Biography:

Wael Rabeh received his PhD in Biochemistry in the lab of Prof Paul F. Cook where he characterized the last enzymatic reaction of the cysteine biosynthetic pathway in Salmonella typhimurium. In 2005, Dr. Rabeh joined the Structural Genomic Consortium (SGC) at the University of Toronto as a post-doctoral fellow, where he characterized the 3D structure of human proteins with medical relevance using X-ray crystallography. In 2007, Dr. Rabeh joined the lab of Dr. Gergely Lukacs at McGill University for the characterization of a membrane channel that is the main cause of Cystic Fibrosis. Dr. Rabeh’s research is devoted for the characterization of proteins’ structure and mechanism to understand their biological function. Major area of his research focus is devoted for the characterization of disease-causing mechanism of proteins with medical relevance to assist in the discovery and design of new therapeutics using proteins’ structural information and computer simulation.

Abstract:

Glucose metabolism is 200 times higher in cancer in comparison to normal tissue as a strategy to support tumor growth and progression, historically known as the ‘Warburg effect’. Hexokinase is the first enzyme of the glycolytic pathway that catalyzes the phosphorylation of glucose for its activation to glucose-6-phosphate and uses ATP as high-energy source of phosphates. Four isozymes are present in human with Hexokinase 2 (HK2) is most active and specifically expressed in verity of different cancers. However, HK2 binding to the outer mitochondrial membrane not only gives it prime access to ATP generated by the mitochondrial but inhibit apoptosis. Here, we aim to biochemically and structurally characterize interactions of HK2 with the mitochondria and the N-terminal role in catalysis and stability of the full-length enzyme. Here, we solved the crystal structure of human HK2 in complex with glucose and glucose-6-phosphate (PDB code: 2NZT), where it is a homodimer with catalytically active N- and C-terminal domains linked by a seven-turn α-helix. Different from the inactive N-terminal domains of isozymes 1 and 3, the N- domain of HK2 not only capable to catalyze a reaction but it is responsible for thermodynamic stabilizes of full-length enzyme. Deletion of first α-helix of the N-domain that binds to the mitochondria altered the stability and catalytic activity of the full-length HK2. In addition, we found the linker helix between the N- and C-terminal domains to play an important role in controlling the catalytic activity of the N-terminal domain. HK2 is a major step in the regulation of glucose metabolism in cancer making it an ideal target for the development of new anticancer therapeutics. Characterizing the structural and molecular mechanisms of human HK2 and its role in cancer metabolism will accelerate the design and development of new cancer therapeutics that are safe and cancer specific.

References:

1. Rabeh, W.M.; Bossard, F.; Xu, H.; Okiyoneda, T.; Bagdany, M.; Liu, Y.; Mulvihill, C.M.; Du, K.; Di Bernardo, S.; Konermann, L.; Roldan, A.; Lukacs, G.L. Correction of both NBD1 energetics and domain interface is required to restore ∆F508 CFTR folding and function. (2012) Cell; 148(1-2): 150-63.
2. Wyatt, E.; Wu, R.; Rabeh, W.; Park, H.W.; Ghanefar, M. and Ardehali, H. Regulation and Cytoprotective Role of Hexokinase III. (2010) PLoS One. 5(11): e13823
3. Okiyoneda, T.; Barrière, H.; Bagdány, M.; Rabeh, W.M.; Du, K.; Höhfeld, J.; Young, J.C. and Lukacs, G.L. Peripheral Protein Quality Control Removes Unfolded CFTR from the Plasma Membrane. (2010) Science. 329: 805-10.
4. Rabeh, W.M.*, Tempel, W.*, Bogan, K.L., Belenky, P., Wojcik, M., Seidle, H.F., Nedyalkova, L., Yang, T., Sauve,A.A., Park, H.W. and Brenner,C. Nicotinamide Riboside Kinase Structures Reveal New Pathways to NAD+. (2007) PLoS Biol. 5(10): e263 *Co-first Authors.
5. Rabeh, W.M.*, Chattopadhyay, A.*, Meier, M., Ivaninskii, S., Burkhard , P., Speroni, F.*, Campanini, B., Bettati,  S., Mozzarelli, A., Li, L. and Cook, P.F. Structure, Mechanism, and Conformational Dynamics of O-Acetylserine Sulfhydrylase from Salmonella typhimurium: Comparison of A and B Isozymes. (2007) Biochemistry 46, 8315-30 *Co-first Authors.

Biography:

Anna Antecka has received her PhD in Environmental Engineering in 2008 from the Lodz University of Technology in Poland, within the Faculty of Process and Environmental Engineering, where she is currently an Assistant Professor in the Department of Bioprocess Engineering. From 2004-2005, she made a one-year scientific stay at the International Institute Zittau, Germany, in the Department of Environmental Biotechnology. In 2002, she studied at the University of Dortmund, Germany. Her main research interests are in microbial ecology and biotechnology of fungal enzymes especially laccase, including its production, purification and characterization as well as enzyme applications for industrial and environmental purposes. Currently, she is focused on projects in the area of integrated continuous up- and downstream processes for the biosynthesis and purification of fungal laccases.a

Abstract:

Statement of the Problem: Laccase (EC 1.10.3.2, polyphenol oxidases) belongs to the group of oxidoreductases which is characterized by its specific catalytic properties and the ability to oxidize various organic compounds. Therefore the enzyme is very attractive for a wide range of industrial and environmental purposes. However, due to relatively low effectiveness and the possibility of gradual degradation of bioproducts in the reactor or during the separation and purification stages, there is a need for new approaches and research in this field. Therefore, the purpose of this research was to study and integrate the stages of up- and downstream processing (biosynthesis and purification) of laccase from Cerrena unicolor in order to obtain a highly active enzymatic product.

Methodology: The biosynthesis was performed in a 14-L bioreactor equipped with a set of sensors for process control. Modifications to the medium- addition of microparticles, MPEC, as well as various types of cultivation/growth strategies were examined. The supernatant was concentrated and purified by an aqueous two-phase system (ATPS) consisting of polyethylene glycol and phosphate buffer solutions, and through foam fractionation (FF) at different pH values and with the addition of different detergents. Ultrafiltration and chromatography methods were also investigated. Molecular mass and isoelectric point was determined with the use of electrophoresis.

Findings: Laccase activity increased 3.5-fold after addition of microparticles to the culture media. The fed-batch mode resulted in high laccase activity (up to 4 U/mL) which remains stable during cultivation. The optimal conditions for laccase purification by FF and ATPS were determined with activity partitioning coefficients between foamate and retentate of almost 200 and 2000, respectively, and with yields reaching 50% and 90%, respectively.

Conclusions: Application of MPEC and fed-batch mode proved successful in increasing enzyme production. Both ATPS and FF are successfully applicable for laccase purification.

References:

1. Antecka A, Blatkiewicz M, Bizukojc M, Ledakowicz S (2016) Morphology engineering of basidiomycetes for improved laccase biosynthesis. Biotechnol. Lett. 38:667-672.

2. Antecka A, Bizukojć M, Ledakowicz S (2009) The kinetic model of laccase biosynthesis by Cerrena unicolor. Chemical, Process Engineering 30:403-416.

3. Michniewicz A, Ledakowicz S, Ullrich R, Hofrichter M (2008) Kinetics of the enzymatic decolorization of textile dyes by laccase from Cerrena unicolor. Dyes and Pigments 77:295-302.

4. Sójka-Ledakowicz J, Lichawska-Olczyk J, Ledakowicz S, Michniewicz A (2007) Bio-scouring of linen fabrics with laccase complex from Cerrena unicolor. Fibres and Textiles EE 63:86-89.

5. Michniewicz A, Ullrich R, Ledakowicz S, Hofrichter M (2006) The white-rot fungus Cerrena unicolor strain 137 produces two laccase isoforms with different physico-chemical and catalytic properties. Applied Microbiology and Biotechnology 69:682-688.

Biography:

Michal Blatkiewicz has done his Master of Engineering Technology in the field of Chemical and Process Engineering from Cracow University. Currently, he is a PhD student at Lodz University of Technology, Faculty of Process and Environmental Engineering, where he is also employed as a Scientific Project Contractor. During his PhD studies, he has done four internships at Dortmund University of Technology. His scientific scope includes primarily fungal cultures and enzymes, and also downstream processing of biological molecules. Currently, he is a part of a research team working on a project concerning continuous processes of biosynthesis, concentration, and purification of fungal laccases, in which he focuses mostly on novel downstream processing methods, such as aqueous two-phase extraction and foam fractionation.

Abstract:

Statement of the Problem: Downstream processing of biological molecules is a very time- and energy-consuming task. One of the major trends in contemporary biotechnology revolves around cost-effective and environment-friendly methods of concentration and purification of bioproducts. Various novel downstream processing tactics are currently being investigated as alternatives to established methods such as ultrafiltration and chromatography. The purpose of this research was to examine the feasibility of polyethylene glycol-phosphate aqueous two phase systems (ATPS) and cetrimonium bromide-induced foam fractionation (FF) as methods for Cerrena unicolor and Pleurotus sapidus laccase separation from culture supernatants. Both processes were investigated in batch and continuous forms.

Methodology: The biosynthesis was performed in a 14-L bioreactor equipped with a set of sensors for process control. The filtered supernatants were concentrated with the use of aqueous two-phase systems or foam fractionation. Batch ATPS experiments were conducted in specially designed extraction flasks, and for continuous ATPS experiments, a mixer-settler unit (MSU) was used. FF experiments were conducted in a special glass column equipped with air disperser and peristaltic pumps for liquid intake and outtake. Laccase activity was determined by 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulphonic acid) assay.

Findings: C. unicolor laccase showed greater affinity towards salt-rich phase with over 90% yields and partitioning coefficients up to 2200. P. sapidus laccase showed strong affinity towards polymer rich-phase also with over 90% yields and full partitioning. MSU experiments showed consistency with batch experiments within non-extreme phase ratio range. Foam fractionation effectiveness depended strongly on pH and surfactant concentration, leading over 100 partitioning coefficient towards the foamate. Low gas and liquid flow rates led to more effective concentration.

Conclusions: Aqueous two-phase extraction and foam fractionation are both effective alternatives to established downstream processing methods for laccase concentration.

Biography:

http://enzymology.conferenceseries.com/Jennifer A Littlechild is Professor of Biological Chemistry and has established the Henry Wellcome Centre for Biocatalysis at Exeter University in 2003. Her research studies involve the structural and mechanistic characterisation of a range of enzymes from thermophilic bacteria and Archaea that have industrial applications. She has a particular interest in thermophilic carbonic anhydrase enzymes and has carried out a project with Statoil from 2011-2013. She has published over 200 publications in refereed high impact journals and presented her research work internationally. She is the UK Representative and Vice-chair of the European Section of Applied Biocatalysis and Member of EU advisory committees for industrial biotechnology.

Abstract:

There is an increasing demand for new enzymes with enhanced performance and/or novel functionalities that provide savings in time, money and energy for industrial processes in the areas of high value chemical production and other "white" biotechnology applications. There is a limited understanding of the metabolic capacity of life and only a small proportion of nature’s catalysts have been utilised for industrial biotechnology. There are new metabolic pathways and enzyme activities to be discovered and many of which could be identified within the large proportion of micro-organisms that cannot be cultured and within their associated viruses. The number of enzymes explored to date remains within the range of 1-2% of known microbial diversity. Enzymes used for commercial biotransformation reactions are required to be stable under the industrial conditions employed. The use of naturally thermostable enzymes isolated from hot environments can be a source of enzymes that are more stable to high temperatures, extremes of pH and exposure to organic solvents. By using both genomic and metagenomic approach within the projects, HOTZYME and THERMOGENE, we have identified hydrolase and transferase enzymes of industrial interest isolated from high temperature environments around the world. A selection of these novel enzymes including esterases, cellulases, epoxide hydrolases, transketolases and transaminases have been characterized both biochemically and structurally. In the case of the epoxide hydrolases, two new enzymes with interesting substrate specificity and stereo-selectivity have been discovered from thermophilic metagenomes. Applications of these new epoxide hydrolases have been demonstrated at industrial scale for the production of new chiral chemical building blocks. A new thermophilic cellulase enzyme with activity at pH 5.0 and active under high salt conditions has been isolated which has potential applications for breakdown of biomass.

References:

1. Sayer C, Finnigan W, Isupov M, Levisson M, Kengen S, Van der Oost J, Harmer N, Littlechild J A (2016) Structural and biochemical characterization of Archaeoglobus fulgidus esterase reveals a bound CoA molecule in the vicinity of the active site. Scientific Reports 6:25542.

2. Zarafeta D, Kissas D, Sayer C, Gudbergsdottir S R, Ladoukakis E, Isupov M N, Chatziioannou A, Peng X, Littlechild J A, Skretas, G, Kolisis F N (2016) Discovery and characterization of a thermostable and highly halotolerant GH5 Cellulose from an Icelandic Hot Spring Isolate. PLoS ONE 11(1):07.

3. Sayer C, Szabo Z, Isupov M N, Ingham C, Littlechild J A (2015). The structure of a novel thermophilic esterase from the Planctomycetes species, Thermogutta terrifontis reveals an open active site due to a minimal cap domain. Front. Microbiol. 11: 1294.

4. Ferrandi C, Sayer C, Isupov M, Annovazzi, C, Marchesi C, Lacobone G, Peng X, Bonch Osmolovskaya E, Wohlgemuth R, Littlechild J, Monti D (2015) Discovery and characterization of thermophilic limonene-1,2-epoxide hydrolases from hot spring metagenomics libraries. FEBS J. 282:2879-2894.

5. Sayer C, Isupov M, Bonch-Osmolovskaya E, Littlechild J A ( 2015) Structural studies of a thermophilic esterase from a new Planctomycetes species, Thermogutta terrifontis. FEBS J. 282: 2846-2857

Biography:

Preeti Chanalia has acquainted herself with biochemical, microbiological and microscopic techniques. She is well versed with protein isolation and purification. She has purified and characterized PIP from L. plantarum and extended her studies to explore applications of PIP (alone and in combination with other enzymes) in meat tenderization and collagen degradation. Her work determined that purified PIP as well membrane bound PIP was very effective in collgen degradation and meat tenderization. Her work indicates the possibility of formation of monostrains into multi-strain probiotics with improved efficiency. She had made a significant contribution to the project and worked as self-motivated researcher to learn and do new things. This study is very useful for food and pharmaceutical industry.

Abstract:

Proline iminopeptidase (PIPs) specifically cleaves N-terminal proline from peptides and helps in overcoming restriction of many aminopeptidases to cleave proline rich peptides/proteins. PIPs are used in food processing, meat tenderization as well as in treating collagen rich wastewater to generate bioactive collagen hydrolysates important for food and pharmaceutical industry. Microbial enzymes account for about 60% of total worldwide sale of enzymes. There is increasing demand of industrial enzymes with novel characteristics for different applications. Among microorganisms lactic acid bacteria have gained great attention because of their GRAS status (generally regarded as safe) and probiotic attributes. Investigation and development of highly potent probiotic consortium (comparable to commercially available products/Probiotics) suitable for functioning in adverse conditions is of great value as therapeutics as well as in various industries. The possibility of formation of mono- strains into multi-strain probiotics with potential of improved efficacy is the goal of this kind of studies. Methodology: Purification using successive column chromatographies, characterization, in silico studies of PIP from probiotic L. plantarum and its use in collagen degradation and meat tenderization by simple and effective treatment with enzyme/s was done. Findings: Membrane bound PIP from L. Plantarum was extracted, purified and characterized further. The effectiveness of PIP in purified form, membrane bound form and in combination with other enzymes to degrade collagen and meat tenderization marks its industrial importance. Conclusion & significance: Purified PIP as well as whole cells effectively hydrolyzed collagen. Whole cells, PIP alone and with other enzymes tenderized chicken meat efficiently. It is very significant for food, pharmaceutical industry and waste management. It also opens avenue for the formation of multi strain probiotics.

References:

1. Dimpi Gandhi, Preeti Chanalia, Pooja Attri, Suman Dhanda. Dipeptidyl peptidase-II from probiotic Pediococcus acidilactici: Purification and functional characterization. International Journal of Biological Macromolecules. 2016, 93,919:932.
2. Preeti Chanalia, Dimpi Gandhi, Raman Kumar, Pooja Attri, Suman Dhanda. Lactic acid production vis-à-vis biowaste management using lactic acid bacteria. World Applied Science Journal. 2016.(Accepted)    
3. Pooja Attri, Drukshakshi Jodha, Dimpi Gandhi, Preeti Chanalia, Suman Dhanda. In vitro evaluation of Pediococcus acidilactici NCDC 252 for its probiotic attributes. International Journal of Dairy Technology. February 2015.  DOI: 10.1111/1471-0307.12194.
4. Prabodh Chander Sharma, Ankit Jain, Mohammad Shahar Yar, Rakesh Pahwa, Jasbir Singh, Preeti Chanalia. Novel fluoroquinolone derivatives bearing N-thiomide linkage with 6-substituted-2-aminobenzothiazoles: synthesis and antibacterial evaluation. Arabian Journal of Chemistry.  November 2012.  DOI: 10.1016/j.arabjc.2012.11.002.
5.  Preeti Chanalia, Dimpi Gandhi, Drukshakshi Jodha, Jasbir Singh. Applications of microbial proteases in pharmaceutical industry: an overview. Reviews in medical microbiology. 2011, 22: 96-101.

Biography:

Dino Hasanagic received his degree of M.Sc. from the Faculty of Science in Sarajevo, and he is currently attending plant biochemistry programme at Faculty of Science in Novi Sad, Serbia. His field of interest is antioxidative metabolism of plant cell - effects of abiotic stress (drought, metals, senescence, ROS signaling, redox state). Dr Biljana Kukavica is expert in plant enzyme antioxidative metabolism. Her interest is focused on enzyme and non-enzyme antioxidative defense in plant cell under oxidative stress. Dr Danijela Kojic has a big experience in the field of biochemistry and molecular biology and her researches are addressing the antioxidative enzyme role in adaptation to stress conditions. The expertise and passion of the authors is recognized among their peers, and they constantly expanding their knowledge in researches regarding enzymology.

Abstract:

The drought is a worldwide problem and insufficient supply of plants with water is one of the most important causes of low agricultural yields and thus representing one of the most common problems faced by the producers. There has been an increased interest in science in recent years in the use of natural aluminosilicates in agriculture where the most famous is zeolite, a mineral whose absorption properties and balanced release of water and nutritive substances ever more successfully solve the issue of water supplying and mineral nutrition and have beneficial impact on overall plant growth. The aim of this study was to investigate the role of zeolite in prevention of oxidative stress in tomato plants exposed to drought. Changes in the activity of peroxidase (POD, EC 1.11.1.7), catalase (CAT, EC 1.11.1.6), ascorbate peroxidase (APX, EC 1.11.1.11), superoxide dismutase (SOD, EC 1.15.1.1) as well as reduced and total ascorbate content in plant leaves exposed to drought for 28 days were investigated. Activities of antioxidant enzymes in the leaves of plants exposed to drought were at the same level with and without the addition of zeolite. The obtained results indicate that zeolite did not prevent oxidative damages caused by drought. Native electrophoresis resolved the presence of two peroxidase isoforms specific for drought and their activities were higher in tomato leaves whit zeolite. The drought induced an increase in activities of superoxide dismutase, ascorbate peroxidase and ascorbate concentration and this antioxidative strategy was more expressed in zeolite treated plants. Unexpected results related to the role of zeolite open the possibility to different perspectives in discussion on the zeolite role in drought prevention.

References:

1. Alfi S, Azizi, F (2015) Effect of Drought Stress and Using Zeolite on Some Quantitative and Qualitative Traits of Three Maize Varieties. Research Journal of Recent Sciences 4: 1-7.
2. Chavan, ML, Janagoudar, BS, Dharmatti, PR, Koti, RV (2010) Effect of drought on growth attributes of tomato (Lycopersicon esculentum Mill.) genotypes. Indian Journal of Plant Physiology 15: 11-18.
3. Kojić, D, Pajević, S, Jovanović-Galović, A, Purać, J, Pamer, E, Škondrić, S, Milovac, S, Popović, Ž, Grubor-Lajšić, G (2012) Efficacy of natural aluminosilicates in moderating drought effects on the morphological and physiological parameters of maize plants (Zea mays L.). Journal of Soil Science and Plant Nutrition 12: 113-123.
4. Pirzad, A, Mohammadzade, S (2014) The effects of drought stress and zeolites on the protein and mineral nutrients of Lathyrus sativus. International Journal of Biosciences 4: 241-248.
5. Gholizadeh A, Amin, MSM, Anuar, AR, Saberioon, MM. (2010) Water stress and natural zeolite impacts on physiomorphological characteristics of Moldavian Balm (Dracocephalum moldavica L.). Australian Journal of Basic and Applied Sciences 4: 5184- 5190

Biography:

Dr. Muhammad Nauman Aftab is an associate professor at MN Institute of Industrial Biotechnology, Government College University, Lahore, Pakistan. He has worked in the area of cloning and gene expression of Bacillus licheniformis and Geobacillus stearothermophilus that code for industrially important enzymes. Some of the cloned genes by his team are β-glucanase, serine protease, β-glucosidase, xylanase, etc. Apart from cloning genes, he has also worked on the production of various enzymes like tannase, lipase and polypeptide antibiotic (bacitracin) from wild bacterial strains like Bacillus licheniformis, Bacillus subtilis and Geobacillus stearothermophilus.

Abstract:

More than 90% energy requirements depend on fossil fuels that include crude oil, natural gas, coal, etc. The burning of these energy sources emit greenhouse gases that are harmful for our environment and are major cause of many diseases like lung cancer, asthma etc. The requirement of fossil fuel is increasing day by day due to rapid industrialization and increased number of vehicles. In the middle of this century, world’s fossil fuels reserves will be significantly reduced. In this scenario, the alternative fuel, bioethanol, can serve as an ideal candidate in reducing greenhouse emissions and can also help in fulfilling the partial energy needs globally. To achieve bioethanol, highly thermostable β-xylanase gene Thermotoga naphthophila was cloned and expressed in E. coli BL21 utilizing pET-21a(+) expression vector. To obtain maximum expression of recombinant xylanase, growth conditions i.e., temperature, pH, inducer and induction time of E. coli were optimized and found to be 7.0, 37ºC, 0.5 mM and 4 hours, respectively. Heat treatment was used for the partial purification of recombinant enzyme. Further purification was carried out by ammonium sulphate precipitation followed by the anion exchange chromatography. Molecular weight of pure recombinant β-xylanase enzyme was calculated to be 150 kDa by SDS-PAGE. Considerable stability was exhibited by the purified enzyme at pH value 8.0 and at temperature 90ºC. The activity of the enzyme was decreased considerably in the presence of EDTA and significantly increased in the presence of Cu⁺². The effect of different organic solvents (methanol, ethanol, n-butanol, acetone and isopropanol) was also explored but no considerable effect on activity of xylanase enzyme was observed. Similarly, inhibitors (urea, triton X-100, Tween-20, Tween-80 and β-mercaptoehanol) did not have any considerable effect on the enzyme activity, however, addition of SDS significantly reduced the activity of β-xylanase activity. The β-xylanase enzyme obtained can be utilized for the saccharification of lignocellulosic mass which can in turn be used in the production of bioethanol.

Biography:

Aida Farag has her expertise in production of important enzymes used in treatment as tannase. We used a marine environment as a new source for isolation of a fungus able to produce the enzyme. Also, the fungus was identified as Aspergillus nomius GWA5.  Partial purification by different agents was done followed by purification using two types of columns and characterization of the enzyme was also studied. The properties of Aspergillus nomius GWA5 tannase may make it very good candidate for using in biotechnology field.   

Abstract:

Tannase ) EC 3.1.1.20) was produced from the culture filtrate of  marine Aspergillus nomius GWA5 and purified by 75% acetone precipitation, followed  by gel filtration on Sephadex G-100 and on DEAE-Sephadex A-50 ion exchange chromatography, yielding 4.48-fold of purification. The molecular weight of the purified tannase was 30kDa, determined by a sodium dodecyl sulphate polyacrylamide gel electrophoresis. The optimum pH and temperature of the purified tannase yielding the highest activity (291 U/mg protein) were 6.0 and 50ºC, respectively. Tannase stability shifted to a more acidic range (4-6). Tannase enzyme was fairly stable to heat treatment in absence of its substrate and it retained about 84.5% of its activity when treated at 80 ºC for 15 min. The effect of activators and inhibitors on tannase activity was investigated, only Mg²⁺activated the pure enzyme while Cd²⁺, EDTA, Pb²⁺ and Hg²⁺ inhibited the enzyme activity and it retained about 51.55%, 40.78%, 30.24% and 24.55% of its activity, respectively. Tannase showed promising activity in removing tannin stains of tea from clothes.

Biography:

Hala Mourad Demerdash is currently an Associate Professor in the Faculty of Pharmacy, Pharos University in Alexandria (PUA) and Consultant in Clinical Pathology at Alexandria University Hospital. She graduated from the Faculty of Medicine Alexandria University and has received her Master’s degree from Chemical Pathology department, Medical Research Institute and she was a Resident in the Chemical Pathology department from1992-1995. She received her MD from Clinical Pathology Department, Faculty of Medicine, Tanta University in 2007. She was an Associate Professor in 2014 at Tanta University.

Abstract:

Obesity is a condition of abnormally increased body fat, resulting from increased energy intake relative to energy expenditure. Obesity is defined as having a body mass index (BMI) of 30 kg/m² or above, with an increasing incidence in all over the world. Obesity is associated with several health related problems that increase the risk of morbidity and mortality. Scientists have found that enzymes play an important role in obesity-related diseases. They found that at very low, basal levels, enzymes control the threshold of cellular function “signaling pathways”. The purpose of this review is to describe the role of oxidative stress in various obesity related health problems; since obesity is associated with oxidative stress as result of increased oxygen utilization due fat deposition in tissues, increased cardiac load, coupled with oxidative phosphorylation in mitochondria and depletion of ATP and consequent free radical formation. Moreover, high dietary saturated fatty acids (SFA) stimulate intracellular pathways, with more oxidative stress through superoxide generation from NADPH oxidases, glyceraldehyde autoxidation, protein kinase C (PKC) activation, and polyol pathway. In addition, oxidative stress is associated with the infiltration of adipose tissue by inflammatory cells, together with production of high levels of free radical as part of the immune response. Thus obesity is viewed as a chronic inflammatory situation that is critically important in development of pathological states due to tissue damage and altered enzyme activity that result in disease state to extent of tumorigenesis, such as insulin resistance diabetes, cardiovascular disease and kidney dysfunction. It can be concluded that weight reduction in obese subjects improve anti-oxidant defense of body; the triggering factor for series of molecular signals. Also, improving anti-oxidant defense through modulation of dietary pattern or pharmaceutical antioxidants, which may be a potential therapeutic approach in obesity related disease.

Biography:

Ebru Sakar is associate professor at Harran University Faculty of Agriculture, in the Department of Horticulture Osmanbey Campus, Turkey. He did his masters in gardens plants from Harran University, Turkey. His research interest is Fruit Growing and Breeding Biotechnology.

Abstract:

Present study was aimed to select superior genotypes within olive populations of Adıyaman, Mardin, Åžanlıurfa and Şırnak provinces in South East Anatolia, leading fruit and tree characteristics were determined in shoot, leaf and fruit samples collected from 142 genotypes. These genotypes were investigated according to “Weighted Rankit” method using fruit weight, number of fruits per 100g, flesh/seed ratio, oil ratio, fatty acid composition, habitus, lenticel size, length of internode and 38 promising genotypes as cultivar candidate (20 are table olives and 18 are olive oil) were selected. Among table genotypes, number of fruits per 100 g between 11 (Yurteri-4) and 25 (Derik-20 and Yedi kardeÅŸler-1), flesh/seed ratio between 5.85g (Yardere-2) and 11.40g (Yedi kardeÅŸler-3) and oil content between 3.0% (Eski kale) and 13.0% (Amak-1); among oil genotypes, fruit weight between 1.14g (Derik zeytin pınarı-2) and 8.99 g (Yurteri-4), flesh/seed ratio between 2.73 g (Zinnar-5) and 11.40 g (Yedi kardeÅŸler-3); oil content between 2.0% (Eski kale çıkışı) and 13.0% (Amak-1), oleic acid ratio between 63.25% (GürmeÅŸe-2) and 74.31% (Yurteri-6) and linolenic acid ratio between 0.49% (Yedi kardeÅŸler-1,Eski kale çıkışı) and 1.42% (BeÅŸdeÄŸirmen-2) were changed. Genetic characterization of 38 selected table and olive (Olea europaea L.) genotypes together with 6 local and 4 foreign reference cultivars obtained from Alata Horticultural Institute was performed using 10 microsatellite markers ((UDO4, UDO9, UDO12, UDO24, UDO26, DCA9, DCA11, DCA13, DCA15 and DCA18) and their genetic similarities were investigated by SSR method. Number of alleles per locus was determined between 7 (UDO9 and UDO24) and 16 (DCA18) for table genotypes and between 4 (UDO4) and 15 for oil genotypes (DCA11ve DCA18). Mean expected and observed heterozygosity were determined as 0.694-0.604 among table genotypes and 0.710 and 0.656 among oil genotypes, respectively. The dendrogram obtained from cluster analysis consisted of two main groups. Several sub-groups were observed within the first group which consisted of the majority of genotypes. This data was further supported by the AFLP analysis. Homonyms and synonyms were not obtained. Close genetic similarities were determined between Amak-1 and Yedi kardeÅŸler-3 in table genotypes and between. Zinnar-5 and Yurteri-4, between. GürmeÅŸe-1 and GürmeÅŸe-2 in oil genotypes.

Biography:

Zeina Nasr passion is to understand the molecular aspect of tumor initiation and progression. Her research focuses on studying the effect of translation initiation dysregulation on cancer behavior. She had worked with several cell lines and transgenic mouse models and deciphered important pathways that contribute to cancer initiation and progression to metastasis. She built her experience by conducting research and teaching in academic institutions. She is currently mainly interested in understanding the extraribosomal functions of ribosomal proteins and their effects on tumorigenesis.

Abstract:

Protein synthesis is a highly regulated and coordinated process involving the action of ribosomes and a set of translation factors. Ribosome biogenesis occurs in the nucleolus and requires the action of 80 ribosomal proteins (RPs), 4 ribosomal RNAs (rRNAs), other associated proteins and small nucleolar RNAs. The structure of the ribosomal subunits has identified the role of RPs as RNA chaperones for ribosomal assembly, and as endo- and exonucleases essential for the maturation of rRNAs. Some play a role in the joining of 40S and 60S subunits during translation initiation. Others interact with tRNA or stabilize the ribosome by encasing the exit groove. Studies have also shown that RPs may have extraribosomal functions, ranging from DNA repair to replication, proliferation, apoptosis, and chemoresistance. Mutations in RPs in animal models and humans induced a wide variety of phenotypes suggesting a role of RPs beyond the ribosome structure. Thus far, 11 RP mutant mice have been reported exhibiting diverse phenotypes including decrease body size, defective organs, and embryonic lethality. Defects in ribosome biogenesis have been linked to many diseases collectively named ribosomopathies. These include Myelodysplatic Syndromes, due to RPS14 haploinsufficiency and Diamond Blackfan Anemia, caused by mutations in RPS19 gene. These abnormalities have shown an increase susceptibility to hematological malignancies. Indeed, RPs have been linked to tumorigenesis in several reports, suggesting a role in promoting transformation. Several RPs are overexpressed upon activation of the oncogene Myc. Some are found overexpressed in various human tumors, including prostate and colon cancer, metastatic nasopharyngeal carcinomas, metastatic melanomas and metastatic human breast cancer cells. Some RPs have also been proposed as biomarkers for various cancers, such as colorectal, gastric, prostate cancers and lymph node metastasis. These pieces of evidence suggest that RPs could be used as potential targets in cancer therapeutics.

Biography:

Dino Hasanagic received his degree of M.Sc. from the Faculty of Science in Sarajevo, and he is currently attending plant biochemistry programme at Faculty of Science in Novi Sad, Serbia. His field of interest is antioxidative metabolism of plant cell - effects of abiotic stress (drought, metals, senescence, ROS signaling, redox state). Dr Biljana Kukavica is expert in plant enzyme antioxidative metabolism. Her interest is focused on enzyme and non-enzyme antioxidative defense in plant cell under oxidative stress. Dr Danijela Kojic has a big experience in the field of biochemistry and molecular biology and her researches are addressing the antioxidative enzyme role in adaptation to stress conditions. The expertise and passion of the authors is recognized among their peers, and they constantly expanding their knowledge in researches regarding enzymology.

Abstract:

The drought is a worldwide problem and insufficient supply of plants with water is one of the most important causes of low agricultural yields and thus representing one of the most common problems faced by the producers. There has been an increased interest in science in recent years in the use of natural aluminosilicates in agriculture where the most famous is zeolite, a mineral whose absorption properties and balanced release of water and nutritive substances ever more successfully solve the issue of water supplying and mineral nutrition and have beneficial impact on overall plant growth. The aim of this study was to investigate the role of zeolite in prevention of oxidative stress in tomato plants exposed to drought. Changes in the activity of peroxidase (POD, EC 1.11.1.7), catalase (CAT, EC 1.11.1.6), ascorbate peroxidase (APX, EC 1.11.1.11), superoxide dismutase (SOD, EC 1.15.1.1) as well as reduced and total ascorbate content in plant leaves exposed to drought for 28 days were investigated. Activities of antioxidant enzymes in the leaves of plants exposed to drought were at the same level with and without the addition of zeolite. The obtained results indicate that zeolite did not prevent oxidative damages caused by drought. Native electrophoresis resolved the presence of two peroxidase isoforms specific for drought and their activities were higher in tomato leaves whit zeolite. The drought induced an increase in activities of superoxide dismutase, ascorbate peroxidase and ascorbate concentration and this antioxidative strategy was more expressed in zeolite treated plants. Unexpected results related to the role of zeolite open the possibility to different perspectives in discussion on the zeolite role in drought prevention.

Biography:

Francesca Mangiavacchi has received her Master’s degree in 2016 under the supervision of Professor Antimo Gioiello and Claudio Santi in the Department of Pharmaceutical Sciences of University of Perugia. Currently, she is a Research Fellow in the group of Catalysis and Organic Green Chemistry of Professor Claudio Santi working on the development of new catalytic methods for oxidation of natural derivatives under mild conditions. In 2015, she received the award for the Best Oral Communication at the 4th Workshop on Selenium Sulphur and Redox Catalysis and in 2016 a Travel Fellowship from the University of Melbourne to attend at the International Conference on Selenium and Tellurium in Gifu (Japan) under the project Selenium (Redox) Therapeutics.

Abstract:

Oxidation reactions are a central and general field of organic and industrial chemistry, being defined as: “a process which involves a gain in oxygen and/or loss of hydrogen”. In recent years, a wide range of oxidative procedure has been developed in the attempt of synthetic chemist to satisfy the need of reaction efficiency and with regard of environmental impact. Although a great effort has been made, the development of new synthetic green processes is desirable. In pursuing our interest in green chemistry combined with our expertise in the selenium chemistry we have developed new eco-friendly oxidative process taking inspiration by biological mechanism of glutathione peroxidase (GPx). The catalytic cycle of GPx is an oxidation reaction in which the selenium atom of a selenocysteine is the catalyst; the hydrogen peroxide is the stoichiometric oxidant, and glutathione the substrate that is subjected to oxidation. In the native enzyme the catalytic triad prevents over oxidation of selenium that is able to oxidize only the thiols. In the absence of thiols and in the absence of stabilizing interaction small selenium containing compound are oxidized to selenonic or perseleninic acid and in this form they can transfer oxygen to carbon-carbon double bond and carbon oxygen double bond of aldehydes. Interestingly, these reactions can be carried out in “on-water” conditions having as unique side product a molecule of water. Herein we present some example of “bio-logical” oxidation applied to unsaturated organic substrates for the synthesis of diol, oxidation of aldehydes into carboxylic acids and oxidative cyclofunctionalization. We used catalytic amount of selenium based catalyst, as selenocysteine and diphenyl diselenide, and hydrogen peroxide as stoichiometric co-oxidant as greener oxidant. Furthermore, we use mild condition, and we could recycle the catalyst at least five times without an evident loss in terms of yields.