Warm-Up What is bacterial transformation?. Plate 28 Bacterial Conjugation.

Slides:

Advertisements

Similar presentations

Genetic Transfer & Recombination In Bacteria

Advertisements

Ch. 27 Bacteria and Archaea

III. Linkage A. ‘Complete’ Linkage B. ‘Incomplete’ Linkage C. Three-point Mapping - combine complementary sets Three Point Test Cross AaBbCc x aabbcc Phenotypic.

Bacterial genetics.

Chapter 18 Genetics of Viruses and Bacteria. Viruses: are much smaller than bacteria consist of a genome in a protective coat reproduce only within host.

Microbial genetics.

Bacterial Genetics1 (Chapter 7) The beginning of Chapters 7 is largely a review of topics covered in Biol 131, and our focus will be on the sections beginning.

1 Donor cell attaches to a recipient cell with its pilus. The pilus draws the cells together. Chromosome F plasmid Conjugation pilus F + cellF – cell.

Genetics of Bacteria. Bacterial Chromosomes One double-stranded, circular molecule of DNA. Found in nucleoid region, which is a dense region of DNA. Many.

2 and 4 February, 2005 Chapter 7 Recombination in Bacteria and their Viruses Conjugation, transformation, transduction.

6/15/2015 The Genetics of Bacteria. 6/15/2015 The Genetics of Bacteria The major component of the bacterial genome is one double-stranded, circular DNA.

7 The Genetics of Bacteria and Their Viruses. 2 3 Plasmids Many DNA sequences in bacteria are mobile and can be transferred between individuals and among.

Microbial Genetics (Micr340) Lecture 8 Conjugation and Transformation.

Changes in bacterial traits Caused by: Changes in environmental conditions (only phenotypic changes) Changes in the genetic codes 1- Intermicrobial exchange.

Bacterial Genetics (Ch18) Bacteria –One of the simplest genetic model systems to study the mechanisms of molecular genetics Escherichia coli (E. coli)

Competent cells formation and transformation of competent cells with DNA. BCH 462 [practical] 2 nd lab.

Genetic transfer and recombination

Ch. 27 Warm-Up 1. What was Frederick Griffith’s contribution to our understanding of DNA? (Refer back to Ch. 16) 2. How do bacteria replicate?

Topic 6 Growth & Reproduction of Bacteria

Recombinant Plasmids.

Biotechnology Unit: Increasing Variation through DNA Transfer

Lecture 7 Microbial Genetics: Genetic Mutations Gene Transfer.

The exchange of Genetic Material between bacteria or How bacteria acquire resistance to antimicrobial agents in nature.

Changes in bacterial traits Caused by: Changes in environmental conditions (only phenotypic changes) Changes in the genetic codes 1- Intermicrobial exchange.

Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Fig. 18.2a & b.

CHAPTER 5 The Genetics of Bacteria and Their Viruses CHAPTER 5 The Genetics of Bacteria and Their Viruses Copyright 2008 © W H Freeman and Company.

Shatha Khalil Ismael. Transformation Certain species of Gram- negative, gram- positive bacteria and some species of Archaea are transformable. The uptake.

The Genetics of Bacteria. Circular DNA o ` Circular DNA - double stranded aka. its chromosome in nucleoid Bacterial Genome: Plasmid o Plasmid - small.

Bacterial Gene Transfer. Bacterial Gene Exchange General scheme of bacterial exchange of DNA. DNA from a donor cell is transferred to a recipient cell.

Chapter 8 – Bacterial and Viral Genetic Systems

1 Sharing of genetic information Bacteria are successful because 1.They carefully regulate their use of energy in metabolic processes by shutting down.

Chapter 8 Outline 8.1 Genetic Analysis of Bacteria Requires Special Approaches and Methods, Viruses Are Simple Replicating Systems Amenable to.

The Genetics of Bacteria and Their Viruses

Bacterial Genetics & Transformation

SC.912.L  In Eukaryotes: gene transfer only from parent to offspring during sexual reproduction (pre technology)  In Prokaryotes: genetic transfer.

Genetic Transfer and Recombination in Bacteria

Exchange of Genetic Information

Bacterial Genetics.

 Learning Outcomes  To compare the mechanism of genetic recombination in bacteria  To describe the function of plasmids and transposons.

Gene Transfer. Gene transfer in bacteria There are three types of gene transfer 1.Transformation 2.Conjugation 3.Transduction.

Bacterial and Viral Genetic Systems Part I Ch. 8 Ebola virus Cholera bacteria H. pylori.

Batterjee Medical College. Ass. Prof. Dr. Manal El Said Department Head of Microbiology Bacteria Genetics.

Genetic Engineering Genetic engineering involves the manipulation of organism genes. The central tool is the recombinant DNA technique. - to isolate a.

Bacteria Genetics Bacteria Genetics Introduction Chromosome (bacteria are haploid; in other words, they have a single chromosome) Chromosome (bacteria.

Recombination In Bacteria. Genetic recombination - transfer of DNA from one organism (donor) to another recipient. The transferred donor DNA may then.

The Genetics of Bacteria

Bacterial Genetics.

Cell Transformation Recombinant DNA Host Cell DNA Target gene Modified Host Cell DNA.

Copyright © 2011 Pearson Education Inc. Lecture prepared by Mindy Miller-Kittrell, University of Tennessee, Knoxville M I C R O B I O L O G Y WITH DISEASES.

Genetics Chapter 4. INTRODUCTION ● The genetic material of Escherichia coli, consists of a single circular DNA molecule is composed of approximately 5.

Bacteria CHAPTER 27. You must know  The key ways in which prokaryotes differ from eukaryotes with respect to genome, membrane- bound organelles, size,

Bacteria. Bacterial Structure A. Contain: 1. Cell wall 2. plasma membrane 3. Cytoplasm 4. Ribosomes (smaller than eukaryotic ribosomes and differ in protein.

Chapter 18.1 Contributors of Genetic Diversity in Bacteria.

Bacterial Conjugation

Ch. 27 Warm-Up What was Frederick Griffith’s contribution to our understanding of DNA? (Refer back to Ch. 16) How do bacteria replicate?

TRANSFERIMIENTO LATERAL DE GENES

The Genetics of Bacteria

CHAPTER 12 DNA Technology and the Human Genome

13-3 Cell Transformation Interactive pgs. 329.

This Week Score Conjugation Plates,

Ch. 27 Warm-Up What was Frederick Griffith’s contribution to our understanding of DNA? (Refer back to Ch. 16) How do bacteria replicate?

Ch. 24 Warm-Up What was Frederick Griffith’s contribution to our understanding of DNA? (Refer back to Ch. 16) How do bacteria replicate?

Chapter 13.3 Cell Transformation.

Ch. 27 Warm-Up What was Frederick Griffith’s contribution to our understanding of DNA? (Refer back to Ch. 16) How do bacteria replicate?

Bacteria Chapter 27.2.

III. Bacteria- heterotrophic, prokaryotic organisms

Ch. 27 Warm-Up What was Frederick Griffith’s contribution to our understanding of DNA? (Refer back to Ch. 16) How do bacteria replicate?

The Genetics of Bacteria

What do you already know about bacteria?

This Week Score Conjugation Plates,

Presentation transcript:

Warm-Up What is bacterial transformation?

Plate 28 Bacterial Conjugation

Gene Sharing Transformation – genetic information passed indirectly from one bacterium to another –Cell  Extracellular fluid  Cell Conjugation – genetic information passed directly from one bacterium to another –Requires cell-to-cell contact

What do you think? How can the sharing of genes benefit bacteria?

Conjugation Vocabulary 2 types of bacteria: F(+) bacteria are able to donate DNA F(-) bacteria are able to receive DNA

Plasmids Plasmid: double-strand loop of DNA, consists of about 20 genes (also called the “fertility factor” or “F factor”)

Plasmid Transfer F(+) bacteria extends and attaches its sex pilus to the F(-) bacteria

Plasmid Transfer F(+) bacteria creates a duplicates its plasmid (called a “daughter F factor”) The new plasmid is transferred to the F(-) bacteria through the sex pilus The F(-) bacteria now becomes F(+)

Plasmid Transfer F(+) F(-)

Plasmid Transfer F(+) F(-)

Plasmid Transfer F(+)

The plasmid (“F factor”) becomes integrated with the F(+) bacteria’s chromosome F(+) bacteria is now known as a “high frequency of recombination” cell (“Hfr” for short) Chromosome Transfer – 1 st Step

Hfr cell

Chromosome Transfer - 2 nd Step Just like in plasmid transfer, the Hfr cell approaches a F(-) cell and extends its sex pilus, creating a conjugation bridge A single strand of the combined DNA is duplicated

Chromosome Transfer - 2 nd Step

Chromosome Transfer – 3 rd Step The F(-) cell removes an equal amount of its DNA and inserts the new Hfr DNA strand into its chromosome F(-) is now known as a recombinant F(-) cell

Chromosome Transfer – 3 rd Step

Chromosome Transfer Hfr cells are formed when the F factor integrates into the bacterial chromosome. This integration occurs at a random location.

Chromosome Transfer The Hfr cell is still able to initiate conjugation with an F(-) cell.

Chromosome Transfer When DNA transfer begins, the Hfr cell tries to transfer the entire bacterial chromosome to the F- cell. The first DNA to be transferred is chromosomal DNA, and the last DNA to be transferred will be the F factor DNA.

Chromosome Transfer Transfer of the bacterial chromosome is almost never complete. Pili are fairly fragile structures, and shear forces tend to break the pilus, disrupting DNA transfer before the entire chromosome can be transferred. As a result, the F factor itself is rarely transferred to the recipient cell.

Benefits of Bacterial Conjugation Bacteria can easily transfer beneficial genes within a population, such as antibiotic resistance More common in Gram-negative bacteria

ations/conjugation/conj_frames.htmhttp:// ations/conjugation/conj_frames.htm

Transformation vs. Conjugation