributed to inadequate affinities of ^MeAA-tRNAs to EF-Tu. Taking advantage of flexizymes, here we have experimentally verified that the affinities of ^MeAA-tRNAs to EF-Tu are indeed weaker than those of pAA-tRNAs. Since the T-stem of tRNA plays a major role in interacting with EF-Tu, we have engineered the T-stem sequence to tune the affinity of ^MeAA-tRNAs to EF-Tu. The uniform affinity-tuning of the individual pairs has successfully enhanced the incorporation of ^MeAAs, achieving the incorporation of nine distinct ^MeAAs into both linear and thioether-macrocyclic peptide scaffolds.