A Novel Mucidosphaerium sp. Downregulates Inflammatory Gene Expression in Skin and Articular Cells.

CONTEXT: Hot-spring therapy is occasionally used for the treatment of inflammatory diseases. Microorganisms might contribute to the anti-inflammatory functions seen in thermal mud therapies. Natural microorganisms, derived from traditional spa resorts, could be useful as a preventive strategy for alternative medical applications. OBJECTIVE: The aim of the study was to find effective microalgae from prominent hot springs to use for the treatment of inflammatory diseases. DESIGN: The research team performed an in-vitro study. Microalgae, derived from Beppu hot springs, were isolated and homogeneously cultured. SETTING: The study took place at the Saravio Central Institute at Saravio Cosmetics in Oita, Japan and the Department of Bioscience and Biotechnology in the Graduate School of Agriculture at Shinshu University in Nagano, Japan. INTERVENTION: For identification, the 18S ribosomal RNA genes of microalgae were investigated by DNA sequencing and homology search, together with microscopic observation. OUTCOME MEASURES: To examine the pharmacological activities of the algal extracts, real-time polymerase chain reactions were performed, using either primary dermal fibroblasts (DFs), dermal papilla cells (DPCs), or fibroblast-like synoviocytes (FLSs). To test the antioxidant activity, both the oxygen radical absorbance capacity and the generation of intracellular reactive oxygen species (ROS) were evaluated. RESULTS: A novel strain of green algae, Mucidosphaerium sp., was isolated from a Beppu hot spring. The algal extract downregulated gene-expression levels of pro-inflammatory cytokines, such as interleukin-1ß (IL-1ß), IL-6, and tumor necrosis factor- alpha (TNF-α), in various primary cells pre-exposed to IL-1ß. The protein level of the risk factors was concomitantly reduced. In addition, the algal extract suppressed the IL-1ß-induced upregulation of cyclooxygenase-2, nerve growth factor, and matrix metalloproteinase-1 (MMP-1) and MMP-3 in DFs. It also inhibited that of MMP-1, -3, and -9 in FLSs. Moreover, the extract inhibited total MMP protease activities. The microalgae decreased the intracellular reactive oxygen species (ROS) level in FLSs with an antioxidant activity of 178.3 ± 0.9 µmol of trolox equivalent/g. CONCLUSIONS: The present study showed that the novel Mucidosphaerium sp., derived from a Beppu hot spring, suppressed inflammatory reactions in both cutaneous and articular cells, partly due to its antioxidative properties. The novel algal strain may be a useful tool as an alternative medicine for skin and joint inflammatory disorders.

Oral administration of spa-derived green alga improves insulin resistance in overweight subjects: Mechanistic insights from fructose-fed rats.

Advanced glycation end products (AGEs) and their receptor (RAGE) system evoke inflammatory reactions and insulin resistance in adipocytes. Spa-derived green alga Mucidosphaerium sp. (MS) had anti-inflammatory properties in vitro. We examined here whether and how MS could ameliorate insulin resistance in fructose-rich diet-fed rats, and conducted a randomized, double blind, placebo-controlled trial to investigate the effects of MS on insulin resistance in overweight subjects. Oral administration of MS for 8 weeks significantly decreased random blood glucose, and fasting insulin, oxidative stress levels, and improved homeostasis model assessment of insulin resistance (HOMA-IR) values in fructose-fed rats, which were associated with the reduction of AGEs, RAGE, 8-hydroxy-2'-deoxy-guanosine, NADPH oxidase activity, macrophage and lymphocyte infiltration, monocyte chemoattractant protein-1 (MCP-1) expression, and adipocyte size in the adipose tissues as well as restoration of adiponectin levels. MS decreased the AGE-induced NADPH oxidase activity, ROS generation, MCP-1 and RAGE gene expression, and lipid accumulation in differentiated adipocytes, while it restored the decrease in adiponectin mRNA levels. An anti-oxidant, N-acetylcysteine mimicked the effects of MS on ROS generation, RAGE gene expression, and lipid accumulation. Oral intake of MS for 12 weeks significantly decreased systolic and diastolic blood pressure, fasting plasma glucose, fasting insulin, HOMA-IR, HDL-cholesterol and creatinine in overweight subjects. Baseline-adjusted diastolic blood pressure, fasting plasma glucose, fasting insulin, and HOMA-IR values were significantly lower in MS treatment group than in placebo. Our present findings suggest that MS may improve insulin resistance by blocking the AGE-RAGE-oxidative stress axis in the adipose tissues.

Advanced Glycation End Products: A Molecular Target for Vascular Complications in Diabetes.

A nonenzymatic reaction between reducing sugars and amino groups of proteins, lipids and nucleic acids contributes to the aging of macromolecules and subsequently alters their structural integrity and function. This process has been known to progress at an accelerated rate under hyperglycemic and/or oxidative stress conditions. Over a course of days to weeks, early glycation products undergo further reactions such as rearrangements and dehydration to become irreversibly cross-linked, fluorescent and senescent macroprotein derivatives termed advanced glycation end products (AGEs). There is a growing body of evidence indicating that interaction of AGEs with their receptor (RAGE) elicits oxidative stress generation and as a result evokes proliferative, inflammatory, thrombotic and fibrotic reactions in a variety of cells. This evidence supports AGEs' involvement in diabetes- and aging-associated disorders such as diabetic vascular complications, cancer, Alzheimer's disease and osteoporosis. Therefore, inhibition of AGE formation could be a novel molecular target for organ protection in diabetes. This report summarizes the pathophysiological role of AGEs in vascular complications in diabetes and discusses the potential clinical utility of measurement of serum levels of AGEs for evaluating organ damage in diabetes.

DNA Aptamer Raised against Advanced Glycation End Products Prevents Abnormalities in Electroretinograms of Experimental Diabetic Retinopathy.

PURPOSE: Abnormalities in electroretinograms (ERG), such as reduced amplitudes and delayed implicit times of a- and b-wave and oscillatory potentials (OPs), are one of the earliest features of diabetic retinopathy prior to obvious vascular changes in diabetic retinas. We have previously shown that serum levels of advanced glycation end products (AGEs) are correlated with a delayed latency of OPs in type 2 diabetic rats. However, the pathological role of AGEs in ERG abnormalities remains unclear. We examined here whether high-affinity DNA aptamer directed against AGEs (AGE-aptamer) prevents ERG abnormalities in experimental type 1 diabetic retinopathy. METHODS: Streptozotocin-induced diabetic rats or control rats received continuous intraperitoneal infusion of either AGE-aptamer or control aptamer via an osmotic mini pump for 16 weeks. Anthropometric, metabolic, and hemodynamic variables were measured, and an ERG was performed. RESULTS: Although AGE-aptamer did not affect body weight, fasting and random blood glucose, HbA1c, blood pressure, or lipid parameters, it completely prevented the increase in serum AGE levels as well as the reduction of a- and b-wave and OP amplitudes in diabetic rats. CONCLUSION: The present study demonstrated for the first time that AGE-aptamer prevents abnormalities in ERG in experimental diabetic retinopathy probably by blocking the harmful effects of AGEs.

Alternate fast and slow stepping of a heterodimeric kinesin molecule.

A conventional kinesin molecule travels continuously along a microtubule in discrete 8-nm steps. This processive movement is generally explained by models in which the two identical heads of a kinesin move in a 'hand-over-hand' manner. Here, we show that a single heterodimeric kinesin molecule (in which one of the two heads is mutated in a nucleotide-binding site) exhibits fast and slow (with the dwell time at least 10 times longer than that of the fast step) 8-nm steps alternately, presumably corresponding to the displacement by the wild-type and mutant heads, respectively. Our results provide the first direct evidence for models in which the roles of the two heads alternate every 8-nm step.

Long-range cooperative binding of kinesin to a microtubule in the presence of ATP.

Interaction of kinesin-coated latex beads with a single microtubule (MT) was directly observed by fluorescence microscopy. In the presence of ATP, binding of a kinesin bead to the MT facilitated the subsequent binding of other kinesin beads to an adjacent region on the MT that extended for micrometers in length. This cooperative binding was not observed in the presence of ADP or 5'-adenylylimidodiphosphate (AMP-PNP), where binding along the MT was random. Cooperative binding also was induced by an engineered, heterodimeric kinesin, WT/E236A, that could hydrolyze ATP, yet remained fixed on the MT in the presence of ATP. Relative to the stationary WT/E236A kinesin on a MT, wild-type kinesin bound preferentially in close proximity, but was biased to the plus-end direction. These results suggest that kinesin binding and ATP hydrolysis may cause a long-range state transition in the MT, increasing its affinity for kinesin toward its plus end. Thus, our study highlights the active involvement of MTs in kinesin motility.

Single-headed mode of kinesin-5.

In most organisms, kinesin-5 motors are essential for mitosis and meiosis, where they crosslink and slide apart the antiparallel microtubule half-spindles. Recently, it was shown using single-molecule optical trapping that a truncated, double-headed human kinesin-5 dimer can step processively along microtubules. However, processivity is limited ( approximately 8 steps) with little coordination between the heads, raising the possibility that kinesin-5 motors might also be able to move by a nonprocessive mechanism. To investigate this, we engineered single-headed kinesin-5 dimers. We show that a set of these single-headed Eg5 dimers drive microtubule sliding at about 90% of wild-type velocity, indicating that Eg5 can slide microtubules by a mechanism in which one head of each Eg5 head-pair is effectively redundant. On the basis of this, we propose a muscle-like model for Eg5-driven microtubule sliding in spindles in which most force-generating events are single-headed interactions and alternate-heads processivity is rare.

Walking, hopping, diffusing and braking modes of kinesin-5.

It is clear that the main cellular mission of the molecular motor kinesin-5 (known as Eg5 in vertebrates) is to cross-link antiparallel microtubules and to slide them apart, thus playing a critical role during bipolar spindle formation. Nonetheless, important questions about the cell biological and biophysical mechanisms of Eg5 remain unanswered. With the 20th 'birthday' of Eg5 approaching, we discuss recent insights into the in vitro and in vivo functions of Eg5, in the context of our own recent work.

Aggregation of partially unfolded Myosin subfragment-1 into spherical oligomers with amyloid-like dye-binding properties.

Proteolytic myosin subfragment 1 (S1) is known to be partially unfolded in its 50-kDa subdomain by mild heat treatment at 35 degrees C [Burke et al. (1987) Biochemistry 26, 1492-1496]. Here, we report that this partial unfolding is accompanied by aggregation of S1 protein. Characteristics of the aggregate thus formed were: (i) formation of transparent sediment under centrifugation at 183,000 x g; (ii) amyloid-like, dye-binding properties such as Congo red-binding and Thioflavin T fluorescence enhancement; (iii) a uniformly sized spherical appearance in electron micrographs; and (iv) sensitivity to tryptic digestion. Gel filtration analysis of the aggregation process indicates that the spheroid was formed through an intermediate oligomeric stage. The aggregate inhibited spontaneous aggregation of an isolated 50 kDa fragment into a large amorphous mass. The remaining native regions in the partially unfolded S1 were probably responsible for this effect. These results show that, unlike the 50-kDa fragment, the partially unfolded S1 molecules do not form amorphous aggregates but assemble into spherical particles. The native regions in partially unfolded S1 may be a determinant of aggregate morphology.

Single-molecule imaging of the dynamic interactions between macromolecules.

In recent years, the development of single-molecule detection techniques has allowed the dynamic properties of biomolecules, which are normally obscured in conventional ensemble measurements, to be measured. One of these single-molecule detection techniques allows the measurement of dissociation and association events of individual molecules to be measured. This technique is based on the unique premise that the mobility between molecules that are bound and the mobility between those that are free in solution are different. The binding of ATP at the beginning and its dissociation at the end of the hydrolysis reaction were detected at the single-molecule level in real time. In this study, we extended this technique to image the dynamic interactions between large biomolecules (protein/protein and protein/polysaccharide). The binding and dissociation of fluorescently labeled macromolecules to partner molecules fixed on a glass surface were visualized by total internal reflection fluorescence microscopy. The dynamic interactions between the proteins in two energy conversion systems, that is, signaling proteins and enzyme molecules moving on dextran, have been measured. In these systems, the dynamic interactions were sensitive to the factors determining the chemical reactions. Thus, the dynamic interactions monitored in the single-molecule measurements provided useful information to further the understanding of the underlying mechanisms of energy conversion systems.

Cell observation method under near-living conditions by scanning electron microscopy.

Most cells of multicellular organisms have "primary cilia", which are single, non-motile, and sensory cilia. They have been reported to detect mechanical stimulation and transform it into internal cell, but the mechanisms are not still well known. Dermal papilla (DP) cells, which locate in the skin and regulate hair follicle development and hair cycle, were reported to have their primary cilia by immune-fluorescent method [1], but their detailed structure and function is unclear.For observation by scanning electron microscopy (SEM), biological specimens are conventionally fixed with glutaraldehyde and dehydrated in 30%, 50%, 70%, 90% and 100% ethanol. Then specimens are dried by butyl alcohol and coated with gold. It takes several days to prepare these specimens. Using many chemical reagent and many steps in this way may lead to destroy biological specimens structure. Here we attempted a recently proposed method using ionic liquid to prepare cell samples in near- living conditions observed the structure of DP cells (2D and clumps) with primary cilia.This time, we used ionic liquid for preparing specimens. First, cultured cells were fixed in glutaraldehyde, and immersed in ionic liquid. Next, the specimens were coated with gold and observed by SEM. Thus, it takes shorter time due to fewer step than conventional method and the process has no drying step. In a conventional way, we got the micrographs of 2D cultured DP cells and observed the cilium of DP cells (200-nm in diameter and 1.5um in length) on nucleus (15-um). In addition we could observe the clumps of DP cells and the cilia-like structure (∼12-um), but they do not attach to scaffoldings of the surface, probably due to drying. In observation using ionic liquid, we got the micrographs of 2D cultured DP cells and observed the cilium- like structure (200-nm in diameter and 2.1-um in length) on nucleus (30-um), as well. In this case, we could not find the cilia- like structure in the clumps of DP cells yet, but they well attached to the scaffoldings and kept the extending structure such as filopodia, too.We here observed DP cells and their cilia in near-living conditions. Unfortunately, we could not primary cilia in clumps of DP cells immersed in ionic liquid yet, but we could reduce damage receiving in the process of specimen's preparation, especially drying. In addition, we are challenging the observation using not only ionic liquid but also nano-suits by detergents [2] and the observation the cilia by SEM after identifying them by fluorescence microscopy, such as CLEM.

Dual pathway spindle assembly increases both the speed and the fidelity of mitosis.

Roughly half of all animal somatic cell spindles assemble by the classical prophase pathway, in which the centrosomes separate ahead of nuclear envelope breakdown (NEBD). The remainder assemble by the prometaphase pathway, in which the centrosomes separate following NEBD. Why cells use dual pathway spindle assembly is unclear. Here, by examining the timing of NEBD relative to the onset of Eg5-mEGFP loading to centrosomes, we show that a time window of 9.2 ± 2.9 min is available for Eg5-driven prophase centrosome separation ahead of NEBD, and that those cells that succeed in separating their centrosomes within this window subsequently show >3-fold fewer chromosome segregation errors and a somewhat faster mitosis. A longer time window would allow more cells to complete prophase centrosome separation and further reduce segregation errors, but at the expense of a slower mitosis. Our data reveal dual pathway mitosis in a new light, as a substantive strategy that increases both the speed and the fidelity of mitosis.

Coordination of kinesin's two heads studied with mutant heterodimers.

A conventional kinesin molecule has two identical catalytic domains (heads) and is thought to use them alternately to move processively, with 8-nm steps. To clarify how each head contributes to the observed steps, we have constructed heterodimeric kinesins that consist of two distinct heads. The heterodimers in which one of the heads is mutated in a microtubule-binding loop moved processively, even when the parent mutant homodimers bound too weakly to retain microtubules in microtubule-gliding assays. The velocities of the heterodimers were only slightly higher than those of the mutant homodimers, although mixtures of these weak-binding mutant homodimers and the WT dimers moved microtubules at a velocity similar to the WT. Thus, the mutant head affects the motility of the WT head only when they are in the same molecule. The maximum force a single heterodimer produced in optical trapping nanometry was intermediate between the WT and mutant homodimers, indicating that both heads contribute to the maximum force at the same time. These results demonstrate close collaboration of kinesin's two heads in producing force and motility.

Evidence for a novel, strongly bound acto-S1 complex carrying ADP and phosphate stabilized in the G680V mutant of Dictyostelium myosin II.

Gly 680 of Dictyostelium myosin II sits at a critical position within the reactive thiol helices. We have previously shown that G680V mutant subfragment 1 largely remains in strongly actin-bound states in the presence of ATP. We speculated that acto-G680V subfragment 1 complexes accumulate in the A.M.ADP.P(i) state on the basis of the biochemical phenotypes conferred by mutations which suppress the G680V mutation in vivo [Wu, Y., et al. (1999) Genetics 153, 107-116]. Here, we report further characterization of the interaction between actin and G680V subfragment 1. Light scattering data demonstrate that the majority of G680V subfragment 1 is bound to actin in the presence of ATP. These acto-G680V subfragment 1 complexes in the presence of ATP do not efficiently quench the fluorescence of pyrene-actin, unlike those in rigor complexes or in the presence of ADP alone. Kinetic analyses demonstrated that phosphate release, but not ATP hydrolysis or ADP release, is very slow and rate limiting in the acto-G680V subfragment 1 ATPase cycle. Single turnover kinetic analysis demonstrates that, during ATP hydrolysis by the acto-G680V subfragment 1 complex, quenching of pyrene fluorescence significantly lags the increase of light scattering. This is unlike the situation with wild-type subfragment 1, where the two signals have similar rate constants. These data support the hypothesis that the main intermediate during ATP hydrolysis by acto-G680V subfragment 1 is an acto-subfragment 1 complex carrying ADP and P(i), which scatters light but does not quench the pyrene fluorescence and so has a different conformation from the rigor complex.

Modulation of actomyosin motor function by 1-hexanol.

This study examines the effects of 1-hexanol as a perturbing agent on actomyosin ATPase and its related functions in the concentration range between 0 and 20 mM. In this range the denaturation of myosin subfragment 1 (S1), as measured by the inactivation rate of its K-EDTA-ATPase, and depolymerization of F-actin were insignificant. Major findings showed that hexanol had the following effects which were fully reversible, (a) a marked activation of S1 MgATPase (approximately 10-fold at 20 mM) without greatly affecting the enhancement of tryptophan fluorescence by formation of S1.ADP.Pi intermediate and the rate of ADP release from S1.ADP; (b) an inhibition of the maximum actin-activated ATPase activity; (c) an increase in the affinity of S1 for actin in the presence of ATP and a decrease in the presence of ADP or the absence of nucleotide; (d) a reduction in the sliding velocity of actin filaments in in vitro motility assays with myosin, and (e) a decrease in isometric tension of single skinned muscle fibers. Thus, the effects of hexanol on actomyosin interaction are distinct for the weak and strong binding states, consistent with a change in the hydrophobic interaction in the interface between myosin and actin accompanying the transition from the weak to the strong binding state. Hexanol also accelerates the Pi release from S1.ADP.Pi, which is the transition step from the weak to the strong binding state. The fact that hexanol accelerates Pi release suggests that this alcohol perturbs the S1.ADP.Pi conformation. We speculate that this intermediate-specific structural perturbation is related to the inhibition of the maximum actin-activated ATPase, in vitro motility, and isometric tension.