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MOLECULAR BIOLOGY – Regulation of gene expression II Regulation of gene expression Part II MOLECULAR BIOLOGY – Regulation of gene expression II There are MULTIPLE opportunities to regulated gene expression (derivation of functional protein) after the initiation of transcription ! Figure 7-92 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Riboswitch … short sequences of RNA that change their conformation upon binding small molecules such as metabolites, usually reside in 5’ UTR Mostly observed in bacteria but also documented in fungi and plants MOLECULAR BIOLOGY – Regulation of gene expression II Riboswitch can can activate ‘self cleaving’ ribozyme activity 5’ STOP AUG H2N COOH 3’ ON Autolytic ribozyme activity STOP AUG 5’ small molecule H2N COOH 3’ OFF MOLECULAR BIOLOGY – Regulation of gene expression II Riboswitch can affect the translation initiation from Shine-Dalgarno sequence Figure 7-106c Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II THERMOSENSOR Figure 7-106b Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Antisense RNA Figure 7-106d Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Figure 7-92 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II ALTERNATIVE SPLICING Figure 7-94 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II e.g. Drosophila Dscam axon guidance receptors Thousands of possible different functional protein sequence combinations MOLECULAR BIOLOGY – Regulation of gene expression II Splicing is subject to tight regulatory control Figure 7-96 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Figure 7-92 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II RNA editing - specific to eukaryotes (and viruses) Non-templated changes to the genetic information that affect the protein sequence and possibly function and are therefore not predictable from genomic DNA sequence Deamination reactions e.g. A - I/G in RNA duplexes by ADAR: C - U deaminations also possible do not rely on RNA duplexes e.g. ApoB100 mRNA in liver and intestine Altered amino acid codons Figure 7-101 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Extensive RNA editing in mitochondria of trypanosomes Uracil insertions Figure 7-100 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Figure 7-92 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Nonsense-mediated mRNA decay DNA gene EJC ribonucleoprotein complexes are remnants of splicing EJC displacement during translation Figure 6-80 Molecular Biology of the Cell (© Garland Science 2008) transcription Premature termination of translation leaves ‘beacon’ EJC leading to abnormal mRNA degradation MOLECULAR BIOLOGY – Regulation of gene expression II Some mRNAs are localized to specific regions of the cytoplasm mRNAs for secreted proteins targeted to ER by SRP Drosophila oocyte polarity and embryo patterning nanos mRNA bicoid mRNA A Bicoid protein P Nanos protein bicoid and nanos proteins inhibit translation of other homogenously distributed cell fate genes which in turn affects the expression of other cell fate mRNAs along the A-P axis as development proceeds MOLECULAR BIOLOGY – Regulation of gene expression II Figure 7-92 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II Central genetic dogma PROMOTER exon 1 DNA exon 2 exon 3 ATG TAA AATAAA TRANSCRIPTION 5’UTR Pre-mRNA intron AUG CAP 3’UTR intron UAA AAUAAA NUCLEUS RNA SPLICING CYTOPLASM mRNA AUG UAA AAUAAA coding sequence TRANSLATION protein OPEN READING FRAME MAPSSRGG….. Regulation of gene expression via regulation of mature mRNAs AAAAA MOLECULAR BIOLOGY – Regulation of gene expression II mRNA stability as a way to regulate gene expression in bacteria – half life couple minutes in eukaryotes – half life minutes to tens of hours 3’ UTR contains regulatory elements that participate in transcript stability 5‘ Cap: • aids mRNA nuclear export • protects from 5‘ - 3‘ exonuclease degradation in cytoplasm • targets transcripts to ribosome for translation Figure 7-109 Molecular Biology of the Cell (© Garland Science 2008) poly-A tail: • participates in termination of transcription • aids mRNA nuclear export • protects from 3‘ - 5‘ exonuclease degradation in cytoplasm • targets transcripts to ribosome for translation MOLECULAR BIOLOGY – Regulation of gene expression II mRNA stability as a way to regulate gene expression in bacteria – half life couple minutes in eukaryotes – half life minutes to tens of hours Cytoplasmic deadenylases e.g. PARN Figure 7-109 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II mRNA’s with longer poly-A tails more likely to be translated PARN binds exposed 5‘ cap of non-translated mRNAs, leading to poly-A tail deadenylation and eventual degradation Regulatory potential to influence this equilibrium e.g. cytoplasmic polyadenylation of short poly-A tails e.g. fertilized mammalian oocytes and post-synaptic neurone sites Figure 7-110 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II mRNA stability mechanisms in action e.g. ferritin/ transferrin receptor system Figure 7-111 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II PROMOTER exon 1 DNA exon 2 exon 3 ATG TAA AATAAA TRANSCRIPTION 5’UTR Pre-mRNA intron AUG CAP 3’UTR intron UAA AAUAAA NUCLEUS RNA SPLICING CYTOPLASM mRNA AUG UAA AAUAAA coding sequence TRANSLATION protein OPEN READING FRAME MAPSSRGG….. AAAAA MOLECULAR BIOLOGY – Regulation of gene expression II microRNA (miRNA) ... small noncoding RNA regulators recognizing 3’UTRs Drosha & Prasha (DGCR8) ● one miRNA recognizes many mRNAs (even hundreds if they share common 3’UTRs) ● more than one miRNA can bind to one mRNA (combinatorial regulation) Pri-miRNA Dicer Pre-miRNA RNA-induced silencing complex RNA induced silencing complex (RISC) 3’UTR sequence homology miRNA (imperfect duplex 22nts - guide strand incorporated, passenger strand degraded) ● >1000 miRNA genes targeting approx 60% of genes ● estimated 16% of pre-miRNAs can be altered by ADAR mediated editing ● miRNA can be derived from spliced introns in non-mammalian species, known as mirtons Figure 7-112 Molecular Biology of the Cell (© Garland Science 2008) MOLECULAR BIOLOGY – Regulation of gene expression II RNA interference (RNAi) dsRNA viral genomes Pre-miRNA transcripts Experimentally introduced RNA Dicer mediated processing small interfering RNA (21-23nt) RNA-induced transcription silencing Argonaut mediated target mRNA degradation RISC re-used n.b. sequence homology not limited to 3’UTR Figure 7-115 Molecular Biology of the Cell (© Garland Science 2008) Co-transcriptional degradation of transcript MOLECULAR BIOLOGY – Regulation of gene expression II Origin of life - RNA world active RNAs involved in: • RNA splicing • Protein synthesis • Expression regulation – siRNA, riboswitches