Day 1 :
Keynote Forum
Klaus Ammann
University of Bern, Switzerland
Keynote: Regulatory hurdles of gene editing, how to overcome them
Time : 10:00-10:30
Biography:
Klaus Ammann, Emeritus Prof. Hon. from the Bern University, Switzerland. Prof. Emeritus Hon. Bern University Switzerland. Thesis: vegetation and glacier history, summa cum laude in 1972 Bern University. Research topics: Biodiversity, Vegetation Ecology, Lichens and Mosses, Biomonitoring of Air Pollution, Plant Biotechnology: Biosafety, Gene Flow and Ecology of Transgenic Crops. Guest lecturing in Delft, Netherlands, Istanbul, Turkey, research in Jamaica, at Duke University and Missouri Botanical Garden. Member of the steering committee of www.prri.net. Scientific activities: maintaining 650 endnote reference bibliographies on plant biotechnology and biodiversity, over 320 publications under Klaus Ammann in journals, blogs, newspapers, books on biosafety research and ca. 210 slide presentations, many literature references with full text links. Editor, Co-Editor in journals from Elsevier, Springer and Landes. Member of scientific committees in Switzerland and Europe on biodiversity and biosafety. Fellow of the Royal Society of Biology, external member of the European Academy.
Abstract:
Gene editing is a new plant breeding method of precise elegance. It will be a unique chance to create new crops, adapted to climate change, be more productive and building new sustainable resistance against the steadily growing and adapting crop pests. It will also help to shift modern agriculture to a more ecological production, in short: it is the future of modern agriculture. Opposition against the new breeding methods is often based on fundamentalist arguments which are not really built on science. Anti-GM literature is often full of questionable statistics and fake arguments. This is a great pity, since stigmatization of the new gene editing is unfortunately built on the easy going psychology of fear of fake risks, often welcomed by a society in rich countries, where the population desperately longs for new risk fights in a clearly growing safety of personal life. It would be much better to develop a constructive attitude, which could manifest in organo-transgenic agricultural strategies, where the best sides of organic farming and modern breeding built on gene editing could be combined without the ideological and commercial hurdles.
Keynote Forum
Shoichiro Ozaki
The Institute of Physical and Chemical Research, Japan
Keynote: The effect of increase of NOx and CO2 on grain and fish production, protection of global warming and climate
Time : 10:30-11:00
Biography:
Shoichiro Ozaki has obtained his PhD in Nutrition and Food Science at Ehime University. He has extended his valuable service for many years and has been a recipient of many award and grants. Currently, he is working as an Emeritus Professor at Ehime University. His international experience includes various programs, contributions and participation in different countries for diverse fields of study. His research interests reflect his wide range of publications in various national and international journals. He is also the Editor-in-chief of Journal of Nutrition and Food Science.
Abstract:
In order, to study the reason why global warming is happening. Studies were conducted on amounts of CO2 emission, CO2 concentration NOx emission, grain production, fish production, population and CO2 fixed from 1900 to 2016. Since the industrial revolution, burning of fossil and production of CO2 and NOx increased greatly. Increased CO2 and NOx promoted the CO2 assimilation. Production of grain and fish increased. About 360 billion tone CO2 is produced by burning of fossil fuels. About 14.4 billion tone NOx is produced in 2015. Most of emitted CO2 is fixed by CO2 assimilation. But since developed country started NOx elimination and NP elimination at around 1975, half of produced NOx is eliminated. Therefore, emitted 360 billion tons CO2 is not fixed completely. Concentration of CO2 increased about 2 ppm. In 2016, 142 billion tons CO2 is remaining to give global warming. 142 billion tons of CO2 must be reduced. We must promote CO2 assimilation by complete use of emitting NOx and NP in waste water. Fossil fuel is burning out soon. We should not spend precious fossil fuel for the elimination of NOx and NP. We must increase CO2 assimilation as much as possible.
Keynote Forum
Nikolaus Stolterfoht
Helmholtz-Zentrum Berlin, Germany
Keynote: Biological applications of charged particle guiding through insulating nanocapillaries
Time : 16:00-16:20
Biography:
Nikolaus Stolterfoht has completed his PhD at Free University Berlin, Germany in 1970 and became a Group Leader at the Hahn-Meitner Institut Berlin where he habilitated. In the late 80’s he became full Professor at University of Caen, France. In 90’s he returned to Berlin at Helmholtz-Zentrum until becoming emeritus. He has 296 publications in reputed journals and a book with Springer. In 2017 he recived the Doctor honoris causa.
Abstract:
After the first observation that keV ions are guided through insulating nanocapillaries, the research topic has received increased attention during the past decade. The significant property of the capillary guiding is a self-organizing process, which controls the charge deposition inside the capillaries. With increasing deposition of the ions, the charge patch increases until the electrostatic field is sufficient to deflect the ions. At equilibrium, the ions are guided at relatively large distances from the surface so that they maintain their incident charge state. Milestones of the field are summarized in accordance with a recent review over the studies of capillary guiding. Experiments are treated emphasizing the guiding of highly charged ions in the keV energy range. Recent work with insulating nano and micro capillaries is reviewed. Apart from the experimental studies, theoretical concepts of the capillary guiding are presented. Specific emphasis is given to single conical capillaries allowing for the production of an ion beam of micron dimensions that can be applied in investigations of biological matter. Experiments are pointed out wherein the microbeam is directed on individual cells scanning their nucleus, environment and surface. Changing the ion energy, the insertion depth of the ion beam is varied so that the cell can be analyzed in three dimensions.
- Medical Biotechnology | Algal Biotechnology | Pharmaceutical Biotechnology | Environmental Biotechnology | Plant and Agriculture Biotechnology
Location: Sylt 5
Session Introduction
Annele Sainio
University of Turku, Finland
Title: Human metaplastic breast carcinoma and decorin
Time : 11:45-12:10
Biography:
Annele Sainio obtained her Master of Science Degree in Genetics in the Department of Biology at the University of Turku (Finland), and defended her thesis “The role of extracellular matrix macromolecules in cancer and diabetic macroangiopathy - with special reference to decorin and hyaluronan” in the spring 2016 respectively. Currently, she works as a Postdoc in the Department of Medical Biochemistry and Genetics at the same university. Her research is focused on specific extracellular matrix macromolecules, particularly proteoglycans and hyaluronan in various disease processes such as tumorigenesis. She has published more than 15 papers in reputed journals.
Abstract:
Decorin is a central extracellular matrix (ECM) proteoglycan known for its oncosuppressive activity. In various types of cancer, including breast cancer, decorin´s expression in the tumor microenvironment has been reported to be markedly decreased. Furthermore, its reduced expression has been shown to be associated with poorer outcome in invasive breast cancer. Metaplastic breast carcinoma (MBC) is a rare subtype of invasive breast cancer and has poor prognosis. In general, cancers are heterogeneous cellular masses comprised of different cell types and their ECM. However, in MBC little is known about the composition of ECM and its constituents. The aim of our study is to explore decorin immunoreactivity and the effect of adenoviral decorin cDNA (Ad-DCN) transduction in MBC. Methods included multiple immunohistochemical stainings to characterize the massive breast tumour. To explore the effect of Ad-DCN transduction on the tumor tissue, three-dimensional (3D) explant cultures derived from the tumour are transduced with the modified adenovirus. The immunohistochemistry results showed that MBC tumour was completely negative for decorin demonstrating that the malignant cells were not able to synthesize decorin. Furthermore, Ad-DCN transduction resulted in a markedly inhibited cell proliferation and altered cytological phenotype of MBC explants by decreasing the amount of atypical cells. The results of our study favor the development of novel adjuvant therapies based on decorin. Noteworthy is also the idea of “normalization of the tumour microenvironment” whereby decorin in its part could orchestrate cancer cells towards a less malignant phenotype.
Biography:
Annele Sainio obtained her Master of Science Degree in Genetics in the Department of Biology at the University of Turku (Finland), and defended her thesis “The role of extracellular matrix macromolecules in cancer and diabetic macroangiopathy - with special reference to decorin and hyaluronan” in the spring 2016 respectively. Currently, she works as a Postdoc in the Department of Medical Biochemistry and Genetics at the same university. Her research is focused on specific extracellular matrix macromolecules, particularly proteoglycans and hyaluronan in various disease processes such as tumorigenesis. She has published more than 15 papers in reputed journals.
Abstract:
Decorin is a central extracellular matrix (ECM) proteoglycan known for its oncosuppressive activity. In various types of cancer, including breast cancer, decorin´s expression in the tumor microenvironment has been reported to be markedly decreased. Furthermore, its reduced expression has been shown to be associated with poorer outcome in invasive breast cancer. Metaplastic breast carcinoma (MBC) is a rare subtype of invasive breast cancer and has poor prognosis. In general, cancers are heterogeneous cellular masses comprised of different cell types and their ECM. However, in MBC little is known about the composition of ECM and its constituents. The aim of our study is to explore decorin immunoreactivity and the effect of adenoviral decorin cDNA (Ad-DCN) transduction in MBC. Methods included multiple immunohistochemical stainings to characterize the massive breast tumour. To explore the effect of Ad-DCN transduction on the tumor tissue, three-dimensional (3D) explant cultures derived from the tumour are transduced with the modified adenovirus. The immunohistochemistry results showed that MBC tumour was completely negative for decorin demonstrating that the malignant cells were not able to synthesize decorin. Furthermore, Ad-DCN transduction resulted in a markedly inhibited cell proliferation and altered cytological phenotype of MBC explants by decreasing the amount of atypical cells. The results of our study favor the development of novel adjuvant therapies based on decorin. Noteworthy is also the idea of “normalization of the tumour microenvironment” whereby decorin in its part could orchestrate cancer cells towards a less malignant phenotype.
Marion Champeaud
Université de Poitiers, France
Title: How to produce high quality microalgae proteins from industrial dairy effluent
Biography:
Marion Champeaud graduated with a Bachelor of Biology five years ago, a Master’s degree in Agro-Industry three years ago from Bordeaux University in France and she is currently doing a PhD in partnership between a biotechnology company Fermentalg and Poitiers University in France (UMR CNRS 7267). Her research studies in engineering process and microalgae culture area resulted in 2 patents-pending and 2 publications in progress.
Abstract:
Utilization of whey or whey permeate is one of major concerns of the dairy industry nowadays, especially the acid whey, which mostly remains untreated prior to disposal. In 2010, 734 million tons of milk, and 160 - 180 million tons of whey per year were produced worldwide (Guimaraes et al., 2010). In 2014, milk production was higher than 800 million tons and is constantly increasing over the years. Despite the different strategies considered by the industrials to valorize whey: lactose crystallization, food applications in bakery products, dry mixes, snack, and milk replacer, alcoholic fermentation, or biogas conversion, only 50 % of this whey is processed (Mollea et al., 2013 ; Siso1996). A new industrial fermentation model was developed by Fermentalg to valorize these dairy by-products to obtain added-value bio-products at the same time. During this process, the microalgae Galdieria sulphuraria is able to consume 100% lactose, 98% of lactate and 79 % of the citrate present in whey permeate. The biomass production depends on by-product lactose concentration and range from 30 to more than 110 g/l of dry matter. In addition to direct bio-remediation of industrial dairy waste, the algae biomass produced show a real nutritional interest due to its high protein content (> 50 %) and is naturally rich in essential amino acid. Thanks to its own bioreactor enlightenment system Fermentalg is able to enhance phycocyanin production without modifying the overall protein content of the biomass.
Gisele Monteiro
University of São Paulo, Brazil
Title: Protein engineering applied to obtain biobetters of antitumor enzyme asparaginase
Biography:
Gisele Monteiro has completed her PhD at the University of São Paulo in Molecular Biology. Currently, she is an Associate Professor of Pharmaceutical Biotechnology in the Faculty of Pharmaceutical Sciences (FCF/USP) and the Vice-Coordinator of the Graduate Course in Biochemical-Pharmaceutical Technology. She has published more than 20 papers in reputed journals and has been serving as an Associate Editor of Brazilian Journal of Microbiology. She received 10 scientific awards, national and international. Her main scientific interest is the study of antitumor drugs and the engineering of proteins used as biopharmaceuticals, such as asparaginase.
Abstract:
Asparaginase (ASNase), an enzyme biotechnologically produced by bacteria, is one of the most important compounds in polychemotherapy to treat acute lymphoblastic leukemia (ALL) in children. There are only three options available as medicine: native enzyme from Erwinia chrysanthemi (ErA) or extracted from Escherichia coli (EcA) and formulated as native or PEGylated (PEG-EcA). However, these options yet present some problems in patients, such as to elicit hypersensitivity and allergenic reactions, neurotoxicity, and hyperammonemia. Aiming to avoid some of these problems, our research group has developed several different mutant proteoforms, expressed in bacteria and yeast, in periplasmic or secreted to extracellular space; with improvement in specific activity, kinetic parameters and stability; different oligomerization states, glycosylated or not, through engineering of genes from E. coli, E. chrysanthemi and S. cerevisiae. We obtained mutants from E. coli ASNase more resistant to human proteases and less immunogenic. In relation to E. chrysanthemi enzyme, our mutants present higher asparaginase activity than the native form, with improved kcat. In addition, we obtained strains of Pichia pastoris that express glycosylated ASNases from bacteria. Last but noteworthy, we obtained P. pastoris and E. coli strains that express active ASNases from S. cerevisiae, an eukaryotic promising options to replace bacterial formulations.
Klaus Pors
University of Bradford, UK
Title: Cytochrome P450 enzymes as target for drug development
Time : 14:00-14:25
Biography:
Klaus Pors is an Associate Professor of Chemical Biology at The Institute of Cancer Therapeutics, University of Bradford, UK. His research group is involved with discovery of novel biological and chemical tools to explore the importance of enzymes in different disease states. Particular focus is on exploiting abnormal cytochrome P450 (CYP), aldehyde dehydrogenase (ALDH) or aldo-keto reductase (AKR) expression in the tumour microenvironment as target for biomarker and drug discovery; he has published 35 papers on these topics. He is a RSC Chemical Biology and Bioorganic Group committee member and the European Editor of Journal of Cancer Metastasis and Treatment
Abstract:
The cytochrome P450 (CYP) enzymes belong to a superfamily of mixed function oxidases that are unique in their ability to oxidize xenobiotics, but under hypoxic conditions also can reduce certain chemical functionalities. There is now growing evidence that CYP1A1 and 2W1 are overexpressed in many human tumor types. The presence of certain CYPs may reflect a resistance mechanism by diminishing the pharmacological activity of anticancer drugs whilst specific CYPs can also modulate cell proliferation by the formation or conversion of endogenous signaling molecules. The potential for CYP-selective metabolism of xenobiotics coupled to their broad substrate specificity provides a unique opportunity to design drugs whose activity is dependent on a critical functional group that can be unmasked or restored by CYP metabolism selectively in tumor tissue. We have identified duocarmycin natural products which lend themselves to being great candidates for use in prodrug strategies. The electronic distribution and lipophilicity of the embedded chloromethylindoline trigger fragment is a key determinant in regioselective oxidation by specific CYP isoforms. We have synthesized and biologically evaluated several libraries of duocarmycins and have shown them to be bioactivated by CYP1A1 and 2W1 in cell-free and cell-based assays. At the meeting we will update on novel data from our drug discovery programme, which include single agent and combination treatment with standard of care drugs using colorectal cancer xenograft models.
Biography:
Abstract:
Global interest in biofuel production has increased to achieve sustainable energy production and reduce climatic change specially developing countries. The present study is pioneer resource assessment study in the Sudan and the Red Sea region. Its objectives are fourfold: to verify the existence in Sudanese’s Red Sea coast zone of microalgae species which are globally reported for their high biomass and biofuel production, to determine the potentially suitable sites for commercial production of microalgae, to estimate the biomass and befuel productivity and the amount of sequestered carbon. The study made use of Red Sea algal review to verify the existence of the required species. The Multi criteria analysis (MCA), as a GIS tool, was used for best site selection is used for industrial scale microalgae cultivation and biofuel production. Climate parameters, land use, landcover, slope and power plants as nutrients sources for CO2 were considered. Theoretical calculations used for potential of biomass, lipids productivity and estimate of carbon fixation for study area based on sunlight and other climatic conditions of site selection assuming cultivation of Chlorella vulgaris in open pond system. The results of suitability analysis determined the bare land out Portsudan city as suitable site for production with a total area estimated to be 19385 hectares. carbon fixation for Red Sea was (279.8 T /ha/ year), (72427.4L/ha/year) and (23.3 gco2/m/d), respectively, this figure more suitable in compression with other in tropical sites such as India, Ethiopia and Australia. However, According to economic and environmental benefits, the study will provide a base to support decision-makers to establish generic strategy to enhance renewable energy sector to meet the SDGS.
Sara Mohseni
Niroo Research Institute, Iran
Title: Detection and evaluation of industrial gas pollutants using optical sensor based on surface plasmon resonance technique
Biography:
Sara Mohseni has completed her PhD in Nanotechnology at Tarbiat Modares University. She is a Researcher at Niroo Research Institute. She has published about 40 papers in international journals and conferences and one book entitled “Laboratory Biochemistry: Modern Theory and Techniques”. She is now working as a Project Manager in Niroo Research Institute related to Biotechnology and Nanotechnology.
Abstract:
Hazardous materials from industries such as heavy metals, pollutants and pathogens to the environment pollute the environment and endanger human health. To identify these pollutants, analytical equipment including UV-visible spectroscopy, chromatography, mass spectrometry and atomic absorption spectrometry can be used. Different contaminants have challenged the usual analytical methods. Therefore, the use of a powerful and reliable tool for detecting pollutants is very important. Industrial pollutants can be identified with high precision using nanotechnology in optical sensors especially in power plants. Surface plasmon resonance (SPR) as an optical sensor is a powerful technique that detects any changes in dielectric-metal interference with high sensitivity on a chip with a nanostructured surface. Principal advantages of SPR compared to other techniques are: direct real time measurement of the interaction among label-free molecules, determination of the association and dissociation rates of the binding process and small amount of sample used in assay. Recently, using semiconductor metal oxides (SMO) as gas sensors has been widely considered in optical techniques such as SPR. Metallic oxides exhibit the surface plasmon emission properties at the interface between the dielectric and the SMO surface. Some metal oxides such as: ZnO, SnO2 and In2O3 are used to identify pollutant gases, including CO, CO2, H2S, NO2 and SO2. Metal oxide thin films have been deposited on Au coated glass prisms. The SPR reflectance curves were obtained under transient mode by varying the concentration of the target gas.
Raina Ijaz,
University of Poonch Rawalakot, Pakistan
Title: Overexpression of a tomato annexin gene AnnSp2, enhances abiotic stress tolerance in transgenic tomato through ABA synthesis and modulation of ROS production
Biography:
Raina Ijaz is working as an Assistant Professor at University of Poonch Faculty of Agriculture, Rawalakot (Azad Kashmir), and focusing on the fate of biotechnology in the horticultural plant vegetable science. She moved to Wuhan, China by the Scholarship Council (CSC) and finished her PhD under the guidance of Prof. Dr. Ye zhibiao at Huazhong Agricultural University in 2017. She has published five research publications in various well reputed scientific impact factor journals. She has participated in many national and international conferences, seminars and presented her research achievements. She is also serving as reviewer/referee for many national and internationals journals.
Abstract:
Drought and high salinity are two major abiotic stresses that affect the agricultural crops worldwide. Annexins belongs to a multigene protein family that play an essential role in plant stress responses and various cellular processes. Here, AnnSp2 gene was cloned from wild tomato (Solanum pennelli) and functionally characterized in cultivated tomato. AnnSp2 was found to be induced after exposure to drought, salt, H2O2 and ABA. Tomato plants overexpressing AnnSp2 remarkably increased plant tolerance to drought and salt stress, as determined through physiological analysis of the germination rate, root growth, survival rate, leaf water loss and Chl content. AnnSp2 transgenic plants were observed to be less sensitive to ABA during seed germination and seedling stages. However, under drought stress the ABA content significantly increased in the AnnSp2 over expressing plants, reduced water loss, attributed to the enhancement of stress tolerance. Furthermore, we found that AnnSl2 reduced sensitivity of plants to drought by influencing ABA induced stomatal movement and expression of ABA inducible genes, including AREB, DREB, NCED, ERD were clearly up regulated under drought and salt stress conditions. Consistent with the accumulation of reactive oxygen species (ROS), lower lipid peroxidation level, increased peroxidase activities including APX, CAT and SOD all of which contributed to increased tolerance to oxidative stress compared with wild-type plants. These results therefore indicate that AnnSp2 play an important role in the abiotic stress response and that overexpression of AnnSp2 in transgenic tomato improves salt and drought tolerance through ABA signalling and the regulation of ROS production in plants.
Klaus Pors,
University of Bradford, UK
Title: Aldehyde dehydrogenases as target for biomarker and drug discovery
Biography:
Klaus Pors is an Associate Professor of Chemical Biology at The Institute of Cancer Therapeutics, University of Bradford, UK. His research group is involved with discovery of novel biological and chemical tools to explore the importance of enzymes in different disease states. Particular focus is on exploiting abnormal cytochrome P450 (CYP), aldehyde dehydrogenase (ALDH) or aldo-keto reductase (AKR) expression in the tumour microenvironment as target for biomarker and drug discovery; he has published 35 papers on these topics. He is a RSC Chemical Biology and Bioorganic Group committee member and the European Editor of Journal of Cancer Metastasis and Treatment.
Abstract:
The human aldehyde dehydrogenases (ALDHs) play a major role in detoxifying highly reactive aldehydes into carboxylic acids. Deregulation of ALDHs have implications in a number of cancers. They play an important role as a cancer stem cell (CSC) marker due to high activity found in CSCs while high expression is also known to lead to resistance to chemotherapeutic drugs. Although the exact role of ALDH is not fully understood, emerging information indicates several isoforms from the ALDH1 family, ALDH3A1 and ALDH7A1 play key roles in many cancer types. To probe the role of ALDH functional activity, at this meeting we will present new data on small molecules that inhibits ALDH functional activity using cell free and cell-based assays; diethylbenzaldehyde (DEAB) was used as a control for inhibition while Aldefluor assay was used as an assay to demonstrate functional activity. Furthermore, our investigations in prostate cancer revealed that several ALDH-affinic probe compounds were able to reduce cell viability in both drug-resistant PC3 prostate cancer cells and patient-derived samples while synergistic effect was observed in combination treatment with docetaxel. Our early drug discovery approach will be presented at the meeting and include drug design to target ALDH7A1, an enzyme that is linked with oxidative stress, lysine metabolism and several diseases including cancer.
- Pharmaceutical Biotechnology | Nano Biotechnology | Medical Biotechnology | Genetics/Genetic Engineering
Location: Sylt 5
Session Introduction
Oara Neumann,
Rice University, USA
Title: Green production of bioethanol using solar steam generated with nanoparticles
Biography:
Oara Neumann is the Peter M and Ruth L Nicholas Research Scientist at Rice University (a fully funded, endowed research scientist position at the university). She has completed her PhD and Postdoctoral study in Applied Physics at Rice University, MSc in Chemical Physics at Weizmann Institute of Science, Israel and another MSc in Analytical Chemistry from Bucharest University, Romania. She is the Pioneer of nanoparticle-based solar thermal applications. She holds several patents and has published more than 25 refereed articles and has an h-index of 16.
Abstract:
Conventional bioethanol for transportation fuel typically consumes agricultural feedstocks also suitable for human consumption and requires large amounts of energy for conversion of feedstock to fuel. Alternative feedstocks, optimally those not also in demand for human consumption, and off-grid energy sources for processing, would both contribute to making bioethanol far more sustainable than current practices. Cellulosic bioethanol production involves three steps: the extraction of sugars from cellulosic feedstock, the fermentation of sugars to produce ethanol, and the purification of ethanol through distillation. Traditional production methods for extraction and distillation are energy intensive and therefore costly, limiting the advancement of this approach. Here we report an initial demonstration of the conversion of cellulosic feedstock into ethanol by completely off-grid solar processing steps. Our approach is based on nanoparticle-enabled solar steam generation, where high-efficiency steam can be produced by illuminating light-absorbing nanoparticles dispersed in H2O with sunlight. We used solar-generated steam to successfully hydrolyze feedstock into sugars, then used solar steam distillation to purify ethanol in the final processing step. Coastal hay, a grass grown for livestock feed across the southern U. S., and sugar cane as a control, are successfully converted to ethanol in this proof-of-concept study. This entirely off-grid solar production method has the potential to realize the long-dreamed-of goal of sustainable cellulosic bioethanol production.
Biography:
Jiali Li has completed her PhD in Physics at the City University of New York in 1999 and Postdoctoral studies from Depertment of Physics, Harvard University. She is a Physics Professor at the University of Arkansas since 2002. She has been one of the pioneers in developing solid-state nanopore technology and its applications in single DNA and protein analysis. She has published more than 30 papers in reputed journals. In recent years, she has been working on protein aggregation, detection and characterization with solid-state nanopore device combined with other nanotechnologies.
Abstract:
In this work, we analyze the process of protein aggregation with a nanopore device combined with AFM and DLS. Our model proteins used are ß-lactoglobulin variant A (bLGa) and a neuronal Tau protein. The main component of a nanopore device is a nanometer size pore, 5 to 20 nm in diameter, fabricated in a free-standing silicon nitride membrane supported by a silicon substrate which separates two PDMA chambers containing salt solution. A stable ionic current is established by applying a biased voltage on a pair of silver chloride (AgCl) electrodes across the nanopore membrane. When a charged protein molecule or a protein aggregate passes through a nanopore, a protein aggregate which has larger volume than a single protein molecule would block larger amount of current or generate a greater current drop amplitude, therefore a nanopore device can be used to characterize protein aggregation in salt solution at single molecule level. The volume of translocating protein molecules or aggregates are estimated using a calibrated nanopore by a standard that has known geometry such as a dsDNA molecule. We show that by using a reference dsDNA molecule, solid state nanopore method is capable of measuring protein aggregation number and the aggregation number distribution in the conditions that is close to their native aqueous solution environment. The nanopore experiments were performed under applied voltages from 60-210 mV at different pH, temperature and salt concentration. We present data of bLGa and Tau self-association and aggregation measured by nanopore method, AFM and DLS.
Gisele Rodrigues Atayde,
University of Sao Paulo, Brazil
Title: The role of the leader of the academic research group in promoting academic startups of biotechnology
Biography:
Gisele Rodrigues Atayde is currently pursuing Master’s Degree student with the Integrated Engineering Group (EESC - USP) and is a Specialist in Industrial Engineering at the University of São Paulo (Brazil) respectively. She graduated in Business Administration from Faculdade Gennari e Peartree University. Her research focuses on academic entrepreneurship, especially the application of technological planning on the academic research groups; including agile project management techniques and technology management tools. Her research interests includes: creation of academic spin-offs, technological entrepreneurship, technology project management and triple helix.
Abstract:
Fostering the creation of academic startups have become a key concept of institutional and governmental directives and strategies of several developed countries. Some incentives are generated within universities and innovation centers which takes into account the necessity to train researchers in management practices, patenting and marketing studies to maximize the possibility of new business originated from research. Regarding the biotechnology field with focus on developing new products, research business opportunities targeting usually often arises after several years of study and even after publications and patenting. In addition to this, there are high research costs involved as well as numerous risks and failures inherent to development during the initial stages of research. Given this context, the necesseity to include facilitating agents that understand the field of ​​study as well as the current market trends and needs becomes important in order to assist researchers during the product development phase to ensure market adherence. One of the hypotheses of this study is that the leader of an academic research group can become a facilitating agent to promote and foster the development of new business. The general objective is to understand the processes involved, beggining with the criteria used to select potential projects until the culmination of a patent generation originated from a research group in the biotechnology field which is focused on production of medical drugs inside a Brazilian university. It is estimated that within the research process and exploration, there are some market validations that can be made during the development phase and can support the creation of new business.
- Poster Presentations 14:00-15:00 @ Sylt Foyer