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Following Molecules/Cells through TIME to Understand Processing and Processes

Following Molecules/Cells through TIME to Understand Processing and Processes. Experimental strategies for investigating:. Kinetics of synthesis or degradation of a molecule Precursor/product relationships Molecular mechanisms (e.g., DNA replication, signal transduction)

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Following Molecules/Cells through TIME to Understand Processing and Processes

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  1. Following Molecules/Cells through TIME to Understand Processing and Processes

  2. Experimental strategies for investigating: Kinetics of synthesis or degradation of a molecule Precursor/product relationships Molecular mechanisms (e.g., DNA replication, signal transduction) Movements of a molecule over time (protein secretion, cell cycle, differentiation) Which cells give rise to particular structures during development?

  3. Experimental Conditions • Need a • Need a

  4. Experimental Conditions • Need a means of differentially marking a population of molecules or cells. • Need a

  5. Experimental Conditions • Need a means of differentially marking a population of molecules or cells. • Need a method for following them through time. Must distinguish labeled from unlabeled at various time points.

  6. For marking: • Molecules

  7. For marking: • Molecules • Radioactivity (e.g., 3H, 35S, 32P) • Density • Fluorescence • Cells

  8. For marking: • Molecules • Radioactivity (e.g., 3H, 35S, 32P) • Density • Fluorescence • Cells • Enzyme expression (often with chromogenic substrate) • Morphology (e.g., chick versus quail) • Fluorescence

  9. Marking constraints: • The label must not affect the process of interest • There must be minimal redistribution of the label over the course of the experiment (except as produced by the process of interest) • (For some experiments) Labeling must be rapid (rapid cellular uptake and incorporation).

  10. For detecting/tracking: • Radioactivity

  11. For detecting/tracking: • Radioactivity • Cell/molecule fractionation and counting • Microscopy (autoradiography) • Density

  12. For detecting/tracking: • Radioactivity • Cell/molecule fractionation and counting • Microscopy (autoradiography) • Density • Density-gradient centrifugation • Mass spectrometry

  13. For detecting/tracking: • Radioactivity • Cell/molecule fractionation and counting • Microscopy (autoradiography) • Density • Density-gradient centrifugation • Mass spectrometry • Fluorescence and enzyme labeling

  14. For detecting/tracking: • Radioactivity • Cell/molecule fractionation and counting • Microscopy (autoradiography) • Density • Density-gradient centrifugation • Mass spectrometry • Fluorescence and enzyme labeling • Microscopy • Cell/molecular fractionation and observation (of fractions, gels, chromatograms)

  15. Density-gradient centrifugation Comes in several flavors!

  16. Density-gradient centrifugation Comes in several flavors! 1. Velocity centrifugation 2. Equilibrium (isopycnic) centrifugation

  17. Density-gradient centrifugation Comes in several flavors! 1. Velocity centrifugation Materials: Sucrose, Ficoll (low osmolarity), etc. Procedure: Premix gradient, run for fixed time Separation: Depends on mass, shape, partial-specific volume (density), which determine “ S value”

  18. Density-gradient centrifugation Comes in several flavors! 1. Velocity centrifugation Materials: Sucrose, Ficoll (low osmolarity), etc. Procedure: Premix gradient, run for fixed time Separation: Depends on mass, shape, partial-specific volume (density), which determine “ S value” 2. Equilibrium (isopycnic) centrifugation Procedure: Run to equilibrium Separation: Depends only on density (neutral buoyancy) a. “Step gradients” (pre-form gradient of sucrose, etc.) b. “Continuous gradients” [gradient forms itself by sedimentation vs. diffusion; CsCl (nucleic acids), Percoll (cells and organelles)]

  19. Meselson & Stahl (1958) • One of the most famous experiments ever – why?

  20. Meselson & Stahl (1958) • One of the most famous experiments ever – why? • They solved an important problem (did DNA replicate the way Watson’s & Crick’s model predicted?).

  21. Meselson & Stahl (1958) • One of the most famous experiments ever – why? • They solved an important problem (did DNA replicate the way Watson’s & Crick’s model predicted?). • They pioneered use of stable-isotope labeling AND isopycnic density-gradient centrifugation in CsCl (with Vinograd).

  22. Meselson & Stahl (1958) • One of the most famous experiments ever – why? • They solved an important problem (did DNA replicate the way Watson’s & Crick’s model predicted?). • They pioneered use of stable-isotope labeling AND isopycnic density-gradient centrifugation in CsCl (with Vinograd). • Methods were elegant, they attended punctiliously to detail (craftsmanship!), the results were very clear, and the presentation was lucid (more craftsmanship!).

  23. conservative distributive semi-conservative

  24. 4000 kb X 650 kDa/kb ≈ 2.6 X 109

  25. How would you answer this question today? Look directly at the DNA molecule? Resolution is an issue. Maybe atomic force microscopy? What about BrdU labeling? Resolution wouldn’t be good enough to distinguish strands.

  26. Pulse/Chase Experiments Here rapid labeling IS an issue. Often, cells are first grown in a metabolite-deficient medium to deplete their stores of that metabolite.

  27. Pulse/Chase Experiments Here rapid labeling IS an issue. Often, cells are first grown in a metabolite-deficient medium to deplete their stores of that metabolite. Labeled metabolite is added, or a tagging procedure is applied, for a discrete interval (the “pulse”).

  28. Pulse/Chase Experiments Here rapid labeling IS an issue. Often, cells are first grown in a metabolite-deficient medium to deplete their stores of that metabolite. Labeled metabolite is added, or a tagging procedure is applied, for a discrete interval (the “pulse”). Cells are then washed and/or an excess of unlabeled metabolite is added (the “chase”).

  29. Pulse/Chase Experiments Here rapid labeling IS an issue. Often, cells are first grown in a metabolite-deficient medium to deplete their stores of that metabolite. Labeled metabolite is added, or a tagging procedure is applied, for a discrete interval (the “pulse”). Cells are then washed and/or an excess of unlabeled metabolite is added (the “chase”). Cells are sampled at intervals to track the metabolite (or tagged molecule) and molecules and/or organelles into which it is incorporated.

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