Genome Sequencing (Bioinformatics II)

Course Feature
  • Cost
    Free
  • Provider
    Coursera
  • Certificate
    Paid Certification
  • Language
    English
  • Start Date
    24th Jul, 2023
  • Learners
    No Information
  • Duration
    No Information
  • Instructor
    Pavel Pevzner and Phillip Compeau
Next Course
5.0
4,436 Ratings
Discover the power of genome sequencing and learn how to apply graph theory and brute force algorithms to assemble genomes and identify antibiotics. Join this course to explore the potential of personalized medicine and learn how to sequence the genome of a deadly Staphylococcus bacterium.
Show All
Course Overview

❗The content presented here is sourced directly from Coursera platform. For comprehensive course details, including enrollment information, simply click on the 'Go to class' link on our website.

Updated in [June 30th, 2023]

Genome Sequencing (Bioinformatics II) is a course that explores the use of graph theory and brute force algorithms to sequence genomes and antibiotics. In the first half of the course, students will learn how to assemble genomes from short pieces of DNA using graph theory. In the second half, students will learn how to apply brute force algorithms to identify naturally occurring antibiotics. Finally, students will apply popular bioinformatics software tools to sequence the genome of a deadly Staphylococcus bacterium that has acquired antibiotics resistance.

[Applications]
Upon completion of this course, students will be able to apply the concepts of graph theory and brute force algorithms to the sequencing of genomes and antibiotics. They will also be able to use popular bioinformatics software tools to sequence the genome of a deadly Staphylococcus bacterium that has acquired antibiotics resistance.

[Career Paths]
[Job Position Path]Genome Sequencing Bioinformatician
[Description]Genome sequencing bioinformaticians are responsible for analyzing and interpreting the data generated from sequencing a genome. They use a variety of software tools and algorithms to assemble the fragments of DNA into a complete genome sequence. They also use bioinformatics software to identify and analyze genes, proteins, and other biological features. Genome sequencing bioinformaticians must have a strong understanding of biology, genetics, and computer science.

[Development Trend]The demand for genome sequencing bioinformaticians is expected to grow as the field of personalized medicine advances. As more and more genomes are sequenced, the need for bioinformaticians to analyze and interpret the data will increase. Additionally, the development of new software tools and algorithms to improve the accuracy and speed of genome sequencing will create more opportunities for bioinformaticians.

[Education Paths]
The recommended educational path for learners interested in genome sequencing and bioinformatics is to pursue a degree in bioinformatics. This degree typically requires a bachelor's degree in a related field such as biology, computer science, or mathematics. The degree program will cover topics such as molecular biology, genetics, computer science, and mathematics. Students will learn how to use bioinformatics software tools to analyze and interpret biological data. They will also learn how to develop algorithms and models to solve biological problems. Additionally, they will gain an understanding of the ethical and legal implications of bioinformatics.

The development trend of bioinformatics degrees is to focus on the application of data science and machine learning to biological problems. This includes the use of artificial intelligence and machine learning to analyze large datasets, as well as the development of algorithms to predict the behavior of biological systems. Additionally, bioinformatics degrees are increasingly focusing on the ethical and legal implications of bioinformatics, as well as the development of new technologies to improve the accuracy and speed of data analysis.

Show All
Recommended Courses
free comparing-genes-proteins-and-genomes-bioinformatics-iii-2170
Comparing Genes Proteins and Genomes (Bioinformatics III)
5.0
Coursera 2,703 learners
Learn More
This course will explore the fascinating world of bioinformatics, teaching you how to compare genes, proteins, and genomes. Learn powerful algorithmic tools such as dynamic programming and combinatorial algorithms to determine the number of mutations that have separated two genes/proteins. Discover how genome rearrangements have shaped the evolution of species, and apply popular bioinformatics software tools to solve sequence alignment problems. Join us and explore the world of bioinformatics!
learn-bioinformatics-from-scratch-theory-practical-2171
Learn Bioinformatics From Scratch (Theory & Practical)
4.2
Udemy 5,661 learners
Learn More
This Bioinformatics course is the perfect way to develop the skills needed to handle the explosion of biological data. It covers five modules, from databases to evolutionary bioinformatics, with a unique blend of theory and practical. With 93 lectures, 19 practical tutorials, 12 assignments and 5 quizzes, this course will give you the knowledge and confidence to tackle the high biological data. After taking this course, you will have a different perspective on biological data and be ready to take on research, academia and industry in the coming years. Don't miss out on this opportunity to learn Bioinformatics from scratch!
drug-design-and-molecular-docking-by-using-computation-tools-2172
Drug Design and Molecular Docking by using computation Tools
3.4
Udemy 14,442 learners
Learn More
This course is designed to help science students become proficient in the field of drug discovery and development simulation studies. It covers the basics of computer-aided drug design (CADD) and molecular docking, including how to install the Molecular Docking Environment (MOE) and retrieve ligands from bioinformatics databases. Students will learn how to perform molecular docking, 2D and 3D molecule interactions, and use the AutoDock software to solve a real-world problem. The course also covers the use of MOE software to study naturally occurring compounds, antivirals, antifungals, anti-nematodes, and anti-protozoal drugs. Sign up now to learn the fundamentals of drug design and molecular docking and gain the skills to solve real-world problems.
learn-dna-primer-design-for-polymerase-chain-reaction-2173
Learn DNA Primer Design for Polymerase Chain Reaction
3.6
Udemy 13,469 learners
Learn More
This Bioinformatics course will teach you how to design DNA primers for Polymerase Chain Reaction (PCR). You will learn the steps of PCR, the specifications of primer design, and how to use Primer BLAST and Primer3 to design primers for single- or multi-insert cloning or for site-directed mutagenesis experiments. With this course, you will be able to design primers with the right GC content, length, and melting temperature to ensure accurate and efficient DNA amplification. Click now to learn the fundamentals of DNA primer design for PCR!
Favorites (0)
Favorites
0 favorite option

You have no favorites

Name delet