PO-275 Effect of acute photobiomodulation treatment on the recovery of exhaustive exercise-induced motor dysfunction: There is no full text article associated whit this abstract

Objective Photobiomodulation (PBM), originally known as “low-level laser therapy”, has been recognized as an effective methond to relieve pain, reduce inflammtion and improve healing. PBM induces photobiological effect at the the cellular level without thermal and toxic effects. Currently, PBM study on muscle recovery after exercise mainly focouses on the changes of molecular and immunological parameters. This study was designed to analyze the effect of acute PBM treatment on exhaustive exercise-induced behaviorial changes. Methods 1. Sprague-Dawley rats were randomly divided into three groups (n=8, each group): Control group without exhaustive exercise (Cont), Exhaustive exercise group (EE) and acute PBM treatment group (APBM). Acute PBM were conducted immediately using a diode laser with continuous wave (CW) at 808 nm (350 mW/cm2) after exhaustive exercise. Each paws were treated using PBM for 2 minutes. Grisp test were performed 24 hours after exhaustive exercise. The grisp strength score and the hanging time on the rope were recorded and analyzed using Sigmastat. Results 1. Signficant decreases of the grisp strength score and the hanging time were observed in the EE group compared with control group. 2. The motor function in the acute PBM treatment group were significantly improved. Conclusions Acute photobiomodulation treatment with 808 nm laser can signicicantly enchance the recovery of exhaustive exercise-induced motor dysfunction . &nbsp

PO-284 Aerobic Exercise Preconditioning Prevents Behavioral Deficits in an Ovariectomized Rat Model of Post-traumatic Stress Disorder

Objective Post-traumatic Stress Disorder (PTSD) occurs in people who suffers reparative shocking, scary, or dangerous event. Evidences demonstrate that PTSD is associated with cognitive decline and depression. In the general population, women tend to show higher incidence of PTSD compared with men. Using the the ovariectomized rat model, the present work was designed to investigate the potential beneficial effect of aerobic exercise on the prevention of PTSD. Methods Adult Sprague-Dawley male rats were randomly divided into the following four groups (n = 8-10 in each group): 1) naïve control group; 2) ovariectomized group (OVX), 3) OVX with PTSD group (OVX + PTSD), 4) OVX + exercise group (OVX + Exe), and 5) OVX + PTSD + exercise (OVX + PTSD + Exe). For exercise pretreatment groups, the rats were subjected to 30 min of treadmill exercise (30 min/day, 5 days / week) for continuous 4 weeks. Open field test and elevated plus maze were used to measure behavioral changes from day 59 to day 66. Hippocampal levels of 17β-estradiol (E2) and brain-derived neurotrophic factor (BDNF) level were measured. Results 1. Results of open field and elevated plus maze test revealed that OVX animals exposed to PTSD showed obvious anxiety-like behavior compared to OVX animals without exercise. Intriguingly, anxiety-like behavior in OVX + PTSD group was significantly improved by aerobic exercise pretreatment in ovariectomized animals after PTSD. 2. Hippocampal levels of E2 and BDNF levels in the OVX + Exe group were significantly increased after aerobic exercise compared to these from OVX without exercise group. Conclusions These findings demonstrated that aerobic exercise preconditioning can efficiently prevent anxiety-like behavior in the ovariectomized rats subjected to PTSD, a mechanism could be associate with the increased levels of E2 and BDNF induced by exercise treatment

PO-274 Photobiomodulation Preconditioning Prevents Hypoxia-ischemia Induced Dyscinesia in a Neonatal Rat Model

Objective Neonatal hypoxia-ischemia (HI) injury caused by oxygen deprivation is the most common cause of severe neurologic deficits and dyscinesia in neonates. The work was designed to evaluate the preventative effect of photobiomodulation (PBM) preconditioning on HI-induced Dyscinesia in a Neonatal Rat Model, and its underlying mechanism of PBM action on brain damage in a HI model in neonatal rats. Methods 10-day-old neonatal Sprague-Dawley rats were randomly divided into 3 groups: (a) control group (animals without ligation); (b) HI group (HI animal with PBM pretreatment); (c) PBM group (HI animal with PBM pretreatment). The hanging wire test and cylinder test were conducted to evaluate the the strength and asymmetry of left (contralateral) paw usage, respectively. The volume shrinkage of the brain was analyzed on postnatal day 29. The neuronal loss, mitochondrial dynamics, mitochondrial fragmentation, cytochrome c release, neuronal apoptosis, dendritic and synaptic injury in hippocampus were tested using the brain collected on postnatal day 16. Results PBM preconditioning significantly attenuated motor function impairment, volume shrinkage, neuron loss, dendritic and synaptic injury after HI. Further mechanistic investigation showed that PBM preconditioning effectively restore HI-induced mitochondrial dynamic changes and inhibit mitochondrial fragmentation, accompanied by a robust suppression of cytochrome c release, and prevention of neuronal apoptosis by inhibition of caspase activation. Conclusions PBM preconditioning can prevent HI induced dyscinesia and brain injury by maintaining mitochondrial dynamics and inhibiting mitochondrial apoptotic pathway. &nbsp

PO-281 Vibration Training Restores Food Intake and Body Weight in a Rat Model of Depression

Objective Stress is well known to negatively affect body weight and food intake in animal models, but the underlying mechanisms have not yet been well elucidated and effective treatment is lacking. This project was initiated to study the potential beneficial effect of vibration training, a novel neuromuscular training method, in the treatment of depression. Methods Adult Sprague-Dawley male rats were randomly divided into the following three groups: 1) naïve control group, 2) depressive disorder group, and 3) depression with vibration training treatment group. To develop a depression phenotype, rats were individually and gently restricted in a modified, well-ventilated tube for 4 h every day for 21 days. Animals in vibration training treatment group were subjected to 30 min of vibration training (30 Hz, 5 days / week) for continuous 5 weeks. Body weight, physical and mental condition, and food intake were recorded daily and the data were statistically analyzed and compared between groups. Results 1. Daily body weight and food intake measurements revealed that both parameters decreased rapidly after the initiating daily restraint stress, compared with control group.  Intriguingly, both body weight and food intake of the depressive disorder group with 5-week vibration training were significantly improved. 2. The secretion of serotonin and dopamine in animals with chronic restraint stress were decreased compared with normal animals, and this attenuation was significantly prevented by vibration training. Conclusions The present study demonstrates that vibration training is capable of restoring food intake and body weight in a rat model of chronic restraint stress-induced depression

Genetic improvement of resistance to blast and bacterial blight of the elite maintainer line Rongfeng B in hybrid rice (Oryza sativa L.) by using marker-assisted selection

Rice blast caused by the fungus Magnaporthe grisea and bacterial blight (BB) caused by Xanthomonas oryzae pv. Oryzae (Xoo) are two major rice diseases in the world. An elite, early maturing maintainer line of hybrid rice, Rongfeng B hybrid rice is susceptible to both blast and BB. For improving its diseases resistance, BL122 and CBB23 were used as the donors of blast resistance genes Pi1 and Pi2 and BB resistance gene Xa23, respectively. These resistant genes were introgressed into Rongfeng B by using a marker-assisted backcross breeding programs, and two improved lines D521 and D524 with Pi1, Pi2 and Xa23 were developed. The results indicated that both improved lines showed high resistance to leaf and neck blast and BB. The resistance frequencies for the rice blast and the length of lesions resulting from BB ranged from 96.7 to 100% and 0.77 to 1.18 cm, respectively. The two improved lines showed the desired variation in the majority of evaluated agronomic traits, including the number of grains per panicle, the grains weight, plant height, and seed setting rate. A new cytoplasmic male sterile line, Rongfeng 3A, with Pi1, Pi2, and Xa23, was successfully developed through successive backcross breeding.Keywords: Gene pyramiding, marker-assisted backcross breeding, rice blast, bacterial bligh

Structural View of a Non Pfam Singleton and Crystal Packing Analysis

Comparative genomic analysis has revealed that in each genome a large number of open reading frames have no homologues in other species. Such singleton genes have attracted the attention of biochemists and structural biologists as a potential untapped source of new folds. Cthe_2751 is a 15.8 kDa singleton from an anaerobic, hyperthermophile Clostridium thermocellum. To gain insights into the architecture of the protein and obtain clues about its function, we decided to solve the structure of Cthe_2751.The protein crystallized in 4 different space groups that diffracted X-rays to 2.37 Å (P3(1)21), 2.17 Å (P2(1)2(1)2(1)), 3.01 Å (P4(1)22), and 2.03 Å (C222(1)) resolution, respectively. Crystal packing analysis revealed that the 3-D packing of Cthe_2751 dimers in P4(1)22 and C222(1) is similar with only a rotational difference of 2.69° around the C axes. A new method developed to quantify the differences in packing of dimers in crystals from different space groups corroborated the findings of crystal packing analysis. Cthe_2751 is an all α-helical protein with a central hydrophobic core providing thermal stability via π:cation and π: π interactions. A ProFunc analysis retrieved a very low match with a splicing endonuclease, suggesting a role for the protein in the processing of nucleic acids.Non-Pfam singleton Cthe_2751 folds into a known all α-helical fold. The structure has increased sequence coverage of non-Pfam proteins such that more protein sequences can be amenable to modelling. Our work on crystal packing analysis provides a new method to analyze dimers of the protein crystallized in different space groups. The utility of such an analysis can be expanded to oligomeric structures of other proteins, especially receptors and signaling molecules, many of which are known to function as oligomers

Confined magnetic vortex motion from metal-organic frameworks derived Ni@C microspheres boosts electromagnetic wave energy dissipation

Magnetic domain structure plays an important role in regulating the electromagnetic properties, which dominates the magnetic response behaviors. Herein, unique magnetic vortex domain is firstly obtained in the Ni nanoparticles (NPs) reduced from the Ni-based metal-organic frameworks (MOFs) precursor. Due to both the high symmetry spheres and boundary restriction of graphited carbon shell, confined magnetic vortex structure is generated in the nanoscale Ni core during the annealing process. Meanwhile, MOFs-derived Ni@C assembly powders construct special magnetic flux distribution and electron migration routes. MOFs-derived Ni@C microspheres exhibit outstanding electromagnetic (EM) wave absorption performance. The minimum reflection loss value of Ni@C–V microspheres with vortex domain can reach −54.6 ​dB at only 2.5 ​mm thickness, and the efficient absorption bandwidth up to 5.0 ​GHz at only 2.0 ​mm. Significantly, configuration evolution of magnetic vortex driven by the orientation and reversion of polarity core boosts EM wave energy dissipation. Magnetic coupling effect among neighboring Ni@C microspheres significantly enhances the magnetic reaction intensity. Graphitized carbon matrix and heterojunction Ni–C interfaces further offer the conduction loss and interfacial polarization. As result, MOFs-derived Ni@C–V powders display unique magnetic vortex, electronic migration network, and high-performance EM wave energy dissipation