Chapter 33 Flashcards
DNA – Deoxyribonucleic Acid
DNA = the molecule for genetic material in our cells. The DNA in cells is the genetic information that is passed from one generation to another
Deoxyribose = ribose where 2’-hydroxyl is replaced w/ a hydrogen
DNA is composed of 4 nucleotides:
- Adenine and guanine (purines)
- Cytosine and thymine (pyrimidines)
- Bases are attached to carbon atom 1’ in the sugar
DNA forms a double helix of two separate strands w/ complementary sequences
Semiconservative replication = two strands unwind, each serves as a template for the new daughter double helix
- During replication: proof-reading and repair mechanisms
For DNA and RNA, the backbone consists of sugars linked by phosphodiester bridges between 3’-hydroxyl of one sugar and 5’-hydroxyl of an adjacent sugar
- The phosphodiester linkage in the backbone and the associated carbons give the directionality of the DNA strand
RNA – Ribonucleic Acid
Ribonucleic acid (RNA) also contains the sugar ribose
RNA = single stranded
RNA is composed of 4 nucleotides:
- Adenine and guanine (purines)
- Cytosine and uracil (pyrimidines)
- Bases are attached to carbon atom 1’ in the sugar
DNA – Double Helical Structure
Nucleic acid strands can form a double helical structure
- DNA double helical structure is based on complementary base pairing of nucleotide’s guanine binding w/ cytosine and adenine binding w/ thymine
- Bonding takes place w/ 2 H-bonds between A & T and 3 H-bonds between G & T
General features of DNA:
- DNA molecules consist of two chain of opposite directionality ~ one strand runs in the 5’ to 3’ direction, and the other in the 3’ to 5’ direction ~ intertwined to form a right-handed double helix
- Sugar-phosphate backbone are on outside of the helix, whereases bases are on inside (right-handed double helix)
- Bases are nearly perpendicular to axis of helix w/ adjacent bases separated by 3.4 A
- Helix is approx. 20 A wide
DNA – Bonds & Forces
H-bonds between base pairs
- Adenine – thymine
- Guanine – cytosine
Stacking forces
- Hydrophobic interactions
- Van der Waals forces
- Base pairs are stacked on one another which helps stabilize double helix
DNA – Multiple Forms
DNA double helix can adopt multiple forms:
- B-form: most common, classical form
- A-form: shorter and wider than B-form
=> bases are at an angle rather than perpendicular to the helical axis
=> RNA double helices and DNA-RNA hybrid helices (structures that form during transcription and RNA processing) will adopt a double helical form that is very similar to the A-form
- Z-form: not completely understood
=> left-handed helix rather than right-handed double helix
DNA – Grooves
B-form grooves
- Major groove (large side)
- Minor groove (small side)
Grooves allow access to the H-bonding capabilities of the exposed bases
H-bonding capabilities provide a means of sequence specific interaction between DNA and the molecules w/ which they must interact with the processes of replication and transcription
DNA – Compaction
Bacterial cells (E. coli): DNA double helix = circular molecule that is twisted into a super helix by process of supercoiling
- The unwound DNA and supercoiled form are topological isomers of each other. Linear DNA molecules can also form superhelices when packaged into chromosomes
Eukaryotic cells: DNA is associated w/ specific protein
DNA in human cells: DNA is 3.6 meters in length and packaged into 46 chromosomes
Supercoiling accounts for some of the compaction, but further compacting is required for certain DNA-binding proteins
Chromatin = entire complex of a cell’s DNA and its associated protein
Histones = proteins that will allow for the compaction of DNA
- Once the DNA is wrapped around the histone, a nucleosome is created
- The basic property of the histone protein means that the histones have a positive charge, which allows for the DNA, which is negatively charged, to nicely wrap around these proteins
Nucleosome = contains histones and DNA
Strategies to compact DNA to fit inside cell:
- Nucleosomes: formed by DNA wrapping around histone proteins (positively charged proteins)
- Supercoiling: additional winding resulting in coil formation
- Chromatin: nucleosomes wrapped into spring structures
- Chromosome: further wrapping and looping of chromatin
