Day 1 :
Keynote Forum
Jaleel Kareem Ahmed
Babylon University, Iraq
Keynote: Red Beet Juice and Urine System
Time : 10:15-11:00
Biography:
Jaleel Kareem Ahmed has his expertise in evaluation in iron and steel industry. He has registered 3 patents in USA, UK and Iraq about using water in iron industry and wax for storage and transportation and using wax for carburizing of steel. He has used chlorophyll as gamma ray absorber to protect Iraqi children from cancer and mechanically red beet juice as scavenger for poisonous heavy metal ions and anticancer and detoxification of urea and uric acid from human body via urine system. In 2013, he was awarded with Scientific Medal from Iraqi Government. In 2014, he got qualified as a Member in Who is Who network. He has been serving as a Reviewer of Journal of Advances in Polymer Technology.
Abstract:
A case study is carried out on the urine of a man with 40 years old. Two samples of urine are taken from the urine system one after drinking concentrated red beet juice (mechanically extracted) and the second one without drinking. Using Ultraviolet-visible absorption spectra measurements was done, the results showed that with concentrated juice the absorption bands are shifted toward low energy due to the hydrogen bond formation by exchangeable proton from the juice (anthocyanin pigments) to the lone pair of electrons on the oxygen and nitrogen atoms in uric acid and urea and vice versa which shifted the n-p* absorption band to the lower energy, while dilution the above sample spectrum shows shifting to the higher energy, this is due to the low hydrogen bonding formation with uric acid and urea due to the low concentration of exchangeable proton upon dilution, as well as water is a good hydrogen bonding competitor. From ultraviolet-visible spectra we conclude that absorption band shifted to the lower energy with drinking concentrated juice and to the higher energy with diluted one which reflects the importance of concentration of the juice on hydrogen bonding formation and on the enhancing of detoxification of uric acid and urea from the blood, thus we recommended high concentration juice which can obtain from red beet (highest concentration of anthocyanin than other fruit). Dilution of pure urine sample does not affect its spectrum; this is because water is already present in urine in a good quantity comparing with uric acid and urea concentrations thus no effect from more water. Results shows that with drinking high concentrated red beet juice viscosity, electrical conductivity and refractive index of exit urine decreased, which enhances detoxification process. The viscosity of urine with juice lower than viscosity of pure water which is 1.00 cP at 20 oC, this make urine+juice easier to flow through urine system than water alone. The pP of urine after drinking the juice is increased; this is due to the capture of the proton of uric acid by anthocyanin which is less acidic then former. The increase of pP results in lessens the tension of the human. The density of the urine increases slightly due to the more hydrogen bonding formation with the anthocyanin results in reducing the volume of the unit weight of the sample.
Keynote Forum
Ruey-Hwa Chen
Institute of Biological Chemistry-Academia Sinica, Taiwan
Keynote: Regulation of BIK ubiquitination determines life-death fate of cellular stress responses and anti-tumor activity
Time : 11:15-12:00
Biography:
Ruey-Hwa Chen has received BS and MS degrees from National Taiwan University and PhD degree from Michigan State University. In 2006, she relocated to Institute of Biological Chemistry, Academia Sinica to be a Research Fellow and promoted to Distinguished Research Fellow in 2012. She was also an Associate Professor and Professor at National Taiwan University. She has served as Deputy Director of Institute of Biological Chemistry in 2011-2013. She has received several awards, including Outstanding Scholar Research Grant, National Science Council; Merit Research Award, National Science Council; Outstanding Award, TienTe Lee Biomedical Foundation; TBF Chair in Biotechnology; the 59th Academic Award, The Ministry of Education; Merit MOST Research Fellow Award and Taiwan Outstanding Women in Science, Wu Chien-Shiung Education Foundation. Her current research focuses on protein ubiquitination in tumorigenesis and tumor progression and protein ubiquitination in autophagy.
Abstract:
The BH3-only pro-apoptotic protein BIK is regulated by ubiquitin-proteasome system. However, the underlying mechanism of this regulation and its physiological functions remain elusive. Here, we identify a BIK ubiquitination/degradation mechanism mediated by ubiquitin ligase Cul5ASB11. Under ER stress, ASB11 is transcriptionally activated by IRE1/XBP1 axis of unfolded protein responses, which results in an enhancement of BIK ubiquitination and proteolysis. Conversely, genotoxic agents act through p53 to down-regulate IRE1 and ASB11, thereby stabilizing BIK. These opposite regulations of ASB11-medaited BIK ubiquitination participate in part to the cell adaptation to ER stress and DNA damage-induced apoptosis. Finally, IRE1 inhibitors stabilize the active form of BIK and increase its anti-tumor efficacy in triple negative breast cancers. Together, our study identifies a BIK ubiquitin ligase, uncovers the opposite regulations of this BIK ubiquitination by ER stress and DNA damage, and exploits the targeting of BIK ubiquitination pathway combined with active BIK for cancer therapy.
Keynote Forum
Tomohiko Utsuki
Tokai University, japan
Keynote: Automatic control of physiological state for future clinical treatment- Necessity of mathematical models
Time : 12:00-12:45
Biography:
Tomohiko Utsuki has obtained his PhD in Health Science from Tokyo Medical and Dental University, Japan. He is currently an Associate Professor of Biomedical Engineering at Tokai University, Japan. His research interest is in automatic control of physiological state for future medical treatment; especially he has developed an automatic control system of brain temperature and applied it to patients for clinical hypothermia in the intensive care unit of Tokyo Medical and Dental University, Medical Hospital. Presently, he is constructing models of cerebral blood flow, intracranial pressure and brain temperature in consideration of their distribution in brain tissue in order to develop an automatic integrated control system of brain's physiological state for more advanced brain resuscitation treatment.
Abstract:
In operating room, emergency room and intensive care unit, medical staff have so heavy burden that they can't sometimes have enough time and attention for clinical treatment. Especially, many routine tasks, which demand advanced knowledge and skills to medical staff, are required for the management of physiological state pertinent to life-support. Thus, it is very useful to develop and apply automatic control systems of physiological state for alleviating such burden in clinical treatment. A few of systems have been developed and attempted to apply to patients in clinical treatment, such as automatic control systems of blood-sugar level, hemoglobin oxygen saturation in artery and concentration of carbon dioxide in alveoli. Notably, an automatic control system of brain temperature was developed and clinically applied. The designing and development of such system usually require a model of relevant physiological state as the controlled object in the simulation test of the system or as the element added in the system's controller, because heuristic system designing based on experiments on animals is not allowed ethically. On the stage of basic development, even if a system is designed by a method without using model, such as ‘Fictitious Reference Iterative Tuning’, a model of physiological state is necessary for verification of the system by simulation. In this presentation, various automatic control systems of physiological state are presented including each model used in the development. Moreover, a model of cerebral blood circulation and extracellular fluid migrations in cerebral tissue are explained, which are constructed as the elements of the integrative model of brain’s physiological state. This integrative model is required for developing an integrated control system, by which intracranial pressure, cerebral blood flow and brain temperature will be automatically controlled in consideration of the mutual effects for advanced brain resuscitation.
- Neurobiology | Structural and Cell Biology | Chemical Biology| Systems Biology | Immunology | Nano Engineering | Stem cell biology and Regenerative medicine| Bio Physics and Structural Biology | Bio-Engineering | Computational Structural Biology | Structural Biology in Drug Discovery | Data Mining in Structural Biology | Cardiac cell biology | Cancer Biology | Structural Biochemistry
Location: CRYSTAL
Session Introduction
Xiongwu Wu
National Institutes of Health Bethesda, USA
Title: New Structure And Energy Cycles Of Kinesin Dimers Walking On Microtubules Revealed From Molecular Simulations
Time : 13:45- 14:15
Biography:
Xiongwu Wu has his expertise in molecular simulation and method development. He developed Self-Guided Molecular/Langevin Dynamics simulation (SGMD/SGLD) methods that enable molecular simulation to access long-time scale events. He has developed core-weighted grid-threading method for rigid fitting of proteins into low resolution cryo-EM maps and Map-restrained SGLD (MapSGLD) method to flexible fit protein structures into cryo-EM maps. He is also the developer for both molecular simulation and modeling packages AMBER and CHARMM
Abstract:
Kinesins are motor proteins that move unidirectionally along microtubules as they hydrolyze ATP. Although the general features of the kinesin walking mechanism are becoming increasingly clear, some key questions remain unanswered, such as how they convert the chemical energy of ATP into mechanical energy and walk processively. In this study, through molecular simulations and free energy calculations, we found that in aqueous solution, kinesin favors an extended form with its microtubule-binding interface (MTBI) motif unfolded, as seen in a recent X-ray structure of kinesin-8. Through the flexible fitting of two newly released cryo-electron microscopy (cryo-EM) maps, we derived atomic structures of the kinesin dimer-microtubule complexes in both two-head-bound and one-head bound states. Free energy calculations showed that kinesin bound to microtubules has a lower free energy than the extended form and that the free energy difference is in the range of the free energy released by ATP hydrolysis. The transition between the extended and compact forms, the structural differences of the leading and trailing heads and atomic force simulations lead us to a completely new mechanism by which kinesin dimers walk on microtubules.
Wolfgang B Fischer
National Yang-Ming University, Taiwan
Title: Structural modeling of membrane proteins from viruses
Time : 14:15 -14:45
Biography:
Wolfgang Fischer is a Professor at the Institute of Biophotonics, School of Biomedical Science and Engineering, National Yang-Ming University, Taiwan. He has obtained his PhD in Chemistry at Heidelberg University, Germany, working in the field of vibrational spectroscopy in 1991. He has worked for years in USA like in Boston University as Postdoctoral Fellow working on bacteriorhodopsin using vibrational spectroscopy; Germany in Analytical Chemistry, working on ion channels as potential biosensors; Oxford University as EU Marie Curie Research Fellow and later as Lecturer, working on viral ion channels using bilayer recordings and molecular dynamics simulations and later moved to Taiwan. His field of research is on biophysical aspects describing dynamics and energetic of protein-protein interactions (PPIs) of membrane proteins. The focus is on the development of computational platform technologies to support structural modeling for drug discovery and design as well as for materials sciences.
Abstract:
Computational methods comprise a valuable tool to close the sequence-structure gap, especially for membrane proteins. At this stage, secondary structure prediction programs are available to identify putative stretches of helical transmembrane domains (TMDs) while few programs are developed to predict a beta sheet fold as the membrane spanning motif. With the knowledge about the putative TMDs, here adopting a helical motif, at hand these TMDs can be assembled into a tertiary structure and finally into putative quaternary structures using docking approaches. As a test case, viral channel forming proteins (VCPs), sometimes also called viroporins, are used to develop strategies to generate plausible structures. VCPs are about five time smaller than human ion channels and therefore used as a miniaturized system to investigate how ion channels are formed. Using E5 protein of human papilloma virus type 16 (HPV-16), the assembly of a polytopic membrane protein with three TMDs is presented in its hexameric form. Using a docking approach, the monomeric form is generated first before assembling into the hexamer. The quality of the model is assessed using potential of mean force calculations (PMF) identifying weak ion selectivity. Principle component analysis (PCA) of the data from a classical molecular dynamics simulation reveal asymmetric dynamics of the monomers. These dynamics are compared with those derived for other VCPs such as polytopic p7 of hepatitis C virus (HCV) with two TMDs and bitopic M2 of influenza A. Finally, coarse grained simulations are applied to probe the formation of the quaternary structure of e.g., Vpu of HIV-1.
Anil Batta
Govt. Medical College-Amritsar, India
Title: Problems of mental adaptation in patients with diabetic foot syndrome
Time : 14:45-15:15
Biography:
Anil Batta is presently an Associate Professor and Senior Consultant in Govt. Medical College, Amritsar, Punjab, India. He has received his MBBS and MD in Medical Biochemistry from Govt. Medical College, Patiala in 1984 and 1991, respectively. His research interest is mainly in clinical application especially cancer and drug de-addiction. He has supervised more than 15 MD, MSc and Doctorate researches and published more than 30 international research papers. He is the Chief-Editor of America’s Journal of Biochemistry. He is also working as an Advisor to the Editorial Board of International Journal of Biological and Medical Research. He is also a Deputed Advisor to Pakistan Medical Journal of Biochemistry. He has been attached as Technical Advisor to various national and international conferences in Biochemistry, also with hi-tech endocrinal, genetics and automated labs of GGS Medical College, Faridkot.
Abstract:
Aim: It is known that in patients with Diabetic Foot Syndrome severe forms of mental disadaptation are observed. They are manifested psycho-emotional disorders and poor treatment compliance. The aim of this work was to study the forms of mental disadaptation in patients with Diabetic Foot Syndrome and the role of psychological and somatic factors in their development.
Method: The following parameters: Levels of anxiety and depression, alexithymia, irrational cognitive principles, personality profile, severity of somatic disorders and treatment compliance were studied in 120 Diabetic Foot Syndrome patients.
Result: The study revealed two main groups of patients with various forms of mental disadaptation and some relationship of psycho-emotional and somatic disorders. In the first patient’s group with severe form mental disadaptation, there were observed high level of alexithymia, depression, the prevalence of psychopathic personality types, combined with deep encephalopathy, cognitive disorders and long duration of disease. A poor compliance of treatment, the progressive deterioration of the disease, large number of lower limb amputations was observed also in this group of patients. In the second patients’ group with less severe form of mental disadaptation, there were observed small level of alexithymia, high anxiety and the prevalence of neurotic personality types and a shorter duration of disease. A good treatment compliance and smaller number of lower limb amputation was also observed in this group of patients.
Whitney Yin
University of Texas Medical Branch, USA
Title: Communication between DNA synthesis and proofreading in mitochondrial DNA polymerase
Time : 15:15-15:45
Biography:
Whitney Yin is an Assistant Professor for University of Texas Medical Branch, USA. She has received Doctoral degree (PhD) in Department of Pharmacology and Toxicology. She is the Editorial Board Member of many peer reviewed journals and has many publications in national and international journals to her credit. She is committed to highest standards of excellence and it proves through her authorship of many books.
Abstract:
Like all high-fidelity DNA polymerases, human mitochondrial DNA polymerase, Pol-g contains polymerization (pol) activity for DNA synthesis and proofreading exonuclease (exo) activity for error correction. Pol-g is a holoenzyme consists of a catalytic subunit Pol-gA and accessory subunit Pol-gB. Pol-gA contains all enzymatic activity including pol, exo and deoxyribose phosphate (dRP) lyase, Pol-gB contains no enzymatic activity of its own but regulates all Pol-gA activates, consequently, the holoenzyme has higher processive and elevated dRP lyase activity. We determined crystal structures of Pol-g ternary complex with primer/template DNA and an incoming nucleotide to understand how the two active sites communicate with each other. The ternary complex reveals a b-hairpin situated between the two active sites in Pol-gA could transfer the information of nucleotide misincorporation in the pol site to the exo site 40Å away for excision. Our enzymatic studies indicate that Pol-g variants in the b-hairpin completely abolish pol activity while retains full exo activity. Additionally, we performed molecular simulation and found the hairpin region are energetically destabilized with perturbation of Pol-g variants in either pol or exo active sites, revealing for the first time that the two active sites are energetically coupled and DNA strand shuttling is accompanied by destabilization of the path connecting the pol and exo sites.
- Special Session
Location: CRYSTAL
Session Introduction
Joel I Osorio
Westhill University, Mexico
Title: RegenerAge System: Therapeutic effects of combinatorial biologics (mRNA and allogenic MSCs) with a spinal cord stimulation system on a patient with spinal cord section
Time : 9:15-10:15
Biography:
Joel I Osorio is the CEO and Founder of Biotechnology and Regenerative Medicine at RegenerAge International™. He is the Vice President of International Clinical Development for Bioquark, Inc. and Chief Clinical Officer at ReAnima™ Advanced Biosciences. He is an Advance Fellow by the American Board of Anti-Aging and Regenerative Medicine (A4M), Visiting Scholar at University of North Carolina at Chapel Hill (Dermatology) and Fellow in Stem Cell Medicine by the American Academy of Anti-Aging Medicine and University of South Florida.
Abstract:
As it has been previously demonstrated that coelectroporation of Xenopus laevis frog oocytes with normal cells and cancerous cell lines induces the expression of pluripotency markers and in experimental murine model studies, mRNA extract (Bioquantine®) purified from intra and extra-oocyte liquid phases of electroporated oocytes showed potential as a treatment for a wide range of conditions, including Spinal Cord Injury (SCI) among others. The current study observed beneficial changes with Bioquantine® administration in a patient with a severe SCI. Pluripotent stem cells have therapeutic and regenerative potential in clinical situations CNS disorders even cancer. One method of reprogramming somatic cells into pluripotent stem cells is to expose them to extracts prepared from Xenopus laevis oocytes. The positive human findings for spinal cord injury with the results from previous animal studies with experimental models of traumatic brain injury and SCI respectively as our evidence and due to ethical reasons, legal restrictions and a limited number of patients, we were able to treat only a very small number of patients, deciding to include in our protocol the RestoreSensor SureScan to complete it. Based on the electrical stimulation for rehabilitation and regeneration after spinal cord injury published by Hamid and MacEwan, we designed an improved delivery method for the in situ application of MSCs and Bioquantine® in combination with the RestoreSensor® SureScan®. To the present day the patient who suffered a complete section of spinal cord at T12-L1 shows an improvement in sensitivity, strength in striated muscle and smooth muscle connection, 13 months after the first treatment and 6 months after the placement of RestoreSensor® at the level of the lesion, showing an evident improvement on his therapy of physical rehabilitation (legs movement) on crawling forward and backwards and standing on his feet for the first time and showing a progressively important functionality on both limbs.
- Young Research Forum
Location: CRYSTAL
Session Introduction
Lisa M Domke
German Cancer Research Center, Germany
Title: The seminiferous tubules of mammalian testes: A different epithelium encased by a bandage structure of smooth muscle cell monolayers
Time : 16:00-16:30
Biography:
Lisa M Domke is currently a PhD student in the Helmholtz Group for Cell Biology of Professor Werner W Franke at German Cancer Research Center, Germany. She has prepared her Master’s thesis with one of the pioneers in cancer research, Professor Dr. Robert A Weinberg at the Massachusetts Institute of Technology (MIT) in Cambridge, USA. The nature of her degree in Biotechnology has allowed her to learn various analytical as well as light and electron microscopical techniques and to work in different fields of life sciences.
Abstract:
Mature seminiferous tubules (STs) of mammalian testes comprise the Sertoli cells and germ cells and are tightly surrounded by a special peritubular cell wall. Using biochemical, immunocytochemical and electron microscopical methods, we have determined that STs differ from all other epithelia by the absence of cytokeratin intermediate filaments (IFs) but are rich in vimentin IFs, do not contain major epithelial marker structures and molecules such as desmosomes or E-cadherin-based adherens junctions (AJs) but contain exclusively N-cadherin-based AJs. In Sertoli cells, we have found two new junction structures: (1) N-cadherin-based areae adhaerentes which often represent even very large areas connecting Sertoli cells with each other or with germ cells. (2) Special AJs arranged in closely and regularly spaced rows of tight junction-like structures and associated with 5-8 nm wide cytoplasm-to-cytoplasm channels (cribelliform junctions). The seminiferous tubule cells are attached to the peritubular wall by a well-developed basal lamina but lack hemidesmosomes and hemidesmosomal marker molecules. The peritubular wall is a stack system of layers of extracellular matrix (ECM) structures alternating with monolayers of very flat lamellar smooth muscle cells (LSMCs). These LSMCs represent differentiated smooth muscle cells (SMCs; positive for smooth muscle α-actin, the corresponding myosin light and heavy chains, α-actinin, tropomyosin, smoothelin, desmin, vimentin, filamin, talin, dystrophin, caldesmon, calponin and protein SM22α). The cells are laterally connected often in overlapping protrusions by AJs containing cadherin-11 as the predominant cadherin, and also P-cadherin and rarely N-cadherin, anchored in cytoplasmic plaques containing β-catenin, proteins p120 and p0071, plakoglobin and protein myozap. LSMCs also contain typical SMC structures such as dense bodies, plasma membrane-associated focal adhesions and caveolae. Thus, we conclude that these LSMCs represent a specific SMC type and not just myoid cells or myofibroblasts as stated in the literature.
Jacob Anderson C Sanchez
Pampanga State Agricultural University, Philippines
Title: Molecular Identification of Sour (Tamarindus indica L.) and Sweet Tamarind (T. indica L.var.Aglibut) using ITS, rbcL and matK DNA markers
Time : 16:30-17:00
Biography:
Jacob Anderson C Sanchez is a Faculty/Researcher of the Pampanga State Agricultural University. His main objective is to conduct researches related to the development of Aglibut sweet tamarind using molecular biology techniques. He is passionate in conducting researches that are essential in ensuring the profit of the marginalized sector. He has also presented his various researches in international conferences at Singapore, Japan, and France.
Abstract:
Aglibut sweet tamarind is a priority commodity of the Pampanga State Agricultural University (PSAU). However, this variety looks like sour tamarind especially when they are still seedlings. This may result in potential economic loss for farmers or business capitalists who would venture in this lucrative business. Therefore, this study aimed to obtain their molecular identification using cpDNA (rbcL, matK) and nrDNA (ITS) markers; to determine the relationships of the samples using Maximum Likelihood and Maximum Parsimony Cladograms and to evaluate the universality of ITS, rbcL and matK in tamarind. BLAST results showed that majority of the samples belong to Tamarindus indica with 99-100% homology. Maximum Parsimony (MP) and Maximum Likelihood (ML) for matK showed that Aglibut sweet tamarind formed a monophyletic group with PSAU’s sour tamarind and paraphyletic to wild-type sour tamarind obtained from Lubao, Pampanga. On the other hand, MP and ML for ITS did not show a fully resolved tree. For the universality, results showed that matK had 100% PCR and sequencing success rates. Meanwhile, ITS showed 100% PCR success rate and 83% sequencing success, whereas rbcL did not work well for the samples. Hence, we conclude that DNA barcodes matK and ITS are the genetic markers that can be used for molecular identification of Aglibut and sour tamarind samples. More importantly, we report that Aglibut sweet tamarind has closer genetic relationship with the PSAU sour tamarind than other varieties
- Video Presentation
Location: CRYSTAL
Session Introduction
Chantal Prévost
Institut de Biologie Physico-Chimique, Paris
Title: Structural insights on homologous recombination
Time : 17:00-17:30
Biography:
Chantal Prévost is a Researcher at the Theoretical Biochemistry Laboratory (LBT) of the French National Research Center (CNRS), in Paris. She has developed a strong expertise in studying complex biological processes in silico via the integrative exploration of unstable macromolecular self-assembly substates. She has elaborated new algorithms for flexible macromolecular docking and protein fiber modeling. She presently applies this expertise to tackling the mechanism of homologous recombination as well as exploring the architecture of oligomeric assemblies, in collaboration with the Prentiss team in Harvard University, USA
Abstract:
Homologous recombination (HR) is an essential biological process common to all living cells that maintains the genome integrity by faithfully repairing double-strand breaks (DSBs). The HR process searches the genome for a region that is homologous to the broken DNA and uses this region as a template to restore the DNA integrity, via the capture of the complementary strand that gets paired with the damaged DNA. Nucleofilaments resulting from the polymerization of a recombinase (RecA in prokaryotes) on each damaged DNA strand recruit the genomic DNA, test it for homology and promote strand exchange. The coordination of dynamic stages with different time and length scales enables the process to be simultaneously fast and stringent. By combining docking explorations and molecular dynamics simulations at the atomic level, we have integrated the results from 30 years studies into new structural insights on the HR process. We propose a mechanism for the initial recognition/strand exchange phase, where more than 80% of non-homologous sequences are eliminated, that uses mechanical tension in the DNA to locally destabilize the base pairing interactions in the searched DNA and perform swift homology tests via pairing exchange. We also investigated the role of ATP hydrolysis in the slower phases of HR using molecular dynamics simulations. These simulations, based on the hypothesis that the filament can change the internal arrangement of its monomers upon ATP hydrolysis, revealed how hydrolysis may promote reverse strand exchange in the filament. This provides a structural interpretation to the observed destabilization of the strand exchange product within filaments where ATP is hydrolyzed.
- Structural Bioinformatics and Proteomics |Structural Biology and Single Molecules |Molecular Modeling and Dynamics|3D Structure Determination|Computational Approaches in Structural Biology|Structural Molecular Biology| Structural Virology |Hybrid Approaches for Structure Prediction|Sequencing|Drug Designing|Signaling Biology|Frontiers in Structural Biology |Recent Advances in Structural Biology |Structural Biology in Cancer Research|Structural Biology Complexity Arenas
Location: CRYSTAL
Session Introduction
Nibedita Naha
National Institute of Occupational Health, India
Title: Tobacco smoking and nicotine modulate Nrf2-BDNF-Dopaminergic signaling in cerebral cortex and testis of adult rats during addiction and withdrawal
Time : 11:00- 11:30
Biography:
Nibedita Naha has her expertise in molecular approach of reproductive toxicology and neurotoxicology, cell signaling and RNA interference using animal models and human subjects with respect to occupational exposure. She has a passion in improving the health and wellbeing through her research findings in the respective fields since 2000. She is the recognized PhD Guide and Reviewer and Editorial Member of several international and national peer-reviewed journals. She is also the CPCSEA nominee for monitoring animal experiments in several research organizations and pharmaceutical companies in India, selected by MoEF, Government of India. She has authored 25 research articles. She has one international patent based on her Post-doctoral research. She is also the Life Member of several national and international scientific societies, Elected Member of PSI and Advisory Board Member of some national conferences.
Abstract:
Statement of the Problem: Tobacco smoking (nicotine) is associated with addiction behavior, drug-seeking and abuse. Several organ systems can also be affected by nicotine/smoking. However, the mechanisms that mediate this association especially, the role of brain-derived neurotrophic factor (BDNF), dopamine (DA) and nuclear factor erythroid-2 related factor-2 (Nrf2) signaling in the cerebral cortex as well as local neurochemical system in the testis, are not fully known.
Aim: The aim of the present study is to explore the toxic consequence of short- and long-term exposure and withdrawal in adult rodent models.
Methodology: We treated male Wistar rats with different doses of oral nicotine and passive smoking for 4-week (short-term) and 12-week (long-term) duration, where doses closely mimic the human smoking scenario. Also, in the precipitated withdrawal model, nicotine acetylcholine receptor blocker Mecamylamine, was given intraperitonially after nicotine treatment followed by biochemical, immune-histological, molecular and statistical analyses.
Findings: The dose- and time-dependent anxiogenic and depressive behavior and cognitive interference are associated with neurodegeneration and DNA damage in the cerebral cortex from layer II onwards upon exposure to nicotine/smoking. Further, the dose- and time-dependent loss of developing spermatogonia and spermatocytes of the seminiferous tubules, disruption of basement membrane and DNA damage, results in low sperm count by smoking/nicotine treatment. Upregulation of pro-oxidants, i.e., reactive oxygen species and inducible nitric oxide synthase (iNOS), over-expression of BDNF, DA and DA marker, tyrosine hydroxylase are linked with concomitant downregulation of antioxidants i.e., ascorbate and Nrf2 in both the exposed cerebral cortex and testis. High serum cotinine of the exposure models of short and long durations are found to be reversed in the withdrawal model. Also, the reversible expressions of Nrf2, iNOS, DA and DA receptor along with tissue architecture are observed in the same area of the cerebral cortex and testis during Mecamylamine treatment, probably due to inhibition of nicotinic effects on both the tissues by releasing pituitary gonadotrophins. However, BDNF expression is not affected by Mecamylamine in the present study, as BDNF might follow differential response pattern upon nicotine withdrawal.
Conclusion & Significance: The intervention of BDNF-DAergic signaling and depletion of antioxidants are important factors in pathogenesis of the cerebral cortex and testis during nicotine/tobacco smoking, leading to neurobehavioral and reproductive impairments respectively, which are counteracted by Mecamylamine, resulting in reversal of nicotine-induced tissue lesion upon withdrawal through upregulation of Nrf2-ARE-mediated transcription mechanism. Thus, our results confirm the beneficial role of the receptor blocker in local BDNF-DAergic circuit of the testis and cerebral cortex that could underpin the novel therapeutic approaches targeting tobacco smoking/nicotine’s neuropsychological disorders including drug addiction.
Wei Li
Shantou University Medical College, China
Title: Title: How do SMA-linked mutations of SMN1 lead to structural/functional deficiency of the SMA protein?
Time : 12:00-12:30
Biography:
Wei Li has his expertise and passion in fundamental biological and medical research, particular in areas related to three-dimensional structures of biologically relevant macromolecules and experimental data-driven molecular dynamics (MD) simulation and molecular docking and modeling. After years of wet- and dry-lab experience in research (including solution-state NMR, python programming and high-performance computer usage), he has developed a set of skills to uncover novel structural/functional insights through computational analysis of experimentally determined structures of biological molecules. Here, as an example in spinal muscular atrophy-related studies, his work presented the first attempt to link clinically identified SMA-linked mutations of SMN1 to the structural/functional deficiency of SMN, the protein that is critical to this neuromuscular disease.
Abstract:
Spinal muscular atrophy (SMA) is an autosomal recessive neuromuscular disease with dysfunctional α-motor neurons in the anterior horn of the spinal cord. SMA is caused by loss (~95% of SMA cases) or mutation (~5% of SMA cases) of the survival motor neuron 1 gene SMN1. As the product of SMN1, the SMN protein is a key component of the SMN complex, and also involved in the biosynthesis of the small nuclear ribonucleoproteins (snRNPs), which play critical roles in pre-mRNA splicing during the pathogenesis of SMA. To investigate how SMA-linked mutations of SMN1 lead to structural/functional deficiency of SMN, a set of computational analysis of SMN-related structures were conducted and are presented. Of extraordinary interest, the computational structural analysis highlights three SMN residues (Asp44, Glu134 and Gln136) with SMA-linked missense mutations, which cause local disruptions of electrostatic interactions for Asp44, Glu134 and Gln136, and result in three functionally deficient SMA-linked SMN mutants, Asp44Val, Glu134Lys and Gln136Glu. From the computational structural analysis, it appears also possible that SMN’s Lys45 and Asp36 act as two electrostatic clips at the SMN-Gemin2 complex structure interface, structurally stabilizing the SMN-Gemin2 complex. Moreover, the structural analysis of a group of four further SMA-linked mutations (Trp92Ser, Trp102X, Ala111Gly and Ile116Phe) highlight the potential significance of the deeply buried hydrophobic side chains of Trp92, Trp102, Ala111 and Ile116 in the SMN Tudor domain, the essential part of SMN for its ability to bind the Sm proteins of snRNPs
S Mondal
National Institute of Animal Nutrition and Physiology, India
Title: Effect of PGF2 receptor antagonist on prostaglandin production and COX-2 protein expression in bovine endometrial epithelial cells
Time : 12:30-13:00
Biography:
S Mondal has completed his PhD from Indian Veterinary Research Institute, Bareilly and Postdoctoral studies from Laval University, Canada. He is presently working as Principal Scientist at NIANP, Bangalore. He has been working in the field of molecular endocrinology, reproductive genomics and stress physiology for last 20 years. He has published over 55 papers in various national and international journals of repute. He has also received several prestigious awards like Siri Research Award, Prof. G P Talwar Midcareer Scientist Award, Prof. G K Pal Award, Fellow of Indian Chemical Society, Fellow of Society for Applied Biotechnology, Fellow of Indian Association of Biomedical Scientists, Dr. K Anji Reddy Award, Prof. P B Sen Memorial Oration Award, Biotechnology Overseas Associateship Award (Long term), ISSRF Young Scientist Award and Indian Science Congress Association Award.
Abstract:
Statement of the Problem: Prostaglandins (PGs) play an important role in regulation of estrous cycle, recognition of pregnancy and implantation in ruminants. The first limiting step in the generation of PGs is the transformation of arachidonic acid by cyclooxygenases-1 and -2 (COX-1, -2). The downstream enzymes, prostaglandin E synthase (PGES) and prostaglandin F synthase (PGFS) catalyze the conversion of PGH2 into PGE2 and PGF2a, respectively. PGF2a acts as the luteolytic agent to control estrous cycle whereas PGE2 helps in implantation and maintenance of pregnancy. PGF2a exerts its autocrine/paracrine action by binding to its receptors to mobilize intracellular Ca2+ and IP3. Activation of FP receptors by PGF2α results in phospholipase C activation, inositol triphosphate hydrolysis and intracellular calcium flux. Pharmacological inhibition of FP receptor antagonist (AL 8810) has been found to decrease PGE2 production in human endometrial cells treated with IL-1β.
Purpose: The purpose of this study is to explore the effect of PGF2a receptor antagonist on prostaglandin production and protein expression in bovine endometrial epithelial cells.
Methodology & Theoretical Orientation: Endometrial epithelial cells at the stage of confluence were incubated with vehicle and/ FP receptor antagonist (AL 8810) for 30 min. Thereafter, the cells were stimulated with vehicle, OT, IFN and OT+IFN in absence and/ presence of AL 8810 for 6 hrs.
Findings: Oxytocin had been found to increase the production of PGF2a in cultured cells in presence of both 10 µM and 25 µM AL 8810 but production was more with 10 µM AL 8810 treatment group. Similarly, OT increased PGE2 production in presence of 10 µM AL 8810 in epithelial cells. The expression of COX-2 protein increased by treatment of AL8810 in presence of OT and OT+IFN but decreases in the presence of IFN alone.
Conclusion & Significance: Production of prostaglandin and COX-2 expression are modulated by PGF2a receptor antagonist
Riad H Khalil
Alexandria University, Egypt
Title: Modulatory effect of different doses of essential oils of Origanium vulgare on the antioxidant, antimicrobial and immune-related genes of seabass Dicentrachus labrax challenged with Vibrio alginolyticus
Time : 14:00-14:30
Biography:
Riad H. Khalil is a senior professor of Fish diseases, Department of Poultry and Fish diseases, faculty of Veterinary medicine in Alexandria University. He has over 15 years working experience fish microbiologist and research focusing on fish diseases and water resource management. He has contributed more than 75 articles in local and international scientific journals and has supervised 45 PhD and 85 master students
Abstract:
A total 3000 pieces of sea bass (Dicentrachus labrax) fingerlings were stocked in a nursery earthen pond by the rate of 3000 pieces with body weight ranges between 40 to 50 grams per pieces in 1000 cubic meters and 90 fish (30×3 replicates) were stocked in aerated aquaria to assess the effects of essential oil of Origanum vulgaris and challenged with 0.5 ml of a virulent strain of Vibrio algenolyticus at 4×106 cells/ml administered intraperitoneally. The experiments were conducted in two phases (In situ phase and Aquarium phase) to evaluate the essential oils of Origanum vulgare at different concentrations 0.5 and 1 ml/kg feed on various antioxidants enzymes activities in liver tissue and to determine antimicrobial activity against different bacteria, fungus and yeasts and detection of gene expression of cytokine from liver as well as effect on Vibrio algenolyticus challenged fingerlings of sea bass. The results revealed that the essential oils of Origanum vulgare increases the catalase activity and severe drop of lipid peroxidation level in liver tissues compared with control group. In the liver of sea bass supplemented with essential oil of Origanum vulgare caused down regulation of HSP. In addition to the essential oils of Origanum vulgare, it has antimicrobial affects against wide range of bacterial and fungal agents of cultured fish. In conclusion the current results demonstrate the oils of O. vulgare (0.5 ml and 1 ml kg-1) improving the fish health status and immune resistance against Vibrio alginolyticus infection and act as antimicrobial and antioxidant
Santanu Datta
Bugworks Research, India
Title: Novel antibacterial series identified through integrated drug discovery technology platform
Time : 14:30-15:00
Biography:
Santanu is currently the CSO of Bugworks antibiotics discovery SME. Prior to this, he was the Principal Research Scientist in AstraZeneca India, where he spent more than 2 decades working in Infectious diseases, with a focus on Malaria and MTB. At AstraZeneca, Santanu scientifically mentored programs across the discovery pipeline and pioneered many ground-breaking concepts such as those of gene and chemical vulnerability. He has served as Principal Investigator in several prestigious research grants from Wellcome Trust, EU and DBT India. His current interest is in systems biology and its application in anti-infective drug discovery and in Industrial Biotechnology specifically the interface between insilico and experimental biology. Santanu, received his Ph.D. from Calcutta University in Biophysics in 1981 and was trained as a molecular biologist during his post-doctoral stint in Indian Institute of Science, Baylor College of Medicine USA and Karolinska Institute Sweden
Abstract:
The mechanism of efflux is a tour de force in bacterial armoury that has thwarted discovery of novel antibiotics. We reported the discovery of a novel series of compounds with potent antibacterial properties that is devoid of efflux liability. Starting from a phenotypic screen with a library diverse molecule on a panel of efflux deficient E. coli strains, we progressed a nitro-thiophene carboxamide derivative that effluxed selectively via the efflux pump AcrAB-TolC. Binding of these molecules to AcrB was evaluated by fluorescent thermal shift and Nile red dye-based assays. Prospective in silico modeling using computational methodologies viz. molecular docking and MD simulations were done. Iterative design and synthesis based on binding potency by in vitro assays and in silico prediction led to the generation of a series of molecules that were potent on wild type and multi-drug resistant clinical isolates of E. coli, Shigella spp. and Salmonella spp. Using a novel system biology reverse MOA (mechanism of action) protocol that measures the synergistic sensitivity on library of specially curated single gene knockout sub-library from the KIEO strains we identified these molecules to be pro-drugs that are activated inside E. coli by specific bacterial nitro reductases NfsA and NfsB. The conversion of these pro-drugs was characterized by in vitro enzymatic assay of purified NfsA and NfsB. Furthermore, these molecules were shown to be bactericidal and efficacious in a mouse thigh infection model.
Krishna Dronamraju
Foundation for Genetic Research, USA
Title: Ethics of Synthetic Biology
Time : 15:00-15:30
Biography:
Krishna Dronamraju is President of the Foundation for Genetic Research, Houston, and a Visiting Professor of the University of Paris. He was a student and close associate of J.B.S. Haldane, receiving his Ph.D. in human genetics from the Indian Statistical Institute, and later worked with Dr. Victor McKusick at the Johns Hopkins University School of Medicine. Dr. Dronamraju is the author of 19 books and over 200 papers in genetics and biotechnology. He was an Advisor to President Bill Clinton’s administration and was a member of the United States Presidential delegation to India in 2000. He served on the Recombinant DNA Advisory Committee of the U.S. National Institutes of Health, Washington, D.C.
Abstract:
Synthetic biology is concerned with the design and construction of new biological parts, devices and systems and the re-design of existing, natural biological systems for useful purposes. The convergence of scientific fields such as molecular biology, computer science and others has rendered it a natural progression, based on existing knowledge. The fact that humanity has reached a stage of development where it seems feasible to create life, or design it to a high degree of specificity, is a significant milestone in its history. It generates important ethical questions: Is synthetic biology something good, a natural use of humanity’s talents, or is it a step towards megalomania, playing God, a usurpation of his role? Is it really a natural progression, nature advancing to a state where its products can, in turn, improve nature itself; or does it challenge the dignity of nature by virtue of its unnaturalness? Is it an expression of the creative talent of humanity, thus enhancing human dignity and perhaps that of all life, or does it challenge the dignity of life itself? Regarding its potential consequences, it may, if it succeeds, lead humanity to a new level of development, a paradigm shifts comparable with the scientific or industrial revolutions, through a vast increase in scientific knowledge and subsequent technological developments in all relevant areas, including medicine, food production and fuel development. However, there is potential for serious accidents if synthetic organisms interact with naturally occurring ones, possibly affecting the future course of evolution. Synthetic biology also offers the possibility of creating ever more powerful weapons. It offers potential for both good and evil which appears to be greater than any other technology that has existed.
- Poster
Location: CRYSTAL
Session Introduction
Jae-Sun Choi
Kyung Hee University, South Korea
Title: Expression of brain-specific angiogenesis inhibitor-1 is decreased and regulated by the AMPK pathway in Parkinson’s disease
Time : 11:30-12:00
Biography:
Jae-Sun Choi has received her BS at Pusan National University and her PhD in Biomedical Science in 2011 at Kyung Hee University, South Korea. She was a Post-doctorate at Kyung Hee University, where she worked in projects about tumor angiogenesis between 2011 and 2016. Since 2016, she is a Research Fellow at Kyung Hee University. She has eight years of experience in basic research with expertise in both Parkinson’s disease and tumor angiogenesis. Her research interests focus on the effect of natural compound on Parkinson’s disease and the novel mechanism mediated by HIF-1alpha of tumor angiogenesis.
Abstract:
Background & Aims: Progressive dopaminergic neurodegeneration is responsible for the cardinal motor defects in Parkinson’s disease (PD). PD researchers still have limited understanding of the key molecular events that provoke the selective dopaminergic neurodefects in this disease. The present study examined whether brain-specific angiogenesis inhibitor (BAI1) participates in the pathway of dopaminergic neuronal loss in a 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) mouse model of PD.
Method: We constructed a PD model to evaluate the role of BAI1 on neuronal cell survival. Eight-week-old male C57BL/6 mice were randomly assigned to a saline group and MPTP (20mg/kg×4/day, 2 hours intervals). Moreover, mouse mesencephalic neurons and SH-SY5Y cells were treated with 10 μM and 300 μM (or 500 μM) of MPP+ for 24 hours, respectively.
Result: BAI1 immunostaining of brain sections from MPTP-treated mice showed that BAI1 was significantly decreased. Moreover, BAI1 level was specifically decreased in dopaminergic neurons in the substantia nigra of MPTP-toxicated mice. In primary mouse mesencephalic neurons and human neuroblastoma cell lines, 1-methyl-4-phenylpyridinium (MPP+) which is a toxic metabolite of MPTP also suppressed the expression of BAI1. We applied a bioinformatics tool to extend upstream regulatory pathway of BAI1 expression. AMP-activated protein kinase (AMPK) was predicted as a regulator and consequently AICAR, a specific activator of AMPK, reduced the BAI1 protein level. BAI1 overexpression decreased nuclear condensation induced by MPP+ treatment.
Conclusion: Down-regulated BAI1 by AMPKα induces neuronal cell death in PD model and BAI1 could play a crucial role as cell survival factor in neurodegenerative pathway of PD.