15^th International Conference on Plant Genomics August 29-30, 2022 Singapore City, Singapore

Track 1: Plant Genomics

Plant Genomics is the part of molecular biology working with the structure, function, evolution, and mapping of genomes in plants. Genomics is the study of genes, their expression and their activities, the role played in biology. Genomics is a branch of genetics that is concerned with the sequencing and analysis of organism's genome. Genomics aids us in maintaining the large number of database that assists us to study genetic variation.

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Track 2: Agricultural Science

Agricultural Science is a broad multidisciplinary field of sciences that consists of the parts of precise, natural, and social sciences that are utilized in the practice and understanding of agriculture agronomy is research and development related to studying and improving plant-based crops.

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Track 3: Plant Tissue Culture and Plant Biotechnology

Plant tissue culture is the growth of plant cells outermost an intact plant. It depends on maintaining plant tissue in lab conditions on a suitable nutrient medium. The culture can be sustained as a mass of undifferentiated cells for a broad area for a period of time, or regenerated into whole plants. The dissimilar techniques used in plant tissue culture. Plant tissue culture is mostly used to produce clones of a plant in a method known as micro-propagation with different stages. Plant Biotechnology is prominent in the field of medicine interfacing biotechnology and bioinformatics, the molecular characterization of medicinal plants; molecular farming; and result from chemistry, nanotechnology, pharmacology, agriculture, Biomass and biofuels as well. Plant Biotechnology is the technology which is used for getting modern product with high yield and at faster rate. 

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Track 4: Plant Proteomics

Plant Proteomics is concerned with the entire complement of proteins of plants including the modifications made to a particular set of proteins. Proteomics is an in depth study of a specific proteome, including information on protein and its modifications and variations. Proteomics works with the interacting partners and members associated with it in a sequential network.

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Track 5: Plant Science

Plant Sciences is the study of plant growth, reproduction, evolution, and adaptation, as well as the use of plants for food, fiber, and ornamental purposes. While students majoring in Plant Sciences necessarily share a common enthusiasm for plants, the variety of available courses and research opportunities encourages a great diversity of individual interests and career paths. Plant Sciences students gain the expertise necessary to advance research in and address many local, regional, and global challenges.

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Track 6: Cereals and Crops

Comparison of the order of blocks within the different cereal chromosomes revealed that each cereal genome can be derived from the cleavage of a single structure, a hypothetical ‘ancestral’ genome, from which the genomes of present day cereals and grasses have evolved. The rice genome is one of the smallest among the cereals and grasses, and in 1995, we demonstrated that rice could be a model for cereals based on this ‘synteny’ because its genome can be divided into groups of genes - a series of genomic building blocks - from which the other larger cereal genomes can be constructed. The genome analysis will also help in our efforts for improvement of staple foods for yield and quality, which is a continuous process because neither the conditions of cultivation nor the genomes have to be targeted to the need of adaptations to a variety of biotic and abiotic stresses. Functional food components vary across the cereal crops and within different tissues of grain. 

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Track 7 : Botanical Science

Botany is the science of plant life and a branch of biology that deals with the study of plants. Plants are a wide range of living organisms from the tiniest organisms to the mammoth living organisms. In general terms plants include algae, fungi, lichens, mosses, ferns, conifers and flowering plants. Botany is the scientific discipline that works on observation, experimentation, recording, classification, and the testing of hypotheses, in a methodological manner.

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Track 8: Plant Reproduction

Plant Reproduction is the creation of new individuals or offspring in plants, which can be refined by sexual or abiogenetic proliferation. Sexual reproduction produces posterity by the combination of gametes, bringing about posterity hereditarily not quite the same as the guardian or folks. Abiogenetic generation delivers new offspring’s without the combination of gametes, hereditarily indistinguishable to the guardian plants and one another, aside from when changes happen. In seed plants, the offspring can be bundled in a defensive seed, which is utilized as an source of dispersal.

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Track 9 : Molecular Plant Breeding

Plant breeding is simple: cross the best parents, and identify and recover progeny that outperform the parents. In practice, plant breeding is a three step process, wherein populations or germplasm collections with useful genetic variation are created or assembled, individuals with superior phenotypes are identified, and improved cultivars are developed from selected individuals. A wide diversity of approaches, tailored to the crop species and breeding objectives, have been developed for improving cultivars these breeding methods feature different types of populations, selection procedures, and outcomes.

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Track 10: Stress Signaling in Plants

Plants undergo continuous exposure to various biotic and abiotic stresses in their natural environment. To survive under such conditions, plants exhibit stress tolerance or stress avoidance through acclimation and adaptation mechanisms that ultimately re-establish cellular and organismal homeostasis or reduce episodic shock effects. These abilities involve intricate and complex mechanisms of perception, transduction, and transmission of stress stimuli, allowing optimal response to environmental conditions. The perception of stimuli and their expansion in cells involves signaling molecules such as intracellular calcium and reactive oxygen species, which intensify the action of particular signaling pathways.

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Track 11: Plant Nutritional Genomics

Plant nutrition is ultimately an applied subject that seeks to understand the processes and mechanisms that underpin the uptake, assimilation and internal redistribution of nutrients by plants and then to use this information to improve the yield or quality of harvested plant parts, be they grains, storage roots or leafy vegetables. The subject now also encompasses the understanding of the responses of plants to nutrient toxicities as well as new topics such as metal ‘hyper accumulation’ and its exploitation in soil decontamination.

Track 12: Plant Bioinformatics

The vast quantities of diverse biological data generated by recent biotechnological advances have led to the development and evolution of the field of bioinformatics. This relatively new field facilitates both the analysis of genomic and postgenomic data and the integration of information from the related fields of transcriptomics, proteomics, metabolomics and phenomics. Such integration enables the identification of genes and gene products, and can elucidate the functional relationships between genotype and observed phenotype, thereby permitting a system-wide analysis from genome to phenome.

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Track 13: Crop Improvement

Crop improvement refers to the genetic alteration of plants to satisfy human needs. In prehistory, human forebears in various parts of the world brought into cultivation a few hundred species from the hundreds of thousands available. In the process they transformed elements of these species into crops though genetic alterations that involved conscious and unconscious selection, the differential reproduction of variants. Through a long history of trial and error, a relatively few plant species have become the mainstay of agriculture and thus the world's food supply.

Related Conference: Plant Sciences | Plant Research | Plant Biochemistry | Plant Biotechnology | Plant Nanotechnology | Plant Pathology | Plant Phycology | Plant Anatomy and Morphology | Plant Hormones | Phytochemical Analysis | Plant metabolic engineering | Plant nutrition and soil science | Plant Tissue Culture | Plant Genetics and Genomics

Track 14: Plant Virology

Plant viruses are wide spread and economically important plant pathogens. The morphology, genome structure, reproduction strategy of different types of plant viruses, which together form the basis of virus classification. Plant viruses consist of a nucleoprotein in that multiplies only in the living cells of a host .The presence of viruses in host cells often results in disease,400 or more viruses are known to attack plants .Viruses are generally specific ,what infects aqueous plant does not cause disease in animal.

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Track 15: Plant physiology

Plant physiology is a sub discipline of plant science worried with the working, or physiology, of plants. Closely related fields incorporate plant morphology (structure of plants), plant nature (associations with the earth), phytochemistry (organic chemistry of plants), cell science, hereditary qualities, biophysics and atomic science. Central procedures, photosynthesis, breath, plant sustenance, plant hormone capacities, tropisms, nastic developments, photoperiodism, photo morphogenesis, circadian rhythms, natural push physiology, seed germination, torpidity and stomata capacity and transpiration, both parts of plant water relations, are concentrated on by plant physiologists.

Track 16: Seed genomics

Seed genomics, from fundamental seed science to handy applications in harvest science, gives a careful foundation comprehension of seed science from an essential science viewpoint. The field to cover three general subjects genomic ways to deal with considering seeds, genomic examination of fundamental seed science, and product seed genomics. From essential seed science to down to earth applications in product science, gives a careful foundation comprehension of seed science from a fundamental science point of view.

Track 17: Plant Epigenetics

A number of epigenetic phenomena were discovered in plants, but are not limited to plants. For instance, paramutation describes the heritable change in expression status of an allele upon its exposure to an allele that has the same sequence but displays a different expression status.  Plant biology has made to the discovery and study of epigenetic phenomena, plants provide ideal systems for epigenomics research. Epigenomic modifications alter gene expression without changing the letters of the DNA alphabet (A-T-C-G), providing cells with an additional tool to fine-tune how genes control the cellular machinery. By understanding epigenomic alterations in plants, scientists may be able to manipulate them for various purposes, including biofuels and creating crops that can withstand stressful events such as drought some of societies associated with Plant Epigenetics include.

Track 18: Gene Discovery

Future improvements of crop plants will benefit from the isolation and characterization of genes that underlie both simply-inherited and polygenic ally-controlled traits. The molecular isolation of economically important plant genes has been facilitated by the construction and application of genetic maps, transposon-based gene tagging, protein-protein interaction cloning, and the development and analysis of large collections of DNA sequences.

Related Conference: Plant Sciences | Plant Research | Plant Biochemistry | Plant Biotechnology | Plant Nanotechnology | Plant Pathology | Plant Phycology | Plant Anatomy and Morphology | Plant Hormones | Phytochemical Analysis | Plant metabolic engineering | Plant nutrition and soil science | Plant Tissue Culture | Plant Genetics and Genomics

Track 19: Plant Nanotechnology

The complex and different responses of plants to nanoparticles, the signal transduction mechanisms involved, and the regulation of DNA expression. Nanoparticles have received much response because of the unique physio-chemical properties of these compounds. Nanotechnology also play an important role in agriculture as compound fertilizers and minute-pesticides, acting as chemical delivery agents that target molecules to specific cellular organelles in plants.

Related Conference: Plant Sciences | Plant Research | Plant Biochemistry | Plant Biotechnology | Plant Nanotechnology | Plant Pathology | Plant Phycology | Plant Anatomy and Morphology | Plant Hormones | Phytochemical Analysis | Plant metabolic engineering | Plant nutrition and soil science | Plant Tissue Culture | Plant Genetics and Genomics

Track 20: Seeds and Plant Genetic Resources

Plant genetic resources are the biological basis of food security. Plant genetic resources for food and agriculture consist of diversity of seeds and planting materials of traditional varieties and modern cultivars, crop wild relatives, and other wild plant species. These resources are used as food, feed for domestic animals, fibres, textiles, and energy. Their conservation and sustainable use is necessary to ensure crop production and to meet growing environmental challenges and climate change. The erosion of these resources poses a severe threat to the world's food security in the long term.

Track 21: Plant Genetic Resource Conservation

Plant genetic resource conservation (PGRC) involves managing and using resources in a manner that does not deplete them. The major objective of PGRC is to safeguard plant genetic diversity from, or to compensate for, deterioration or loss by a variety of causes. In doing so, PGRC may also help traditional farming cultures survive (Alcorn, 1991). The needs of burgeoning human populations have caused habitat destruction through conversion (e.g., clear-cutting of woodlands and paving of agricultural fields; Noss and Peters, 1995) and habitat deterioration through climatic change (Graudal et al., 1995) and chemical contamination, etc. These habitat changes are currently the primary causes for extinction of plant communities, taxa, and their constituent genes. For example, Wilkes (1991) reported that during a 25-year period, many Mexican and Guatemalan populations of teosinte (species of Zea L.), the wild relative of maize (Z. mays L. ssp. mays), were reduced to fractions of their previous size through habitat conversion. Perrino (1994) estimated that in recent years 90% of the traditional wheat varieties in Italy have been extirpated because their habitat, traditional Italian farming villages, has been transformed into modern communities emphasizing non-agricultural employment.

Track 22: Sustainable Food Systems and Agriculture

Plant Genetic Resources (PGR) have an important role to play to ensure food security. They have been the foundation for the development agriculture ever since it started 10,000 years ago. Agriculture and food production today is faced with many challenges such as climate change, land degradation, increasing human population, and biodiversity loss. This article discusses the specific role that PGR have to play in addressing these challenges in order to secure food to humanity in a sustainable way. The chapter also explains the concept of genetic resources and gives a historical account of the actions taken by the global scientific community to conserve and use PGR. Moreover, the different strategies and methods for conservation (ex situ, in situ and on farm conservation) of PGR are presented.

Track 23: Breeding Genetics and Biotechnology

Plant genetic resources have defined as the genetic material of plants, which is of value as a resource for present and future generations of people. Traditionally, this definition focused on crop plants and their wild relatives, but it is increasingly considered that all plant species are a potential resource for humanity. The ultimate goal of genetic resources conservation is to ensure that the maximum possible genetic diversity of a taxon is maintained and available for utilization. Plant genetic resource conservation acts as a link between the genetic diversity of a plant and its utilization or exploitation by humans.

Plant Sciences | Plant Research | Plant Biochemistry | Plant Biotechnology | Plant Nanotechnology | Plant Pathology | Plant Phycology | Plant Anatomy and Morphology | Plant Hormones | Phytochemical Analysis | Plant metabolic engineering | Plant nutrition and soil science | Plant Tissue Culture | Plant Genetics and Genomics

Track 24: Biodiversity and Ecosystem Services

Plant genetic resources for food and agriculture are one component of biodiversity, whose management can influence ecosystem services. It is provide provisioning services, such as food, as well as regulating, supporting and cultural services. Today’s agricultural systems focus on improving productivity. In this context, a strong focus on only provisioning ecosystem services has threatened, as uniform, improved varieties have displaced locally adapted varieties, eliminating considerable PGRFA from farmers’ fields (Fowler and Mooney, 1990). By 1999, only twelve crops and five animal species made up 75% of the world’s food demand (FAO, 1999). Globally, the land area devoted to high-yielding cereals has increased starkly over the past 50 years. Rice, wheat, and maize collectively increased from 66% to 79% of all cereal area between 1961 and 2013, at the expense of other cereals containing a higher micronutrient content (DeFries et al., 2015). For example, the cultivated area for sorghum, barley, oats, rye, and millet declined from 33% to 19% of the total cereal area.

Globalization has resulted in homogeneity not just in the types of crop cultivated, but also in the diets of people. While there is growing diversity on individuals’ plates, the difference between national diets is decreasing and cultivation of foreign crops is increasing (Khoury et al., 2014; and Chapter 2: Global Trends and Challenges to Food and Agriculture into the 21st Century). Foreign crops represent 69% of current production systems, and thus countries are becoming more interdependent in accessing diversity of foods and nutrients (Khoury et al., 2014; 2016).

Track 25: Genomics-Based Hybrid Rye Breeding

Plant Genetic Resources (PGRs) are important stocks for broadening the genetic diversity in elite breeding populations. This is especially valid for hybrid breeding, because the gene pools representing the heterotic groups are proprietary to the private breeding companies and, therefore, may deplete in genetic variation over time by artificial selection (Kovach and McCouch, 2008; Wright et al., 2005; Yamasaki et al., 2005), resulting in a reduced selection gain. Rye has a rich reservoir of self-incompatible PGR with more than 22,000 accessions maintained in 94 gene banks (Schlegel, 2014). Among them are wild species, weedy rye populations, old landraces, and elite populations from the main rye-growing countries. For introgressing, monogenic traits, like Rf genes or disease resistance genes, repeated marker-assisted backcrossing would be the most straightforward solution. When using PGR for introgressing of quantitative traits, the main challenges (Haussmann et al., 2004) are the unknown membership to heterotic groups, the high genetic load making continued self-inefficient, a potential yield penalty either caused by linkage of highly valuable genomic segments with unwanted loci or by pleiotropy and a lack in adaptive traits necessary for performance testing (e.g., flowering date, lodging resistance). While molecular markers (Fischer et al., 2010) can easily attain the assignment to heterotic groups, the other challenges could only be solved by a targeted identification of valuable genomic segments prior to broad introgressing into self-fertile elite populations. One possibility is the use of introgressing libraries consisting of a series of near-isogenic lines (NILs) where each line has only a small marker-defined donor chromosome segment (DCS) from the PGR and all lines together represent the total donor genome (Eshed and Zamir, 1994). By restricting the introgressing to defined DCS in an elite background, the mentioned challenges are minimized and the subsequent introgression into elite populations can focus on short, pretested, beneficial DCS. Crossing and marker-based backcrossing (Falke et al., 2008), developed two introgression libraries in winter rye. They comprised each of 40 BC2S3 lines covering 74% and 59% of the total genome of the Iranian primitive rye Altevogt 14160.

Evaluation of multienvironmental testcross performance revealed that 60% of the introgression lines were significantly superior to the recurrent elite parent line in at least one of the traits grain yield, plant height, TKW, falling number, pentosan, protein or starch content, assuming beneficial QTL in the DCS (Falke et al., 2009a). By using a mixed linear model, many of the beneficial QTL could be assigned to individual DCS although most lines had more than one DCS (Mahone et al., 2013). Only some DCS for quality traits were detected in both, per se and testcross performance (Falke et al., 2010). The main shortcomings of these early introgression libraries produced from 1999 to 2003 were the dependence on AFLP markers in the early generations that were not easy to reproduce, a nonsaturated genetic map, and a too short backcrossing procedure resulting mainly in introgression lines with several, rather long DCS. Later, computer simulations revealed that it is advantageous to use the BC3S2 generations for constructing introgression libraries with increasing population sizes from early to advanced generations (Falke et al., 2009c)

Importance and scope

Plant genomics is a mounting and constantly evolving field of study, one which has gained much ground in past years through the development of advanced research and data management tools. Expert researchers explore the current issues and methodologies of this expanding field, specifically addressing areas of gene discovery and the functional analysis of genes with a target on the primary tools and sub-disciplines of genetic mapping, mRNA, protein and metabolite profiling. Plant genomics employ exciting new methods to investigate molecular plant breeding technology and gene functional analysis via transformation, mutation, protein function, and gene expression. The success of transgenic crops has erased the last vestiges of doubt about the value of agricultural biotechnology and triggered large-scale investments in plant genomics. The first genomics technology that was practiced on a large scale was sequencing the 5′ ends of cDNAs, to produce expressed sequence tags (ESTs).

Plant Genomics has roots in agriculture and Plant Genomics also has scope in agriculture fields, medicine, food production and textiles. It is the main source of food for human being. As well as we can get plant proteins, phytochemicals from plants, from medicinal plants some medicines are prepared and which can cure some fatal diseases. Form some recent study it is proved that plant antioxidant helps us to protect from free radical damage. By using Phytochemicals some cancer cell proliferation can be prevented at earlier stage. Beside that we can increase the nutrition value of plant by plant biotechnology and plant breeding.  Now days green energy are used as non-conventional source of energy to reduce environmental pollution. So in human life Plant Genomics and plant oriented studies are very much important to sustain in this planet.
 

Value of Plant genomics to Agriculture and Society

Genomics will accelerate the application of gene technology to agriculture. this technology will enhance food security, by increasing productivity, and food safety, by eliminating Mycotoxins. There is a third benefit, derived from the first two: increased wealth. By accelerating the application of technology, genomics significantly increases the value of seeds and agricultural products. This increase adds much wealth to the customers, company owners, employees, and citizens of the nations in which genetic supply companies operate, and to both producing and importing nations whose food costs consequently are decreased.

Agricultural plant genomics should be publicly funded for several reasons. First, the DNA sequence of plants is necessary for continued low-cost, rapid progress to understand crops. As such, it is an essential resource for scientists in both the public and private sectors. Second, industry needs the public sector to create innovative methods for structuring and analysing databases, which can’t be done without access to genomics resources. Third, genomics is an equalizer in the research world. 

The significance of plants in human life is significant. Plants and plant products are essential for us. Food, energy, medicine and so many things we are able to get from plants. This conference seek to bring all such scientist, Noble Laureate, researcher, research scholar, students and people together who are involved in this field and provide them to discuss about their innovation, exchange ideas and interaction with each other.

Major Plant science Associations around the Globe

American Society of Plant Biologists (ASPB)

Australian Society of Plant Scientists (ASPS)

Argentinean Society of Plant Physiology (SAFV)

American Society of Agronomy (ASA)

African Crop Science Society (ACSS)

Brazilian Society of Plant Physiology (SBFV)

Botanical Society of China (BSC)

Canadian Society of Plant Biologists (CSPB)

Chile’s National Network of Plant Biologists (CNNPB)

Chinese Society of Plant Biology (CSPB)

Crop Science Society of America (CSSA)

Crop Science Society of China (CSSC)

European Association for Research on Plant Breeding (EUCARPIA)

European Plant Science Organisation (EPSO)

Federation of European Societies of Plant Biology (FESPB)

Genetics Society of China (GSC)

International Society of Plant Pathology (ISPP)

Indian Society of Plant Physiology (ISPP)

International Crop Science Society (ICSS)

International Society for Horticultural Science (ISHS)

Irish Plant Scientists' Association (IPSA)

International Society for Plant Molecular Biology (ISPMB)

Japanese Society for Plant Cell and Molecular Biology (JSPCMB)

Japanese Society of Plant Physiologists (JSPP)

Korean Society of Plant Biologists (KSPB)

New Zealand Society of Plant Biologists (NZSPB)

Target Audience:

The target audience will be Plant Biologist, Microbiologist, plant physiologist, agriculturalist plant pathologist, Molecular and cell biologist researcher or scientist who are researching in cancer biology and using plant product as cancer reducing agent.

Meet Your Target Market With members from around the world focused on learning about Plant Genomics, this is your single best opportunity to reach the largest assemblage of participants from the all Over the World. Conduct demonstrations, distribute information, meet with current, make a splash with a new product line, and receive name recognition at this 3-day event. World-renowned speakers, the most recent techniques, tactics, and the newest updates in Plant Science are hallmarks of this conference.

A Unique Opportunity for Advertisers and Sponsors at this International event:

https://plantgenomics.environmentalconferences.org/sponsors.php

The global market for genomics is expected to reach USD 22.1 billion by 2022, growing at an estimated CAGR of 10.3% from 2014 to 2022, according to a new study by Grand View Research, Inc. Genomics play an imperative role in the field of infectious disease testing by enabling the use of fast and effective result rendering molecular diagnostic tests. This, coupled with growing prevalence of infectious diseases and hospital acquired infections is expected to drive market growth during the forecast period. Other driving factors for this market include decreasing prices of DNA sequencing, increasing demand for genome analysis in animal and plant feedstock, extensive presence of both private and public external funding programs and growing patient awareness levels. In addition, presence of untapped growth opportunities in emerging countries such as India, Brazil and China and the increasing health awareness are expected to serve this market as future growth opportunities.

Genomics based diagnostics dominated the overall market in terms of revenue at 36.4% in 2013 majorly owing to the presence of a relatively larger number of R&D programs. Genomics based personalized medicine segment on the other hand is expected to grow at the fastest CAGR of over 12.0% from 2014 to 2022 due to increasing demand for population based therapeutic solutions and subsequent increase in R&D initiatives.

Market Size - $11.1 Billion in 2013, Market Growth - CAGR of 10.3% from 2014 to 2022, Market Trends - Growing demand for personalized medicine and the consequent rise in demand for genomics based R&D initiatives is expected to drive market growth during the forecast period

Past Conference

Conference Series LLC LTD invites all the participants from all over the world to attend 29^th  International Conference on Proteomics, Genomics & Bioinformatics during July 27-28, 2020 (Webinar) which includes prompt keynote presentations, Oral talks, Poster presentations, and Exhibitions.

Plant Genomics 2020 is the premier event that brings together a unique and international mix of experts, researchers and decision makers both from academia and industry across the globe to exchange their knowledge, expertise and research innovations to build a world-class plant genomics conference.

It’s our greatest pleasure to welcome you to the official website of ‘29^th 15th International Conference on Proteomics, Genomics & Bioinformatics that aims at bringing together the Professors, Researchers, scientists, Program developers to provide an international forum for the dissemination of original research results, new ideas, and practical development experiences which concentrate on both theory and practices. The conference will be held on July 27-28, 2020. The theme of the conference is around, “COVID-19 effect on Accelerating Innovations in Plant Genomics”. Featuring 2 days of the scientific webinar, special sessions, speaker & poster session,  Industrial Expo. 300+ attendees from all over the world. The event focuses on aspects such Plant Genomic, Speciation & Origin of Genomes, Plant Genetics and Epigenetics, Plant Nutritional Genomics and Horticulture, Plant Science and Agricultural Sciences, Genome Sequencing and Plant Molecular Breeding, Plant Proteomics as well understanding tools to overcome the barrier and enable successful data analysis and management. Presentations concentrate not only particular to plant genomics but also crop and forestry research ranging from wheat, barley, maize and rice to potato, tomato, Arabidopsis, biofuels and various fruits. Conference Series LLC LTD organizes a conference series of 1000+ Global Events inclusive of 300+ Conferences, 500+ Upcoming and Previous Symposiums and Workshops in USA, Europe & Asia with support from 1000 more scientific societies and publishes 700+ Open access journals which contain over 30000 eminent personalities, reputed scientists as editorial board members.

Why to attend???

With members from around the world focused on learning about Plant Genomics and its advances; this is your best opportunity to reach the largest assemblage of participants from the Plant Science and Genomics community. Conduct presentations, distribute information, meet with current and potential scientists, make a splash with new advancements and developments, and receive name recognition at this 2-day event. World-renowned speakers, the most recent techniques, developments, and the newest updates in Plant Genomics are hallmarks of this conference.

Target Audience:

• Plant Genomics Students, Scientists
• Plant Genomics Researchers
• Plant Genomics Faculty
• Agricultural Colleges
• Plant and Agriculture Associations and Societies
• Business Entrepreneurs
• Training Institutes
• Software developing companies
• Manufacturing Agricultural Devices Companies

For more information:- https://plantgenomics.environmentalconferences.org/2020