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Unlock your guides13.2 DNA Replication and Repair
2 min read•july 25, 2024
DNA replication is a crucial process that ensures genetic continuity. It involves unwinding the DNA double helix, synthesizing new strands, and repairing errors. This complex mechanism relies on various enzymes and occurs in a semi-conservative manner.
Understanding DNA replication is key to grasping how genetic information is passed on. It also sheds light on , , and . The process's accuracy and repair mechanisms are vital for maintaining cellular health and preventing diseases like cancer.
DNA Replication Process and Enzymes
Process of DNA replication
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Top images from around the web for Process of DNA replication
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- produces daughter molecules with one original and one new DNA strand ensuring genetic continuity
- Initiation begins at (ori) sites where unwinds DNA double helix creating
- Elongation involves synthesizing RNA primers followed by adding to growing strand in 5' to 3' direction
- form on due to discontinuous synthesis then joins these fragments
- occurs when replication forks meet and adds telomeres to chromosome ends protecting genetic material
Leading vs lagging strands
- synthesized continuously in 5' to 3' direction following movement requires only one RNA primer
- Lagging strand synthesized discontinuously in 5' to 3' direction opposite to fork movement requires multiple RNA primers forming Okazaki fragments
- Replication fork Y-shaped structure where parental DNA strands separate allowing simultaneous leading and lagging strand synthesis
Mechanisms of DNA repair
- reverses UV-induced thymine dimers through (photolyase enzyme)
- Excision repair removes damaged DNA:
- (BER) removes damaged bases (uracil DNA glycosylase)
- (NER) removes bulky DNA lesions (UV-induced pyrimidine dimers)
- corrects errors in base pairing during replication (MutS, MutL proteins)
- :
- uses sister chromatid as template (RAD51 protein)
- directly ligates broken ends (Ku proteins)
Consequences of replication errors
- Mutations alter genetic information:
- change single nucleotides (sickle cell anemia)
- Insertions or deletions cause (cystic fibrosis)
- Chromosomal abnormalities rearrange genetic material:
- exchange segments between chromosomes (chronic myeloid leukemia)
- reverse DNA segments within chromosomes (hemophilia A)
- Genetic disorders arise from inherited mutations (Huntington's disease)
- Cancer develops through accumulation of mutations in oncogenes and tumor suppressor genes (p53 gene)
- Aging accelerates due to cellular senescence from accumulated DNA damage (Werner syndrome)
- Cell death triggered by excessive DNA damage through (radiation exposure)
- Evolution driven by some mutations contributing to genetic diversity and adaptation (antibiotic resistance)
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