Finishing Replication Molecular Biology and Cytogenetics PDF

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This document provides a summary on the topic of finishing replication. The document includes sections discussing prokaryotes, the end replication problem, telomerase, and telomere. This information is useful for studying molecular biology and cytogenetics at a university level.

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Molecular Biology and Cytogenetics 5. Finishing Replication Instructor: Dr. Mohammad Abukhalil Finishing replication in Prokaryotes ⚫ Termination of DNA replication in bacteria is completed when two replication forks meet at the terminus of the chromosome. ⚫ When a circular c...

Molecular Biology and Cytogenetics 5. Finishing Replication Instructor: Dr. Mohammad Abukhalil Finishing replication in Prokaryotes ⚫ Termination of DNA replication in bacteria is completed when two replication forks meet at the terminus of the chromosome. ⚫ When a circular chromosome finishes replication, the two new circles may be physically interlocked or catenated. ⚫ Decatenation of interlocked circles is carried out by topoisomerase type II by breaking the phosphodiester bonds. The end replication problem ⚫ Each DNA replication, end of DNA loses 50~100 nt. ⚫ Lose genes near the end of chromosome I- Attach a protein to 5’ end to serve as primer ⚫ Some bacteria have linear chromosome and animal virus. (Note: most bacteria have circular chromosome to solve end problem) ⚫ They have a terminal protein attached covalently to their 5′ DNA ends that provide an OH that replace the 3’OH normally provided by an RNA primer. II- Telomerase ⚫ Is a ribonucleoprotein ⚫ Responsible for elongating the 3` strand Telomere ⚫ Repetitive regions at the very ends of chromosomes are called telomeres, and they're found in a wide range of eukaryotic species, from human beings to unicellular protists. ⚫ Telomeres act as caps that protect the internal regions of the chromosomes, and they protect the end of the chromosome from fusion with neighboring chromosomes. ⚫ Telomeres consist of multiple tandem repeats (from 20 to several hundred) of a short sequence, usually of six bases (TTAGGG, in vertebrates including humans). Telomerase 1. RNA component: Template. 2. Protein component: reverse transcriptase enzyme. Telomerase ⚫ Telomerase carries a small segment of RNA, complementary to the six-base-pair telomere repeat. ⚫ The enzymatic portion of telomerase resembles other reverse transcriptases, proteins that synthesize DNA using an RNA template. ⚫ After telomerase has elongated the 3’-ends, the complementary strand can be filled in by normal RNA priming followed by elongation by DNA polymerase and joining by ligase. Regulation of telomerase activity ⚫ Telomere length regulation involves the accessibility of telomeres to telomerase. ⚫ Length control involves a number of factors including: ⚫ Proteins POT1, TRF1, and TRF2 ⚫ t-loop formation ⚫ A telomere-specific protein complex forms called shelterin. When the telomere is long enough: ⚫ POT1 levels are high at the 3′ overhang. ⚫ The action of telomerase is blocked. When the telomere is too short: ⚫ Little or no POT1 is present at the 3′ end. ⚫ Telomerase is no longer inhibited. A model for t-loop formation ⚫ The 3′ single-stranded DNA tail invades the double- stranded telomeric DNA. ⚫ A loop forms in which the 3′ overhang is base paired to the C strand sequence. ⚫ The t-loop may aid in preventing telomerase access. Regulation of telomerase activity ⚫ NO telomerase → NO maintenance of telomere → telomere loss (50-150 bp/end/division) → cell apoptosis ⚫ Telomerase → telomere maintenance → immortal cell Telomerase is tightly regulated Telomerase, aging, and cancer ⚫ In most human somatic cells, not enough telomerase is expressed to maintain a constant telomere length: Progressive shortening of telomeres. ⚫ High levels of telomerase activity in ovaries, testes, rapidly dividing somatic cells, and cancer cells. ⚫ Some stem cells, notably those in tissues that must be replenished at a high rate throughout life—bone marrow or gut lining, for example— retain full telomerase activity. Telomerase and aging: the Hayflick limit ⚫ The Hayflick limit is the point at which cultured cells stop dividing and enter an irreversible state of cellular aging (senescence). ⚫ Proposed to be a consequence of telomere shortening. Dyskeratosis congenita: loss of telomerase activity ⚫ Premature aging syndrome. ⚫ Problems in tissues where cells multiply rapidly and where telomerase is normally expressed. ⚫ Two forms of dyskeratosis congenita: ⚫ X-linked recessive ⚫ Autosomal dominant X-linked recessive dyskeratosis congenita ⚫ Mutations in dyskerin gene. ⚫ Dyskerin is a pseudouridine synthase that binds to small nucleolar RNAs and to telomerase RNA. ⚫ Patients with dyskerin mutations have 5-fold less telomerase activity than unaffected siblings. Autosomal dominant dyskeratosis congenita ⚫ Mutations in telomerase RNA gene in the pseudoknot domain. ⚫ Partial loss of function of telomerase RNA. Gene therapy for liver cirrhosis ⚫ Inhibition of liver cirrhosis in mice by telomerase gene delivery. ⚫ Why hasn’t this gene therapy strategy progressed to human trials?

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