BMS100 Central Dogma Pre-learning Video 2: RNA PDF

Summary

This document is a presentation on the Central Dogma and different types of RNA. It covers pre-learning material and includes in-class topics such as transcription and translation. The document contains questions relating to the presented material.

Full Transcript

Central Dogma Pre-learning video 2: RNA Dr. Rhea Hurnik BMS100 Plan Pre-learning 1) DNA, Chromosomes, & genes 2) RNA In-class: Transcription Translation Template strand Like DNA, RNA is a polymer made of nucleotides linked by a phosphodiester bond. RNA differs from DNA chemically in 2 main ways: § 1) Ribose sugar vs deoxyribose sugar § 2) Uracil (U) base rather than thymine (T) Still contains adenine, guanine, and cytosine RNA Structurally RNA and DNA are also quite different § DNA always occurs in a double-stranded helix § RNA is single-stranded Therefore can fold up into various shapes Types of RNA - mRNA As outlined in the central dogma, DNA is transcribed into RNA to serve as a template for protein translation § In this case the RNA transcript is called messenger RNA (mRNA) Initially it is termed pre-mRNA. Pre-mRNA then undergoes processing into mature mRNA § This is discussed further in class Types of RNA continued Some sequences of DNA are transcribed into RNA than does not get translated into proteins § This is called non-coding RNA § Non-coding RNA serve as enzymatic, structural, and regulatory components of a wide variety of processes in the cell Non-coding RNA - snRNA Small nuclear RNA (snRNA) functions in the spliceosome § Preview: spliceosomes are needed to remove introns from pre-mRNA – aka splicing (discussed in class) snRNA associated with proteins subunits to form small nuclear ribonucleoproteins (snRNPs), which form the core of the spliceosome. Non-coding RNA - rRNA Ribosomal RNA (rRNA) § Needed for the basic structure of ribosome complex § Involved in catalysis of the peptide bond between amino acids Check your knowledge Which of the following RNA molecules directly codes for proteins? § A) mRNA § B) tRNA § C) rRNA § D) snRNA Non-coding RNA - tRNA Transfer RNA (tRNA) are needed in translation to carry the correct amino acid to the growing polypeptide chain tRNA folds into a unique cloverleaf shape Non-coding RNA - tRNA Two particular regions of the tRNA are particularly important to protein translation § Anticodon: 3 consecutive nucleotides that pairs with the complementary codon in an mRNA molecule § Amino acid binding site: Short single-stranded region at the 3’ end of the tRNA molecule Binds the amino acid that corresponds to the anti-codon on the tRNA Wobble Hypothesis Despite 64 possible combinations of nucleotides in into a 3 nucleotide codon, there are only 20 amino acids § This demonstrates the redundancy of the genetic code § This implies that either: There is more than 1 possible tRNA for many of the amino acids OR Some tRNA molecule can base-pair with more than one codon § Both are true! Wobble Hypothesis Some tRNA are built to only require accurate base-pairing of only the first two positions of the codon & can tolerate mismatch (aka wobble) in the third position § This explains why so many of the alternative codons for an amino acid differ only in their third nucleotide. Non-coding RNA - other miRNA (micro RNA) § Regulate gene expression via post-transcriptional silencing Block/prevent translation of specific mRNAs & promote their degradation siRNA (Small interfering RNA) § Reduce gene expression Direct degradation of specific mRNA lncRNA (long non-coding RNA) § Regulate gene expression Can increase or decrease transcription § Involved in X-chromosome inactivation Types of RNA - summary Types of RNA Name Function mRNA Messenger RNA Codes for proteins rRNA Ribosomal RNA Important constituents of ribosomes. Catalyzes protein synthesis tRNA Transfer RNA Adaptor between mRNA and amino acids snRNA Small nuclear RNA Splicing of pre-mRNA miRNA Micro RNA Regulate gene expression: block translation of specific mRNA & promote its degradation siRNA Small interfering RNA Regulate gene expression: direct specific mRNA degradation lncRNA Long non-coding RNA Regulate gene expression: can increase or decrease transcription Check your knowledge Which of the following RNA molecules are involved in gene regulation § A) mRNA, tRNA, siRNA § B) tRNA, rRNA, miRNA § C) siRNA, miRNA, lncRNA § D) snRNA, lncRNA, miRNA The end! References Abali, Emine E; Cline, Susan D; Franklin, David S; Viselli, Susan M. Lippincott Illustrated Reviews: Biochemistry (Lippincott Illustrated Reviews Series) (p. 105). Wolters Kluwer Health Boron, W. and Boulpaep, E. Medical Physiology (3rd ed). Elsevier Alberts et al. Molecular Biology of the Cell. Garland Science. Betts et al. Anatomy and Physiology (2ed). OpenStax Images: § Kcneuman, CC BY-SA 4.0 , via Wikimedia Commons. Retrieved from: https://upload.wikimedia.org/wikipedia/commons/7/7e/Topological_ram ifications_of_DNA_replication_and_transcription.jpg