Soil bacteria to produce new antibiotics

Similar documents
Centre for Personalised Medicine in Tübingen - developing tailor-made treatments for patients

CeGaT: DNA and RNA sequencing specialist

LONG-TERM BENEFITS FROM RESEARCH INTO STREPTOMYCES BACTERIA

BIO8041 BIO3030. Antimicrobial Drug Discovery

How snails can survive heat

Unit 2: Metabolism and Survival Sub-Topic (2.7) Genetic Control of Metabolism (2.8) Ethical considerations in the use of microorganisms

3. A student performed a gel electrophoresis experiment. The results are represented in the diagram below.

Unit 8.3: Biotechnology

Genetics Lecture 21 Recombinant DNA

Basic Concepts and History of Genetic Engineering. Mitesh Shrestha

2. Outline the levels of DNA packing in the eukaryotic nucleus below next to the diagram provided.

Following text taken from Suresh Kumar. Bioinformatics Web - Comprehensive educational resource on Bioinformatics. 6th May.2005

Pharmaceutical Biotechnology

At the end of this lesson you should be able to

DNA Cloning with Cloning Vectors

Patenting biotechnological inventions

Chapter 9. Biotechnology and DNA Technology

Unit 8: Genomics Guided Reading Questions (150 pts total)

Biotechnology: Unlocking Nature s Secrets

Biotech Applications Nucleic acid therapeutics, Antibiotics, Transgenics. BIT 220 End of Chapter 22 (Snustad/Simmons)

-Is the process of manipulating genes and genomes

Recombinant DNA. Lesson Overview. Lesson Overview Recombinant DNA

Plasmids & Transposable Elements. Dr. Wiaam Ahmed Al-Amili

Biotechnology: Unlocking Nature s Secrets

Hybridization - the act or process of mating organisms of varieties or species to create a hybrid. Insecticide crops

Name Per AP: CHAPTER 27: PROKARYOTES (Bacteria) p559,

Guided Notes Unit 5: Molecular Genetics

By two mechanisms: Mutation Genetic Recombination

University of Groningen. Bacterial natural products Ceniceros, Ana

Molecular Biology: Gene cloning

DNA and Biotechnology Form of DNA Form of DNA Form of DNA Form of DNA Replication of DNA Replication of DNA

Chapter 10 Microbial Genetics: New Genes for Old Germs

ADAMAS UNIVERSITY FACULTY OF SCIENCE - DEPARTMENT OF BIOTECHNOLOGY BACHELOR OF SCIENCE (Honours) SEMESTER - I

Genome Sequence Assembly

Duncanrig Secondary School

Refresher on gene expression - DNA: The stuff of life

2 nd year Medical Students - JU Bacterial genetics. Dr. Hamed Al Zoubi Associate Professor of Medical Microbiology. MBBS / J.U.S.

CHAPTER 2A HOW DO YOU BEGIN TO CLONE A GENE? CHAPTER 2A STUDENT GUIDE 2013 Amgen Foundation. All rights reserved.

Bayer Pharma s High Tech Platform integrates technology experts worldwide establishing one of the leading drug discovery research platforms

Lecture 3 (FW) January 28, 2009 Cloning of DNA; PCR amplification Reading assignment: Cloning, ; ; 330 PCR, ; 329.

Molecular Biology: DNA sequencing

Pharmacogenetics: A SNPshot of the Future. Ani Khondkaryan Genomics, Bioinformatics, and Medicine Spring 2001

Biosc10 schedule reminders

12/31/16. I. Manipulating DNA (9.1) A. Scientists use several techniques to manipulate DNA. 1. DNA is a very large molecule

Introduction to BIOINFORMATICS

UNIT 3: GENETICS Chapter 9: Frontiers of Biotechnology

STUDY GUIDE SECTION 13-1 DNA Technology

AGRO/ANSC/BIO/GENE/HORT 305 Fall, 2016 Overview of Genetics Lecture outline (Chpt 1, Genetics by Brooker) #1

Genome research in eukaryotes

Ribotyping Easily Fills in for Whole Genome Sequencing to Characterize Food-borne Pathogens David Sistanich

Alternative CRISPR system could improve genome editing

Origins of Biotechnology

National Health Research Institutes

13-2 Manipulating DNA Slide 1 of 32

Microbial Biotechnology agustin krisna wardani

DNA recombination without ligase: TOPO TA Cloning. topoisomerase

Texas A&M University-Corpus Christi CHEM4402 Biochemistry II Laboratory Laboratory 4 - Polymerase Chain Reaction (PCR)

Introduction to Bioinformatics

2014 Pearson Education, Inc. CH 8: Recombinant DNA Technology

Examination Assignments

Department of Genetics

Gene Cloning and DNA Analysis: An introduction

Regulation of enzyme synthesis

Genetics and Biotechnology 13.2 DNA Technology

RISK ASSESSMENT OF GENETICALLY MODIFIED MICRO-ORAGNISMS: A FORMAT THAT OFFERS ONE POSSIBLE WAY OF ACHIEVING GOOD PRACTICE

The Institute of Microbiology of the Czech Academy of Sciences is looking for. four POSTDOCTORAL FELLOW positions in the fields of:

The Integrated Biomedical Sciences Graduate Program

Bioscientists Do you have the Bayer Spirit?

THE BENEFITS AND USES OF MICROBES

DEPARTMENT: MICROBIOLOGY PROGRAMME: B SC. Statements of Programme Specific Outcomes (PSOs)

Mutagenesis for Studying Gene Function Spring, 2007 Guangyi Wang, Ph.D. POST103B

CH 8: Recombinant DNA Technology

Department of Biology and Biotechnology. Student name:, Student No.

Biotechnology and DNA Technology

Marineinspired Oncology

Biotechnology. Chapter 20. Biology Eighth Edition Neil Campbell and Jane Reece. PowerPoint Lecture Presentations for

Synthetic Biology. Sustainable Energy. Therapeutics Industrial Enzymes. Agriculture. Accelerating Discoveries, Expanding Possibilities. Design.

Chapter 8: Recombinant DNA. Ways this technology touches us. Overview. Genetic Engineering

Pristinamycin. Damocles 2015

7.1 Techniques for Producing and Analyzing DNA. SBI4U Ms. Ho-Lau

NEW DRUG FORMULATIONS TO BOOST FIGHT AGAINST RESPIRATORY ILLNESSES AND ANTIBIOTIC-RESISTANT SUPERBUGS

Experiment 9: Isolation, Characterization and Identification of Antibiotic Producing Bacteria

BIOTECHNOLOGY. Biotechnology is the process by which living organisms are used to create new products THE ORGANISMS

NB536: Bioinformatics

BIOTECHNOLOGY. Sticky & blunt ends. Restriction endonucleases. Gene cloning an overview. DNA isolation & restriction

Course Agenda. Day One

Motivation From Protein to Gene

B. Incorrect! Ligation is also a necessary step for cloning.

9.4. Genetic Engineering. Entire organisms can be cloned. Web

Department of Systems Biotechnology

CHAPTER 9: GENETIC ENGINEERING DR. BERTOLOTTI

Lecture Series 10 The Genetics of Viruses and Prokaryotes

Reading Lecture 3: 24-25, 45, Lecture 4: 66-71, Lecture 3. Vectors. Definition Properties Types. Transformation

Lesson Overview. Studying the Human Genome. Lesson Overview Studying the Human Genome

5.) Name and describe one gene product in E.coli that is associated with performing each step in the recombination process. (6pts)

Lecture Four. Molecular Approaches I: Nucleic Acids

Antimicrobial Peptides

- Selection of Target Molecular for Drug Discovery by Verifications on the Validity of Target Candidates -

Enzyme that uses RNA as a template to synthesize a complementary DNA

Marineinspired Oncology

Transcription:

Powered by Website address: https://www.gesundheitsindustriebw.de/en/article/news/soil-bacteria-to-produce-newantibiotics/ Soil bacteria to produce new antibiotics An ever-growing number of genomes of soil bacteria of the genus Streptomyces are being sequenced. Using a method known as genome mining, researchers at the University of Tübingen are working on the identification of gene clusters that have the potential to be used in industrial biotechnology for the production of new antibiotics and other pharmaceutically active substances. To achieve this, the biosynthesis gene clusters are integrated into special production strains where they are optimized. Antibiotics have been a medical success story ever since they were first used. However, many antibiotics have become less effective as more and more bacterial pathogens are becoming resistant to antibiotic treatment. There is an immanent need for new antibiotics due to the large number of bacteria that have evolved resistance to antibiotics. However, far too few new antibiotics have been developed over the last decades. And this discrepancy has become one of the major problems in pharmaceutical research, said Prof. Dr. Lutz Heide from the Pharmaceutical Institute at the University of Tübingen. Heide is one of several researchers around the world who focus intensively on the discovery and development of new antibiotic substances with the aim of closing the gap in effective antibacterial treatments. Heide has been working with Prof. Dr. Wolfgang Wohlleben from the Interfaculty Institute for Microbiology and Infection Medicine at the University of Tübingen for many years. The two scientists share a common interest in the use of soil bacteria, the Streptomyces species in particular, as sources of antibiotics. In addition, they are working jointly to intensify research into anti-infective drugs in Tübingen, and to this end they are also involved in the establishment of the German Centre for Infection Research in Tübingen. 1

Prof. Dr. Lutz Heide from the Institute of Pharmacy at the University of Tübingen works intensively with European colleagues in the development of new drugs. private 2

Prof. Dr. Wohlleben is the spokesperson of the DFG-funded The bacterial cell envelope: structure, function and infection interface collaborative research centre, in which Prof. Dr. Lutz Heide is also involved. private Streptomycetes as antibiotics producers classics with huge potential Streptomyces - a promising source of drugs. Paas, Tübingen Soil bacteria have long been potent antibiotics producers. This comes as no surprise due to their ability to live in a relatively heterogeneous environment: bacteria in soil have to withstand changing, sometimes rather extreme environmental conditions, and are also faced with a broad range of enemies and competitors. Bacteria have therefore evolved a plethora of biosynthesis pathways that enables them to produce antibiotic substances; they have developed a sophisticated regulatory system with genetic and epigenetic components to produce effective substances for fighting off enemies. In their investigation of the biosynthesis genes and their complex regulation in Streptomyces, the Tübingen researchers benefit greatly from the progress made in DNA sequencing technologies. Streptomyces are the most successful producers of antibiotics and have been studied in great detail. The sequenced genomes reveal that Streptomyces species are able to synthesize between 15 and 35 different antibiotics, including substances we ve never seen before, said Heide. Considering the fact that a large number of soil bacteria exist and that only around 0.3 per cent of them have been subject to laboratory investigations, there is still a huge number of antibacterial substances to be discovered. The European ERA-IB programme brings together international expertise As part of the ERA-IB framework, which fosters innovation in industrial technology, the European Union is supporting Heide and Wohlleben over the next three years in their effort to discover new antibiotics and potentially also other drugs and make them suitable for medical applications. The Tübingen researchers are involved in two large cooperative projects dealing with drugs produced by Streptomyces bacteria. The projects focus on different steps in the utilization scale and therefore complement each other perfectly, said Heide. Prof. Heide is the coordinator of the GenoDrug project. As is a common requirement for EU 3

projects, the project also involves partners from several EU countries. GenoDrug brings together gene regulation experts from Poland and the Netherlands, Spanish scientists who are specialists in testing the efficacy of new substances and in developing molecular genetic strategies for optimizing bioproduction. A team from Finland, which also has a large number of medium-scale fermenters in which optimized Streptomyces strains can be cultured, contributes its process know-how to the project. The major goal of the GenoDrug team is to develop a method that allows them to activate silenced gene clusters that contain the construction plans for interesting antibiotics and potentially also for other drugs to be used in the treatment of cancer, amongst other things. These gene clusters will be optimized and integrated into production strains. So in principle, the project is all about creating a new drug development technology. We want to analyze the bioactivity and toxicity of the substances identified using the genome mining method and then produce the substances in the milligramme scale, said Heide explaining their ambitious goal. Bioproduction of anti-infectives and anti-tumour drugs will be optimized The second collaborative project, IMMUNOTEC, is being coordinated by Prof. Dr. Juan-Francisco Martin from INBIOTEC, a biotechnology institute in the Spanish city of Leon. In addition to the teams led by Heide and Wohlleben, the project also involves a Spanish SME that produces antibiotics. The project focuses on known drugs that can be produced with Streptomyces species tacrolimus and ascomycin. These two substances are effective immunosupressants and are used, amongst other things, to prevent rejection of organ transplants. Further developments of these substances also have huge potential for tumour treatment. The patent relating to the production of tacrolimus has recently expired, which is one of several reasons why we have included this substance in our research programme, said Heide. The project partners plan to develop Streptomyces production strains that enable the production of larger quantities of pharmaceutically active substances at a considerably lower price. In order to achieve such goals, random mutagenesis is the method of choice for changing the genetic information of an organism in a stable manner, resulting in mutations. We hope that our methods, which target the regulation of gene expression, will enable us to achieve our objectives more quickly. We also intend to optimize the methods for our specific purposes. In order to do this, we will integrate the gene clusters of interest into other bacteria. We will use the same genus of bacteria, but another species, for example Streptomyces griseus, as production strain," said Heide. Sophisticated molecular biology and genetic engineering are key Something that appears to be relatively easy thanks to the availability of innovative genetic engineering methods is nevertheless associated with quite a few pitfalls. Heide explains, The gene clusters we are dealing with are around 100 kb in size, which makes them difficult to clone. We need to produce clones that contain the inserts of several plasmids. And we also work with artificial bacterial chromosomes, which are far from easy to handle. Another challenge is to integrate the huge clusters stably into the production strain. This is why we want to optimize the rest of the bacterial metabolism for our purposes, for example the 4

The DNA of Streptomyces bacteria will be recombined in order to produce new antibiotics with biotechnological means. Paas, Tübingen nitrogen- and phosphate-dependent regulatory pathways, said Heide. Such sophisticated and complex relationships can only be achieved using bioinformatic methods. Both projects rely on bioinformatic methods in order to deal with and interpret the huge amount of data produced. In the medium term, the research will use metabolism models and simulations to help them advance their laboratory work. Further information: University of Tübingen Pharmaceutical Institute Prof. Dr. Lutz Heide Auf der Morgenstelle 8 72076 Tübingen Tel.: +49 (0)7071/ 29 72 460 E-mail: heide(at)uni-tuebingen.de 5

Article 19-Mar-2012 leh BioRegio STERN BIOPRO Baden-Württemberg GmbH The article is part of the following dossiers Biopharmaceuticals continue their triumphant success Industrial biotechnology biological resources for industrial processes 6

2024 © businessdocbox.com Privacy Policy | Terms of Service | Feedback