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Transfer 5 µl from your PCR tube to fresh tube, add 1 µl dye & run on 0.7% gel

Transfer 5 µl from your PCR tube to fresh tube, add 1 µl dye & run on 0.7% gel. Protein degradation Some have motifs marking them for polyubiquitination : E1 enzymes activate ubiquitin E2 enzymes conjugate ubiquitin E3 ub ligases determine specificity, eg for N-terminus.

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Transfer 5 µl from your PCR tube to fresh tube, add 1 µl dye & run on 0.7% gel

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  1. Transfer 5 µl from your PCR tube to fresh tube, add 1 µl dye & run on 0.7% gel

  2. Protein degradation • Some have motifs marking them for polyubiquitination: • E1 enzymes activate ubiquitin • E2 enzymes conjugate ubiquitin • E3 ub ligases determine specificity, eg for N-terminus

  3. E3 ubiquitin ligases determine specificity • >1300 E3 ligases in Arabidopsis • 4 main classes according to cullin scaffolding protein • RBX positions E2 • DDB1 positions DCAF/DWD • DCAF/DWD picks substrate • NOT4 is an E3 ligase & a component of the CCR4–NOT de-A complex • CCR4–NOT de-A • Complex regulates pol II • Transcription, mRNA • deg & prot deg are • linked!

  4. DWD Proteins • Tested members of each subgroup for DDB1 binding • co-immunoprecipitation

  5. DWD Proteins • Tested members of each subgroup for DDB1 binding • co-immunoprecipitation • Two-hybrid: identifies • interacting proteins

  6. DWD Proteins • Tested members of each subgroup for DDB1 binding • co-immunoprecipitation • Two-hybrid: identifies • interacting proteins • Only get transcription if • one hybrid supplies Act D • & other supplies DNA • Binding Domain

  7. Regulating E3 ligases The COP9 signalosome (CSN), a complex of 8 proteins, regulates E3 ligases by removing Nedd8 from cullin CAND1 then blocks cullin Ubc12 replaces Nedd8 Regulates DNA-damage response, cell-cycle & gene expression Not all E3 ligases associate with Cullins!

  8. COP1 is a non-cullin-associated E3 ligase • Protein degradation is important for light regulation • COP1/SPA1 tags transcription factors for degradation • W/O COP1 they act in dark • In light COP1 is exported to cytoplasm so TF can act

  9. COP1 is a non-cullin-associated E3 ligase • Recent data indicates that COP1 may also associate with CUL4

  10. Protein degradationrate varies 100x • Most have motifs marking them for polyubiquitination: taken to proteosome & destroyed • Other signals for selective degradation include PEST & KFERQ • PEST : found in many rapidly • degraded proteins • e.g. ABCA1 (which exports • cholesterol in association with • apoA-I) is degraded by calpain

  11. Protein degradationrate varies 100x • Other signals for selective degradation include PEST & KFERQ • PEST : found in many rapidly degraded proteins • e.g. ABCA1 (which exports cholesterol in association with apoA-I) is degraded by calpain • Deletion increases t1/2 10x, adding PEST drops t1/2 10x

  12. Protein degradationrate varies 100x • Other signals for selective degradation include PEST & KFERQ • PEST : found in many rapidly degraded proteins • e.g. ABCA1 (which exports cholesterol in association with apoA-I) is degraded by calpain • Deletion increases t1/2 10x, adding PEST drops t1/2 10x • Sometimes targets poly-Ub

  13. Protein degradationrate varies 100x • Other signals for selective degradation include PEST & KFERQ • PEST : found in many rapidly degraded proteins • e.g. ABCA1 (which exports cholesterol in association with apoA-I) is degraded by calpain • Deletion increases t1/2 10x, adding PEST drops t1/2 10x • Sometimes targets poly-Ub • Recent yeast study doesn’t support general role

  14. Protein degradationrate varies 100x • Other signals for selective degradation include PEST & KFERQ • PEST : found in many rapidly degraded proteins • e.g. ABCA1 (which exports cholesterol in association with apoA-I) is degraded by calpain • Deletion increases t1/2 10x, adding PEST drops t1/2 10x • Sometimes targets poly-Ub • Recent yeast study doesn’t support general role • KFERQ: cytosolic proteins with KFERQ are selectively taken up by lysosomes in chaperone-mediated autophagy under conditions of nutritional or oxidative stress.

  15. Protein degradationin bacteria Also highly regulated, involves chaperone like proteins Lon

  16. Protein degradationin bacteria Also highly regulated, involves chaperone like proteins Lon Clp

  17. Protein degradationin bacteria Also highly regulated, involves chaperone like proteins Lon Clp FtsH in IM

  18. PROTEIN TARGETING All proteins are made with an “address”which determines their final cellular location Addresses are motifs within proteins

  19. PROTEIN TARGETING All proteins are made with “addresses”which determine their location Addresses are motifs within proteins Remain in cytoplasm unless contain information sending it elsewhere

  20. PROTEIN TARGETING Targeting sequencesare both necessary& sufficient to send reporter proteins to new compartments.

  21. PROTEIN TARGETING 2 Pathways in E.coli http://www.membranetransport.org/ Tat: for periplasmic redox proteins & thylakoid lumen!

  22. 2 Pathways in E.coli • Tat: for periplasmic redox proteins & thylakoid lumen! • Preprotein has signal seqS/TRRXFLK

  23. 2 Pathways in E.coli • Tat: for periplasmic redox proteins & thylakoid lumen! • Preprotein has signal seqS/TRRXFLK • Make preprotein, folds • & binds cofactor in • cytosol

  24. 2 Pathways in E.coli • Tat: for periplasmic redox proteins & thylakoid lumen! • Preprotein has signal seqS/TRRXFLK • Make preprotein, folds • & binds cofactor in • cytosol • Binds Tat in • IM & is sent to • periplasm

  25. 2 Pathways in E.coli • Tat: for periplasmic redox proteins & thylakoid lumen! • Preprotein has signal seqS/TRRXFLK • Make preprotein, folds & binds cofactor in cytosol • Binds Tat in IM & is sent to periplasm • Signal seq is • removed in • periplasm

  26. 2 Pathways in E.coli http://www.membranetransport.org/ • Tat: for periplasmic redox proteins & thylakoid lumen! • Sec pathway • SecB binds preprotein • as it emerges from rib

  27. Sec pathway • SecB binds preprotein as it emerges from rib & prevents folding

  28. Sec pathway • SecB binds preprotein as it emerges from rib & prevents folding • Guides it to SecA, which drives it through SecYEG into periplasm using ATP

  29. Sec pathway • SecB binds preprotein as it emerges from rib & prevents folding • Guides it to SecA, which drives it through SecYEG into periplasm using ATP • In periplasm signal peptide is removed and protein folds

  30. Sec pathway part deux • SRP binds preprotein as it emerges from rib & stops translation • Guides rib to FtsY • FtsY & SecA guide it to SecYEG , where it resumes translation & inserts protein into membrane as it is made

  31. Periplasmic proteins with the correct signals (exposed after cleaving signal peptide) are exported by XcpQ system

  32. PROTEIN TARGETING Protein synthesis always begins on free ribosomes in cytoplasm

  33. 2 Protein Targeting pathways Protein synthesis always begins on free ribosomes in cytoplasm 1) proteins ofplastids, mitochondria, peroxisomes andnucleiare imported post-translationally

  34. 2 Protein Targeting pathways Protein synthesis always begins on free ribosomes In cytoplasm 1) proteins ofplastids, mitochondria, peroxisomes andnucleiare imported post-translationally made in cytoplasm, then imported when complete

  35. 2 Protein Targeting pathways Protein synthesis always begins on free ribosomes In cytoplasm 1) Post -translational: proteins ofplastids,mitochondria, peroxisomesandnuclei 2) Endomembrane system proteins are imported co-translationally

  36. 2 Protein Targeting pathways 1) Post -translational 2) Co-translational: Endomembrane system proteins are imported co-translationally inserted in RER as they are made

  37. 2 pathways for Protein Targeting 1) Post -translational 2) Co-translational: Endomembrane system proteins are imported co-translationally inserted in RER as they are made transported to final destination in vesicles

  38. SIGNAL HYPOTHESIS Protein synthesis always begins on free ribosomes in cytoplasm in vivo always see mix of free and attached ribosomes

  39. SIGNAL HYPOTHESIS Protein synthesis begins on free ribosomes in cytoplasm endomembrane proteins have "signal sequence"that directs them to RER Signal sequence

  40. SIGNAL HYPOTHESIS Protein synthesis begins on free ribosomes in cytoplasm endomembrane proteins have "signal sequence"that directs them to RER “attached” ribosomes are tethered to RER by the signal sequence

  41. SIGNAL HYPOTHESIS • Protein synthesis begins on free ribosomes in cytoplasm • Endomembrane proteins have"signal sequence"that directs them to RER • SRP (Signal Recognition Peptide) binds signal sequence when it pops out of ribosome & swaps GDP for GTP

  42. SIGNAL HYPOTHESIS • SRP (Signal Recognition Peptide) binds signal sequence when it pops out of ribosome & swaps GDP for GTP • 1 RNA & 7 proteins

  43. SIGNAL HYPOTHESIS • SRP binds signal sequence when it pops out of ribosome • SRP stops protein synthesis until it binds “docking protein”(SRP receptor) in RER

  44. SIGNAL HYPOTHESIS SRP stops protein synthesis until it binds “docking protein”(SRP receptor) in RER Ribosome binds Translocon & secretes protein through it as it is made

  45. SIGNAL HYPOTHESIS SRP stops protein synthesis until it binds “docking protein”(SRP receptor) in RER Ribosome binds Translocon & secretes protein through it as it is made BiP (a chaperone) helps the protein fold in the lumen

  46. SIGNAL HYPOTHESIS Ribosome binds Translocon & secretes protein through it as it is made secretion must be cotranslational

  47. Subsequent events • Simplest case: • 1) signal is cleaved within lumen by signal peptidase • 2) BiP helps protein fold correctly • 3) protein is soluble inside lumen

  48. Subsequent events Complications: proteins embedded in membranes

  49. proteins embedded in membranes • protein has a stop-transfer sequence • too hydrophobic to enter aqueous lumen

  50. proteins embedded in membranes • protein has a stop-transfer sequence • too hydrophobic to enter lumen • therefore gets stuck in membrane • ribosome releases translocon, finishes job in cytoplasm

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