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Metabolic Network Analysis
Biologists are faced with two fundamental questions about living systems. First if every molecule in a cell is replaced over time it is still the same cell? Secondly if every cell in an organism is replaced over time is it still the same organism? High-throughput technologies have advanced significantly and we have an understanding of the ‘wiring diagrams’ of living systems. In course you will learn about the energy requirements of living cells in biosynthesis transport of nutrients and cell maintenance. Discover the three cardinal points of bioenergetics which highlight the importance of ATP (adenosine triphosphate) in biofuel synthesis cell maintenance microbial motility and re-synthesis of macromolecules. Study the process of ATP formation from the electron transport chain (also known as phosphorylation) and the systems by which the cells overcome energy shortage under anaerobic conditions. Likewise you examine the law of mass action as well as the induction and repression models of gene regulation. Learn to distinguish between one-dimensional and two-dimensional annotations of genome sequences: the difference will help you identify the open reading frames (ORFs) gene product functions and the mathematical models (stoichiometric matrix) for representing the component interactions. Did you know that measuring the metabolic fluxes (i.e. the phenotype of the cell) is a systems biology problem? Learn how metabolic engineers adopt systems engineering methodologies for identifying the evolution of biological functions and emergent properties of cells and communities from genetic sequences.Next you will discover the ‘sense of purpose’ of every microbial cell as well as the functional states and properties of biological networks. Consider that you have many options for printing the documents you have saved in your computer system. Similar to the equivalent options in printing a document the numerous ways through which a cell can perform its various functions will be outlined. You compare and contrast the two types of biological network models to discover the strength and weaknesses of both approaches. The module on transcriptional regulatory networks will cover the three fundamental data types the associated problems with each regulatory system and their significance in cell behaviour. Study the network reconstruction process and the effects of intermediary metabolism which elaborates their regulatory structures. Additionally you will learn novel methods that will help you to properly conceptualize the four vital levels of network functions. The module on genome-scale metabolic model reconstruction examines genome annotation biochemical and physiological data identification procedures and quantitative analysis. Familiarize yourself with the steps for genome annotation and see the numerous databases where the network data can be curated and expanded.Finally the mathematical representation of reconstructed networks answers key questions like ‘What are the characteristics of the frameworks for the chemical reactions in remodelled networks?’ and ‘What does the mathematical formulation tell about the state of the biological and chemical networks?’. Discern the basic features of the stoichiometric matrix and its interconnectedness with the stoichiometric coefficients. You will also learn about network boundaries network maps and how to use multi-omics data via biotransformation to generate information from the database. See how you can differentiate determined and under-determined systems. Then the constraints which affect all living cells and the concepts of the bounded space of the stoichiometric matrix as well as subject areas in thermodynamically infeasible cycles will be discussed. Furthermore consider the four optimization methods for constraint-based reconstruction and analysis (COBRA) of metabolic networks. The systems for flux coupling finder as well as comprehensive dynamic flux balance analysis (DFBA) and gene deletion algorithm models are explained. The complex and highly technical aspects of this course have been expertly simplified to make it more exciting and rewarding for you when you take on the challenge. Enrol in this course today!
Disclaimer: Product information, including title, description, and images, is sourced/provided by our affiliate partner, Alison US CA.
Disclaimer: Some of the links on this website are affiliate links, meaning we may earn a commission if you click through and make a purchase. This comes at no additional cost to you.
By clicking the button above, you acknowledge that you will be redirected to a third-party website and agree to their terms and conditions.
Product information, including title, description, and images, is sourced/provided by our affiliate partner, Alison US CA.
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Refer a friend and earn 0.05 CEC when they click the link, plus an additional 1.00 CEC if they register. Share this Product and boost your earnings together!