Call for Abstract

19th International Conference on Microbial Interactions & Microbial Ecology, will be organized around the theme “Antimicrobial Resistance: The Role of Microbial Interactions in Drug Resistance Evolution”

Microbial Interactions 2024 is comprised of 23 tracks and 0 sessions designed to offer comprehensive sessions that address current issues in Microbial Interactions 2024.

Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.

Register now for the conference by choosing an appropriate package suitable to you.

Microbial interactions encompass the myriad ways in which microorganisms interact with each other and their environments. These interactions can be synergistic, where both or all participating organisms benefit, or antagonistic, where one organism's growth and survival come at the expense of another. Examples of synergistic interactions include mutualism, where different microbial species cooperate for mutual benefit, such as nitrogen-fixing bacteria in root nodules of legumes providing essential nutrients to the plant while receiving carbohydrates in return. Another form of positive interaction is commensalism, where one organism benefits without harming or helping the other, as seen in the human gut where some bacteria thrive on the nutrients present without affecting the host, Conversely, antagonistic interactions are characterized by competition, amensalism, and predation. In competitive scenarios, microorganisms vie for the same resources, such as nutrients or space, leading to the inhibition or exclusion of some species. Amensalism occurs when one organism produces substances that inhibit or kill another organism, a classic example being the production of antibiotics by certain fungi or bacteria that suppress the growth of nearby competitors. Predation involves one microorganism actively consuming another, such as bacteriophages infecting and lysing bacterial cells. These interactions are crucial in shaping microbial communities, influencing ecological balance, and driving evolutionary processes.

Host-Pathogen Interaction along with organic manure in solving stressed agriculture problems. Beneficial microbes associated with plants are known to stimulate plant growth and enhance plant resistance to biotic (diseases) and abiotic (salinity, drought, pollutions, etc.) stresses. The plant growth-promoting rhizobacteria (PGPR) and mycorrhizae, a key component of Host-Pathogen, could play vital roles in the maintenance of plant fitness and soil health under stressed environments,The host-pathogen interaction is defined as how microbes or viruses sustain themselves within host organisms on a molecular, cellular, organismal or population level. This term is most commonly used to refer to disease-causing microorganisms although they may not cause illness in all hosts. Because of this, the definition has been expanded to how known pathogens survive within their host, whether they cause disease or not. On the molecular and cellular level, microbes can infect the host and divide rapidly, causing disease by being there and causing a homeostatic imbalance in the body, or by secreting toxins which cause symptoms to appear. Viruses can also infect the host with virulent DNA, which can affect normal cell processes (transcription, translation, etc.), protein folding, or evading the immune response.

Soil-plant-microbe interactions along with organic manure in solving stressed agriculture problems. Beneficial microbes associated with plants are known to stimulate plant growth and enhance plant resistance to biotic (diseases) and abiotic (salinity, drought, pollutions, etc.) stresses. The plant growth-promoting rhizobacteria (PGPR) and mycorrhizae, a key component of soil microbiota, could play vital roles in the maintenance of plant fitness and soil health under stressed environments, Plant-soil microbe interactions are critical to the health and productivity of ecosystems. These interactions involve a complex network of relationships where plants, soil, and microorganisms communicate and exchange nutrients. Plants exude a variety of organic compounds through their roots, which serve as food for soil microbes. In return, these microbes help plants by enhancing nutrient availability, decomposing organic matter, and protecting plants from pathogens. Mycorrhizal fungi, for instance, form symbiotic associations with plant roots, extending their reach and enhancing the uptake of water and essential nutrients like phosphorus.

Microbial ecology is the study of relationship between microbes and their surrounds, biased image of the role of microbes in nature obtained from laboratory studies of pure culture cultures  data leads to inappropriate conclusions about their relevance. Eg. E. coli grows in animals intestinal tracts but merely survive in aquatic environments , E. coli are transients and not residents of aquifers from which they can be isolated.Microbial ecology studies entail the use of conventional microbiological techniques (cultural / enumeration procedures, EM, radioactive tracer methods) and modern molecular techniques (gene analysis, nuclei acid probes, sequencing) .EcologyEvolution and Biodiversity, formerly the Microbial Ecology and Evolution track encompasses many aspects of microbial and phage ecology and the roles of microbes in their natural environments. Our rapidly advancing knowledge of the complexity, immense diversity, and important roles of natural microbial communities will be highlighted in many of the exciting EEB sessions

The activities of complex communities of microbes affect biogeochemical transformations in natural, managed and engineered ecosystems. Meaningfully defining what constitutes a community of interacting microbial populations is not trivial, but is important for rigorous progress in the field. Important elements of research in microbial community ecology include the analysis of functional pathways for nutrient resource and energy flows, mechanistic understanding of interactions between microbial populations and their environment, and the emergent properties of the complex community.

  • Soil Microbial Community
  • Rizosphere Microbial Communities
  • Photoautotroph Microbial Communities
  • Water Microbial Community

microorganism may be a microbe that has the potential to cause sickness. To cause an infection, microbes should enter our bodies. Microbes will enter the body through the four sites listed below: Respiratory tract (mouth and nose) e.g. respiratory  disease virus that causes the contagious disease.Gastrointestinal tract (mouth oral cavity) e.g. eubacteria epidemic cholera that causes cholera. Urogenital tract e.g. Escherichia  that causes    urinary tract infection. Breaks within the skin surface e.g. eubacteria tetani that causes tetanus, Microbial diseases are caused by microorganisms such as bacteria, viruses, fungi, and parasites. These diseases can range from mild infections, like the common cold, to severe illnesses, such as tuberculosis, HIV/AIDS, and malaria. Microorganisms can enter the body through various routes, including inhalation, ingestion, or direct contact with contaminated surfaces or bodily fluids. Once inside, they multiply and produce toxins or trigger immune responses that lead to symptoms of disease. The severity and spread of microbial diseases are influenced by factors such as the virulence of the microorganism, the host's immune system, and environmental conditions.

Microbiology & Infectious Diseases are affected by interaction between microorganisms in three ways. The indigenous flora (commensal microorganisms) of some mucous surfaces provide one of the main protective mechanisms against infection by pathogens (disease-producing microbes). The commensal populations interfere with the establishment of pathogens on mucous membranes by evoking anaerobic conditions, by competing for space and nutrients and by producing inhibitors. How, at the beginning of successful infection, pathogens in relatively small numbers overcome this protective activity of the commensal population is unknown, Microbiology is the branch of biology that focuses on the study of microorganisms, which include bacteria, viruses, fungi, and parasites. It delves into their structure, function, genetics, and ecological roles. Understanding microbiology is crucial in the context of infectious diseases, as many pathogens are microorganisms that can cause illness in humans, animals, and plants. Microbiologists investigate how these organisms spread, evolve, and interact with their hosts and environments. They play a vital role in developing treatments such as antibiotics and vaccines, as well as in designing strategies for disease prevention and control.

Applied and Environmental Science (AES) is well-covered in the program of Microbiology 2020. The most exciting findings in this field in the last few years will be presented including recent, game-changing discoveriescausing disease by being there and causing a homeostatic imbalance in the body, or by secreting toxins which cause symptoms to appear. Viruses can also infect the host with virulent DNA, which can affect normal cell processes (transcription, translation, etc.), protein folding, or evading the immune response, Applied and Environmental Science are dynamic fields at the forefront of addressing global challenges related to sustainability, pollution, and resource management. Applied science involves the practical application of scientific knowledge and principles to solve real-world problems. In the context of environmental science, this often translates to developing technologies, strategies, and policies aimed at mitigating environmental impact, conserving natural resources, and promoting sustainable development. Researchers in applied and environmental science collaborate across disciplines such as chemistry, biology, engineering, and policy-making to innovate solutions that balance human needs with ecological integrity.

The track is organized into three thematic sessions: Soil MicrobiologyWater Microbiology, and Environmental Biotechnology. The first sessions includes researches on soil as a habitat for microorganisms, and introduces the main types of soil microorganisms, how they interact with the soil, and the techniques used in their analysis. Soil microbiology is the study of organisms in soil, their functions, and how they affect soil properties. It is believed that between two and four billion years ago, the first ancient bacteria and microorganisms came about in Earth's oceans. In the second section includes Freshwater, Wastewater, and Drinking Water Microbiology and assays of microbial pathogens-bacteria, viruses, and protozoan parasites which are used in food and water quality control as well as an exercise in applied bioremediation of contaminants in water.

Antimicrobial Agents and Resistance (AAR) will cover a range of important topics. One of the major challenges today is the rising tide of antimicrobial resistance, with the emergence of "untreatable" microbes causing diseases that were once readily treatable. The AAR track is the best place to find information regarding new antimicrobial agent discovery, preclinical investigations of new antimicrobial drugs in the pipeline, and first-look data of human clinical trials using new antimicrobial agents,Antimicrobial agents are substances used to kill or inhibit the growth of microorganisms, including bacteria, viruses, fungi, and parasites. These agents, which include antibiotics, antifungals, antivirals, and antiparasitics, are critical in treating infections and preventing the spread of disease. Antibiotics, for instance, have been pivotal in combating bacterial infections such as tuberculosis, pneumonia, and sepsis. However, the misuse and overuse of antimicrobial agents in both human medicine and agriculture have led to the development of antimicrobial resistance (AMR), where microorganisms evolve mechanisms to withstand the effects of these drugs.

Mycology, the study of fungi, is a critical field of biology that delves into the diverse and complex world of fungal organisms. Fungi play vital roles in various ecosystems, acting as decomposers, symbionts, and pathogens. Their unique biology, including their ability to form complex structures like mycelia and spores, allows them to thrive in a wide range of environments. Mycology covers the taxonomy, genetics, physiology, and ecology of fungi, providing insights into their evolutionary relationships and functional roles in nature. This field is not only important for understanding biodiversity and ecosystem dynamics but also for its implications in agriculture, industry, and medicine, Fungal pathogens and associated diseases are a significant focus within mycology due to their impact on human health, agriculture, and the environment. Fungal infections can range from superficial conditions like athlete's foot to life-threatening systemic diseases such as cryptococcosis and aspergillosis, particularly in immunocompromised individuals. Agricultural crops are also vulnerable to fungal pathogens, which can cause devastating diseases like rusts, blights, and mildews, leading to substantial economic losses. Advances in mycology are essential for developing effective antifungal therapies, improving diagnostic techniques, and implementing sustainable agricultural practices to manage and mitigate the effects of fungal pathogens. Understanding the mechanisms of fungal pathogenicity and host resistance is crucial for addressing the challenges posed by these versatile and often resilient organisms.

Clinical and Public Health Microbiolog has always been well-represented at Microbiology Conferences, Meetings and will continue to be so at Microbiology 2024. Thorough coverage of the science of antibiotic susceptibility testing: new protocols, new drug panels, new drugs in the pipeline, and new organisms to test are among the most important part of the track. Sessions in this track will also deep dive into testing and treatment of all clinically important microbe with growing incidence,Clinical and public health microbiology are critical disciplines within the field of microbiology that focus on different aspects of disease prevention, diagnosis, and control. Clinical microbiology primarily deals with the identification and characterization of microbial pathogens that cause infections in humans. This involves using a variety of techniques, such as culturing microorganisms from patient samples, performing biochemical tests, and utilizing advanced molecular methods like PCR to detect specific pathogens. Clinical microbiologists play a vital role in healthcare settings by providing timely and accurate diagnostic information that guides treatment decisions and helps in the management of infectious diseases.

Exciting developments in Food Microbiology has been the availability and application of molecular analyses that have allowed scientists to address microbial food safety questions beyond merely determining whether particular pathogens are in a food. Such global analyses are allowing scientists to ask deeper questions regarding food-borne pathogens and are currently leading the way to ascertaining the genes, proteins, networks, and cellular mechanisms that determine the persistence of strains in foods and other environments, determine why certain strains are more commonly isolated from foods, and determine why certain strains are more pathogenic. Such molecular tools are also making it possible to more fully determine the microflora present in foods along with pathogens, and to assess the effect that the food microbiota has on the death, survival, and pathogenicity of food borne pathogens.We are in the era of speed and precision. Like many other disciplines in environmental biologyaquatic microbiology tends to move forward with new rapid and cutting edge tools to study water-related microorganisms from river banks to the abyss of the oceans. These innovations help to resolve the issues with determining the risks associated with climate change, human activities as well as the interactions between species to redefine what a healthy water environment is for all living organisms sharing these environments

Molecular microbiology is a rapidly expanding area of contemporary science: the application of molecular biology has opened up the microbial world in many remarkable ways. The attraction of microbes is that they are self-contained and that they offer complete solutions to understanding the phenomenon of life, Molecular microbiology is a specialized branch of microbiology that delves into the intricate world of microorganisms at the molecular level. It focuses on understanding the genetic and biochemical mechanisms that govern microbial life, encompassing a wide range of organisms from bacteria and archaea to viruses and fungi. By studying the molecular processes within these organisms, researchers gain insights into fundamental biological processes such as metabolism, gene regulation, and cellular signaling. This field is pivotal in advancing our understanding of microbial pathogenesis, antimicrobial resistance, and microbial interactions with their environments, offering critical knowledge for developing new therapeutic strategies and biotechnological applications.

The focus is the host cell responses elicited by the interaction of micro-organisms. Equal emphasis is placed on responses to prokaryotic, viral and eukaryotic micro-organisms. In addition to mammalian systems, papers addressing other hosts such as plants and insects are strongly encourage. Systems biology is a rapidly expanding discipline fueled by the 'omics era and new technological advances that have increased the precision of data obtainable, Cellular microbiology focuses on understanding the interactions between microorganisms and their host cells at a cellular and molecular level. This field delves into how bacteria, viruses, and other microbes interact with host cells, hijacking cellular processes to establish infection or symbiotic relationships. Researchers in cellular microbiology study the mechanisms of pathogenesis, immune evasion, and host responses, aiming to uncover new targets for therapeutic interventions. By elucidating the intricate dynamics between microbes and host cells, cellular microbiology contributes to advancements in medicine, vaccine development, and strategies to combat infectious diseases.

Antimicrobial Agents and Resistance (AAR) will cover a range of important topics. One of the major challenges today is the rising tide of antimicrobial resistance, with the emergence of "untreatable" microbes causing diseases that were once readily treatable. The AAR track is the best place to find information regarding new antimicrobial agent discovery, preclinical investigations of new antimicrobial drugs in the pipeline, and first-look data of human clinical trials using new antimicrobial agents,Antimicrobial agents are substances used to kill or inhibit the growth of microorganisms, including bacteria, viruses, fungi, and parasites. These agents, which include antibiotics, antifungals, antivirals, and antiparasitics, are critical in treating infections and preventing the spread of disease. Antibiotics, for instance, have been pivotal in combating bacterial infections such as tuberculosis, pneumonia, and sepsis. However, the misuse and overuse of antimicrobial agents in both human medicine and agriculture have led to the development of antimicrobial resistance (AMR), where microorganisms evolve mechanisms to withstand the effects of these drugs.

Microbial biodegradation is the use of bioremediation and biotransformation methods to harness the naturally occurring ability of microbial xenobiotic metabolism to degrade, transform or accumulate environmental pollutants, including hydrocarbons (e.g. oil), polychlorinated biphenyls (PCBs), polyaromatic hydrocarbons (PAHs), heterocyclic compounds (such as pyridine or quinoline), pharmaceutical substances, radionuclides and metals. Biological processes play a major role in the removal of contaminants and take advantage of the catabolic versatility of microorganisms to degrade or convert such compounds. Interest in the microbial biodegradation of pollutants has intensified in recent years,and recent major methodological breakthroughs have enabled detailed genomic, metagenomic, proteomic, bioinformatic and other high-throughput analyses of environmentally relevant microorganisms, providing new insights into biodegradative pathways and the ability of organisms to adapt to changing environmental conditions.

Veterinary Microbiology addresses both specific, defined problems, as well as trends in host/parasite interaction. This session is a complete reference on microbial biology, diseases, diagnosis, prevention, and control. Also foundation of knowledge on pathogens and how they interact with hosts, Veterinary microbiology is a specialized field within veterinary medicine that focuses on the study of microorganisms relevant to animal health and disease. This discipline encompasses the investigation of various pathogens such as bacteria, viruses, fungi, and parasites that can affect animals. Understanding these microorganisms is crucial for diagnosing, treating, and preventing infectious diseases in livestock, pets, and wildlife. Veterinary microbiologists employ a range of techniques, from traditional culturing methods to advanced molecular biology and genomic sequencing, to identify and characterize pathogens. By studying the interactions between microorganisms and their animal hosts, veterinary microbiologists contribute significantly to improving animal welfare, enhancing food safety, and preventing the spread of zoonotic diseases that can affect humans.

Microbial cytology is the study of the structure, function, and life processes of microbial cells. It delves into the detailed architecture of bacteria, archaea, fungi, and other microorganisms, focusing on cellular components such as the cell wall, membrane, cytoplasm, and organelles. Advances in microscopy and imaging techniques have allowed scientists to observe these structures with unprecedented detail, providing insights into how microbes grow, reproduce, and interact with their environments. Understanding microbial cytology is fundamental for various applications, including the development of antibiotics that target specific cellular components and the engineering of microbes for industrial processes, Microbial physiology examines the metabolic and biochemical processes that enable microorganisms to sustain life, grow, and reproduce. This includes studying how microbes obtain energy, utilize nutrients, and regulate their internal environments in response to external conditions. Insights from microbial physiology are crucial for biotechnology, as they help in optimizing microbial processes for the production of biofuels, pharmaceuticals, and other valuable products. Recombination DNA technology, which involves the manipulation of DNA sequences to create new genetic combinations, leverages knowledge from microbial cytology and physiology. By introducing specific genetic changes, scientists can engineer microbes with desirable traits, such as enhanced metabolic capabilities or the ability to produce novel compounds. This powerful tool has revolutionized research and industry, enabling the production of genetically modified organisms (GMOs) that have applications in medicine, agriculture, and environmental management.

Plant Pathology outlines how to recognize, treat, and prevent plant diseases. It covers the wide spectrum of abioticfungal, viralbacterialnematode and other plant diseases and their associated epidemiology. It also covers the genetics of resistance and modern management on plant disease, Plant Pathology focuses on understanding the diseases that affect plants, identifying the pathogens that cause these diseases, and developing strategies to manage and control them. This includes studying fungi, bacteria, viruses, nematodes, and other microorganisms that can harm plants, leading to reduced crop yields and quality. By investigating the interactions between plants and pathogens, scientists can develop resistant plant varieties, improve diagnostic techniques, and implement effective disease management practices to ensure food security and sustainable agriculture.

Microorganisms and viruses can also interact with host cells to induce alterations in cellular phenotype and function in order to subvert host cell metabolism to meet their own needs. Some microbes and viruses exert effects on the host immune response in order to evade host immune control. Understanding the interplay between infectious pathogens and their host cells is important in order to identify potential new targets for drug therapy, Microbial pathogenesis is the study of how microorganisms, such as bacteria, viruses, fungi, and parasites, cause disease in their hosts. Understanding microbial pathogenesis is crucial for developing strategies to prevent and treat infections. Pathogens employ a variety of mechanisms to colonize their hosts and evade the immune system. For instance, some bacteria produce toxins that damage host cells or disrupt normal physiological processes, while others manipulate host cell signaling to facilitate their survival and replication. Viruses often hijack host cellular machinery to replicate and spread, leading to widespread tissue damage. Fungi and parasites can cause disease by directly invading tissues or inducing inflammatory responses that contribute to host pathology.

Industrial microbiology is primarily associated with the commercial exploitation of microorganisms and involves processes and products that are of major economic, environmental and gregarious consequentiality throughout the world, Industrial microbiology focuses on the use of microbes in large-scale industrial processes, such as fermentation, to produce substances like antibiotics, enzymes, and biofuels. This discipline involves the optimization of microbial strains, fermentation conditions, and downstream processing to maximize yield and efficiency. Microbial biotechnology, on the other hand, involves the genetic manipulation of microorganisms to develop new products and processes. Techniques such as recombinant DNA technology, CRISPR, and synthetic biology are employed to enhance the capabilities of microbes, enabling the production of pharmaceuticals, biodegradable plastics, and other high-value products.

Agriculture and forest microbiology is a specialized field that delves into the roles and functions of microorganisms in agricultural and forest ecosystems. These microorganisms, including bacteria, fungi, archaea, and viruses, play vital roles in nutrient cycling, soil fertility, and plant health. In agricultural settings, soil microbiota are crucial for decomposing organic matter, fixing nitrogen, and promoting plant growth through various symbiotic relationships. For example, mycorrhizal fungi form associations with plant roots, enhancing water and nutrient uptake. Understanding these interactions is essential for developing sustainable farming practices that increase crop yields while reducing the reliance on chemical fertilizers and pesticides, In forest ecosystems, microbiology is equally important, as microbes are key players in the decomposition of organic matter, which recycles nutrients back into the soil, supporting tree growth and maintaining the health of the forest. Forest microbiomes also contribute to the resilience of forests against environmental stresses such as climate change, pests, and diseases. Research in this field aims to uncover the complex microbial networks that sustain these ecosystems and to harness beneficial microbes for forest conservation and restoration efforts. By integrating microbiological knowledge with ecological and agricultural practices, scientists and land managers can enhance biodiversity, improve ecosystem services, and promote the sustainability of both agricultural and forested landscapes.