Chromosomal Landscapes

Slides:

Advertisements

Similar presentations

Chapter 6 DNA  Consists of Deoxyribose sugar Phosphate group A, T, C, G  Double stranded molecule (Double Helix) Two strands of DNA run antiparallel.

Advertisements

Chromosome Structure In prokaryotes, DNA molecules are contained in cytoplasm and consists mainly of a ring of DNA and associated proteins. Eukaryotic.

From gene to protein DNAPhenotype RNA ReplicationTranscription *Transcription Translation *Translation *Gene The flow of information: 1. Storage 2. Replication.

DNA REPLICATION. DNA copying Each cell division cell must copy its entire DNA So each daughter cell gets a complete copy Rate of synthesis –Bacteria =

Biological Information Flow

Chromosomal Landscapes Refer to Figure 1-7 from Introduction to Genetic Analysis, Griffiths et al., 2012.

Relationship between Genotype and Phenotype

DNA Replication Part 2 Enzymology. Figure The Polymerization Reaction.

Molecular Biochemistry (Bioc432) Part 2 Dr. Hani Choudhry

AP Biology DNA Replication Ch.12.2 AP Biology DNA Replication  Purpose: cells need to make a copy of DNA before dividing so each daughter.

DNA Replication. What is DNA replication? When does it happen? DNA replication is the process by which the DNA molecule duplicates itself to create identical.

DNA Replication Lecture 7. DNA Replication  Synthesis of two new DNA duplexes based on complementary base sequences with parental DNA.  Is progressive,

Molecular Genetics 2: DNA Replication WHAT IS DNA REPLICATION? The process of making two identical DNA molecules from an original, parental DNA molecule.

16.2 DNA Replication. DNA in Prokaryotes and Eukaryotes Prokaryotes: –ring of chromosome –holds nearly all of the cell’s genetic material.

Chapter 25 DNA Metabolism Replication, Repair and Recombination Semiconservative DNA replication Each strand of DNA acts as a template for synthesis of.

DNA REPLICATION SBI4U Ms. Manning. DNA Replication  Produces two identical copies of the chromosome during S phase of interphase  Catalyzed by many.

Beyond Mendel - the molecular basis of inheritance, and DNA biology 1.

© 2012 Pearson Education, Inc DNA Is Reproduced by Semiconservative Replication.

DNA REPLICATION. What does it mean to replicate? The production of exact copies of complex molecules, such as DNA molecules, that occurs during growth.

Chapter 16 DNA Replication. Base Pairing A forms 2 H bonds with T G forms 3 H bonds with G In RNA, A forms 2 H bonds with U Complimentary strands Anti-parallel.

2A. Distinguish between DNA and RNA.

DNA Replication Robert F. Waters, Ph.D.. Goals:  What is semi-conservative DNA replication?  What carries out this process and how?  How are errors.

Chromosomal Landscapes Refer to Figure 1-7 from Introduction to Genetic Analysis, Griffiths et al., 2012.

From DNA to Protein Chapter 8. Terminology Genetics Genome Chromosome Gene Locus Alleles Genotype/Phenotype Heredity.

DNA Replication Lecture 11 Fall Read pgs

DNA Replication When/why do cells need to replicate (copy) DNA? Growth Reproduction Repair Where do we start? Replication origin – a specific sequence.

DNA replication Chapter 16. Summary of history Griffith Mice & Strep Transformation External DNA taken in by cell.

Replication in Prokaryotes Chapter 6 part II. DNA replication DNA replication is semiconservative The two strands of DNA unwind with the help of DNA helicase.

DNA Replication. II- DNA Replication II- DNA Replication Origins of replication Origins of replication Replication ForkshundredsY-shaped replicating DNA.

DNA Replication Lecture 10 Dr. Attya Bhatti. Mechanism of DNA replication In E-Coli In the late 1950s, Arthur Kornberg successfully identified and purified.

INTERACTIVE NOTES PGS CHROMOSOMES & DNA REPLICATION.

Biosynthesis of Nucleic Acids: Replication Feb. 25, 2016 CHEM 281.

Chapter 16 Molecular Basis of Inheritance. Brainstorm What have we already learned about DNA this semester?

DNA Replication-III 28/04/2017.

Do Now  What is replication?  Where does this take place?

DNA Replication How does each cell have the same DNA? How is a prokaryote different than a eukaryote?

DNA Replication the big event during S phase. The Animation hill.com/sites/ /student_view0/chapter14/animations.html#

DNA Synthesis DNA Synthesis in General

Relationship between Genotype and Phenotype

Relationship between Genotype and Phenotype

DNA Replication.

DNA Replication (II) 王之仰.

BIOLOGY 12 DNA Replication.

Relationship between Genotype and Phenotype

DNA Replication.

WHY DNA Replication? DNA replicates to make duplicate copies for cell division DNA replication occurs during S (synthesis) of Interphase of cell cycle.

2A. Distinguish between DNA and RNA.

DNA Structure & Replication

Happy Hump Day!.

DNA REPLICATION.

2A. Distinguish between DNA and RNA.

Copying the genetic blueprint

DNA Replication.

Chapter 12 Sections 1 and 2 only

DNA Replication.

BioFlix® DNA Replication Slide Show

Chromosomal Landscapes

DNA REPLICATION AND REPAIR

BIOLOGY 12 DNA Replication.

DNA Chromosomes and Replication

KEY CONCEPT DNA replication copies the genetic information of a cell.

DNA REPLICATION.

DNA REPLICATION.

KEY CONCEPT DNA replication copies the genetic information of a cell.

BioFlix® DNA Replication Slide Show

DNA replication Chapter 16.

DNA and RNA structure The painting “Dawn of the Double Helix” composes the DNA duplex as human figures. The theme in this painting is “Life forms: The.

DNA Replication.

Dna replication SBI4U.

Relationship between Genotype and Phenotype

Presentation transcript:

Chromosomal Landscapes Refer to Figure 1-7 from Introduction to Genetic Analysis, Griffiths et al., 2012.

Human Chromosomal Landscapes Refer to Figure 1-8 from Introduction to Genetic Analysis, Griffiths et al., 2012.

Relationship between Genotype and Phenotype Molecular Basis for Relationship between Genotype and Phenotype genotype DNA DNA sequence transcription replication RNA translation amino acid sequence protein function phenotype organism

DNA replication is discontinuous. Replication of DNA is semiconservative. Each strand serves as a template. The two strands separate from each other when hydrogen bonds are broken. Replication of DNA is semiconservative. Each strand serves as a template. The two strands separate from each other when hydrogen bonds are broken. New strands are synthesized by the addition of nucleotides with bases complementary to those of the template. DNA replication is discontinuous. Two identical double helices result. New strands are synthesized by the addition of nucleotides with bases complementary to those of the template. DNA replication is discontinuous. Two identical double helices result. Refer to Figure 7-11 from Introduction to Genetic Analysis, Griffiths et al., 2012.

DNA polymerization requires DNA polymerase. Refer to Figure 7-15 from Introduction to Genetic Analysis, Griffiths et al., 2012.

At least 5 DNA polymerases are known in E. coli . DNA polymerase I (pol I): adds nucleotides in 5’ to 3’ direction removes mismatched bases in 3’ to 5’ direction degrades double-stranded DNA in 5’ to 3’ direction DNA polymerase II (pol II): repairs interstrand cross-links DNA polymerase III (pol III): catalyzes DNA synthesis at replication fork in 5’ to 3’ direction and only adds nucleotides at 3’ end of growing strand

Overview of DNA Synthesis DNA polymerases synthesize new strands in 5’ to 3’ direction. Primase makes RNA primer. Lagging strand DNA consists of Okazaki fragments. In E. coli, pol I fills in gaps in the lagging strand and removes RNA primer. Fragments are joined by DNA ligase.

DNA Replication at Growing Fork DNA polymerases add nucleotides in 5’ to 3’ direction. Because of antiparallel nature, synthesis of DNA is continuous for one strand and discontinuous for the other strand.

DNA Replication: Synthesis of Lagging Strand Several components and steps are involved in the discontinuous synthesis of the lagging strand. Note that DNA polymerases move in 3’ to 5’ direction on the template DNA sequence.

DNA Replication: Synthesis of Lagging Strand DNA extended from primers are called Okazaki fragments. In E. coli, pol I removes RNA primers and fills in the gaps left in lagging strands. DNA ligase joins these pieces.

Replisome and Accessory Proteins Looping of template DNA for the lagging strand allows the two new strands to be synthesized by one dimer. pol III holoenzyme is a complex of many different proteins. Refer to Figure 7-20 from Introduction to Genetic Analysis, Griffiths et al., 2012.

DNA polymerases can extend (but cannot start) a chain. Priming DNA Synthesis DNA polymerases can extend (but cannot start) a chain. Primase enzyme makes short RNA primer sequence complementary to template DNA. DNA polymerase extends RNA primer with DNA. Primosome is a set of proteins that are involved in the synthesis of RNA primers. Refer to Figure 7-20 from Introduction to Genetic Analysis, Griffiths et al., 2012.

Supercoiling results from separation of template strands during DNA replication.

Helicases and Topoisomerases Helicase enzymes disrupt hydrogen bonding between complementary bases. Single-stranded binding protein stabilizes unwound DNA. Unwound condition increases twisting and coiling, which can be relaxed by topoisomerases (such as DNA gyrase). Topoisomerases can either create or relax supercoiling. They can also induce or remove knots.

Nucleosome assembly follows thereafter. Chromatin assembly factor I (CAF-I) and histones are delivered to the replication fork. CAF-I and histones bind to proliferating cell nuclear antigen (PCNA), the eukaryotic version of clamp protein. Nucleosome assembly follows thereafter. Refer to Figure 7-23 from Introduction to Genetic Analysis, Griffiths et al., 2012.

Overview of DNA Synthesis DNA polymerases synthesize new strands in 5’ to 3’ direction. Primase makes RNA primer. Lagging strand DNA consists of Okazaki fragments. In E. coli, pol I fills in gaps in the lagging strand and removes RNA primer. Fragments are joined by DNA ligase.