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CMS A long noncoding RNA regulates photoperiod-sensitive male sterility, an essential component of hybrid rice(2012) doi: 10.1073/pnas.1121374109 A non-coding RNA locus mediates environment-conditioned male sterility in rice. (2012) Cell Research 22:791–792. doi:10.1038/cr.2012.43 Comparative expression profiling of miRNA during anther development in genetic male sterile and wild type cotton. (2013) BMC Plant Biology 13:66 Differential Proteomic Analysis of Anthers between Cytoplasmic Male Sterile and Maintainer Lines in Capsicum annuum L.(2013) Int. J. Mol. Sci. 14(11), 22982-22996; doi:10.3390/ijms141122982 Transcriptome map of plant mitochondria reveals islands of unexpected transcribed regions (2011) BMC Genomics 12: 279. Heterozygous alleles restore male fertility to cytoplasmic male-sterile radish (Raphanus sativus L.): a case of overdominance(2013) J. Exp. Bot. 64: 2041-2048. Aging Genome 1. DNA damage 2. Epigenetic shifts 3. Telomere shortening Cellular level 1. Mitochondria: ROS, DNA damage, other 2. Misfolded proteins 3. Dysfunctional stem cells Organismal level 1. Autoimmune, other defects in immune system 2. Defective signaling Journal Clubs Spend ~ 5’ setting the stage: • what is the general question? • Why is it important? • What was previously known? • What were the outstanding questions? Journal Clubs Spend ~ 5’ setting the stage: • what is the general question? • Why is it important? • What was previously known? • What were the outstanding questions? Then state the specific question addressed in your paper Journal Clubs Then state the specific question addressed in your paper Next explain how they studied it • General overview of techniques first, then specifics • What were they trying to do? • how did they do it? Journal Clubs Then state the specific question addressed in your paper Next explain how they studied it • General overview of techniques first, then specifics • What were they trying to do? • how did they do it? Then describe their results Journal Clubs Then describe their results • General overview first • Then specific experiments Journal Clubs Describe their results • General overview first • Then specific experiments • Specific purpose of each experiment • How they tested it • Data they collected • Controls!! • How they analyzed it Journal Clubs Describe their results • General overview first • Then specific experiments • Specific purpose of each experiment • How they tested it • Data they collected • Controls!! • How they analyzed it Conclusions they drew Journal Clubs Describe their results • General overview first • Then specific experiments • Specific purpose of each experiment • How they tested it • Data they collected • Controls!! • How they analyzed it Conclusions they drew Your interpretation • Do you agree? • How could they improve? Non-coding RNA Nearly ½ of human genome is transcribed, only 1% is coding • 98% of RNA made is non-coding Non-coding RNA Nearly ½ of human genome is transcribed, only 1% is coding • 98% of RNA made is non-coding •Fraction increases with organism’s complexity Non-coding RNA Structural 1. rRNA 2. tRNA 3. snRNA 4. snoRNA 5. cleavage: RNAses P & MRP, U3, snR30, etc Regulatory 1. Small • siRNA • miRNA 2. Long • Activator • Enhancer • silencing Other ncRNA? Incredible diversity of functions! • Epigenetic • Directly regulating transcription • Post-transcriptional regulation Some are made by Pol II, others by Pol III HID1 ncRNA 1. Extracted total RNA from a mix of tissues, separated by size and sequenced 50-300 nt fraction HID1 ncRNA 1. Extracted total RNA from a mix of tissues, separated by size and sequenced 50-300 nt fraction 2. BLAST to find relatives (and discard tRNA, etc) HID1 ncRNA 1. Extracted total RNA from a mix of tissues, separated by size and sequenced 50-300 nt fraction 2. BLAST to find relatives (and discard tRNA, etc) 3. T-DNA express to find mutants HID1 ncRNA 1. Extracted total RNA from a mix of tissues, separated by size and sequenced 50-300 nt fraction 2. BLAST to find relatives (and discard tRNA, etc) 3. T-DNA express to find mutants 4. ordered seeds for ones they found interesting HID1 ncRNA • ordered seeds for ones they found interesting • Grew them under varying light conditions • • • HID1 ncRNA ordered seeds for ones they found interesting Grew them under varying light conditions Found one specifically defective in sensing continuous red • • • HID1 ncRNA ordered seeds for ones they found interesting Grew them under varying light conditions Found one specifically defective in sensing continuous red HID1 ncRNA • Found one specifically defective in sensing continuous red • Confirmed that the HID1 ncRNA was responsible by adding back wt gene to “rescue phenotype” • • • • HID1 ncRNA Confirmed that the HID1 ncRNA was responsible by adding back wt gene to “rescue phenotype” Checked expression Constitutive Not regulated by light HID1 ncRNA • • Checked expression • Constitutive • Not regulated by light Tested sequence requirements to rule out ORFs • • HID1 ncRNA Tested sequence requirements to rule out ORFs Tested structural requirements under cR • • HID1 ncRNA Tested sequence requirements to rule out ORFs Tested structural requirements under cR • Both SL2 and SL4 are needed for it to function • • • HID1 ncRNA Tested sequence requirements to rule out ORFs Tested structural requirements under cR Searched for targets by RNA-seq • • HID1 ncRNA Searched for targets by RNA-seq HID1 represses PIF3 expression under cR HID1 ncRNA • Does HID1 act alone? • Added an S1 aptamer to HID1 RNA to help find it HID1 ncRNA • Does HID1 act alone? • Added an S1 aptamer to HID1 RNA to help find it • Was part of an ~ 500 kDa complex HID1 ncRNA • Does HID1 act alone? • Added an S1 aptamer to HID1 RNA to help find it • Was part of an ~ 500 kDa complex • ChIP-PCR showed that the complex bound the PIF3 promoter HID1 ncRNA • Does HID1 act alone? • Added an S1 aptamer to HID1 RNA to help find it • Was part of an ~ 500 kDa complex • ChIP-PCR showed that the complex bound the PIF3 promoter • Is HID1 conserved in evolution? HID1 ncRNA • Does HID1 act alone? • Added an S1 aptamer to HID1 RNA to help find it • Was part of an ~ 500 kDa complex • ChIP-PCR showed that the complex bound the PIF3 promoter • Is HID1 conserved in evolution? • Are the orthologs functional? HID1 ncRNA • Does HID1 act alone? • Added an S1 aptamer to HID1 RNA to help find it • Was part of an ~ 500 kDa complex • ChIP-PCR showed that the complex bound the PIF3 promoter • Is HID1 conserved in evolution? • Are the orthologs functional? • What next? Mitochondria and the immune system • Mito play important role in recognizing & fighting viruses • Via RLR (retinoic acid-inducible receptors) pathway that detects dsRNA • MAVS (mitochondrial antiviral signaling) protein on MOM is key • dsRNA receptors bind MAVS & trigger interferon & cytokine synthesis Programmed cell death vs necrosis Necrosis: progressive loss of membrane integrity swelling of cytoplasm, release of cell constituents Often follows irreversible injury Passive Indiscriminate PCD Active Orderly process mediated by intracellular death programs May or may not be due to an external factor Nuclear condensation Condensation of PM Apoptosis Ordered process that breaks cell into easily recycled pieces Caspases digest proteins CAD digests DNA Apoptosis Two basic steps: commitment and execution Commitment depends on interplay between various signals Bax & Bcl2 have opposite effects 2 main pathways: extrinsic & intrinsic Apoptosis 2 main pathways: extrinsic & intrinsic Tumor necrosis factor and Fas ligand = extrinsic signals that can trigger apoptosis via death receptor Apoptosis 2 main pathways: extrinsic & intrinsic Tumor necrosis factor and Fas ligand = extrinsic signals that can trigger apoptosis via death receptor Bind receptors in PM (TNFR or fas) Tumor necrosis factor and Fas ligand = extrinsic signals that can trigger apoptosis via death receptor Bind receptors in PM (TNFR or fas) Receptors activate FADD & TRADD: Adaptors with death domains that bind receptor’s DDs Receptors activate FADD & TRADD: Adaptors with death domains that bind receptor’s DDs Procaspase 8 binds FADD Receptors activate FADD & TRADD: Adaptors with death domains that bind receptor’s DDs Procaspase 8 binds FADD Procaspase 8 is processed to caspase 8 = initiator caspase Procaspase 8 binds FADD Procaspase 8 is processed to caspase 8 = initiator caspase Caspase 8 converts procaspase 3 to active form = executioner Procaspase 8 binds FADD Procaspase 8 is processed to caspase 8 = initiator caspase Caspase 8 converts procaspase 3 to active form = executioner Caspase-3 & CAD execute the cell
