Regulation of metabolism

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Created by
Deborah Otunji

Cards (33)

  • Protein Release
    Cell lysis (mechanical, chemical, enzymatic)
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  • Protein Purification Steps
    1. Centrifugation
    2. Chromatography (ion exchange, affinity, size exclusion)
    3. Electrophoresis
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  • Assays
    Enzyme assays to measure catalytic activity, specific assays for target protein identification
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  • Specific Activity
    Ratio of enzyme activity to the amount of protein, indicating enzyme purity
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  • Subcellular Fractionation
    Differential centrifugation to separate cellular components based on size and density
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  • In Vivo Studies
    Use of radioisotopes (e.g., 14C, 32P) to trace metabolic pathways
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  • Protein Characteristics
    • Solubility
    • Charge
    • Size
    • Binding Abilities
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  • Amino Acid Sequencing
    Edman Degradation: Sequentially removes and identifies N-terminal amino acids of a protein
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  • Protein Localization
    Use of Antibodies: Immunocytochemistry to visualize protein distribution in cells
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  • 3D Structure Analysis
    1. ray Crystallography: Provides detailed structure of protein's active sites and interactions
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  • Homeostasis
    The ability of an organism to maintain a stable internal environment despite external changes
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  • Importance of Homeostasis
    • Essential for survival, as enzymes and metabolic pathways need precise conditions (pH, temperature, ion concentrations)
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  • Deregulation of Homeostasis
    Results in metabolic disorders (e.g., diabetes, metabolic syndrome), leading to disease or death
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  • Regulatory Strategies
    • Control of Enzyme Amount
    • Control of Enzyme Activity
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  • Control of Enzyme Amount
    1. Gene Expression: Regulation at transcriptional (gene transcription) and post-transcriptional (mRNA stability, translation) levels
    2. Protein Degradation: Ubiquitin-proteasome system targets proteins for degradation
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  • Control of Enzyme Activity
    • Allosteric Control
    • Feedback Inhibition
    • Multiple Forms of Enzymes (Isoenzymes)
    • Covalent Modifications
    • Localization and Degradation
    • Proteolytic Activation
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  • Allosteric Control
    • Regulatory Sites: Binding sites separate from the active site where molecules can increase or decrease enzyme activity
    • Cooperativity: Binding of a substrate to one active site affects activity at other sites (e.g., hemoglobin)
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  • Feedback Inhibition
    End product of a pathway inhibits an enzyme involved early in the pathway
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  • Multiple Forms of Enzymes (Isoenzymes)
    • Structural Differences: Small variations in amino acid sequences
    • Kinetic Properties: Differences in KM (affinity for substrate) and Vmax (maximum rate)
    • Tissue-Specific Expression: Different tissues may express different isoenzymes for the same reaction
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  • Covalent Modifications
    • Reversible Modifications: Phosphorylation, acetylation, methylation, ubiquitination
    • Activation/Inhibition: Modifications can either activate or inhibit enzyme function
    • Localization: Enzymes may be directed to specific cellular compartments
    • Degradation: Targeted degradation of enzymes via lysosomes or proteasomes
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  • Proteolytic Activation

    Zymogens/Proenzymes: Inactive precursors that require proteolytic cleavage to become active
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  • Proteolytic Activation Examples
    • Blood Clotting: Activation of clotting factors
    • Digestive Enzymes: Activation of pepsinogen to pepsin
    • Programmed Cell Death (Apoptosis): Activation of caspases
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  • Allosteric Control Mechanism

    Non-substrate molecules bind to allosteric sites, inducing conformational changes affecting enzyme activity
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  • Allosteric Control Example
    • Aspartate transcarbamoylase (ATCase) is regulated by CTP (inhibitor) and ATP (activator)
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  • Multiple Forms of Enzymes (Isoenzymes)
    Fine-Tuning Metabolism: Allows cells to adapt to different metabolic needs
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  • Isoenzyme Example
    • Hexokinase and glucokinase are isoenzymes that phosphorylate glucose but have different kinetic properties and tissue distributions
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  • Covalent Modifications: Phosphorylation
    Catalyzed by kinases and reversed by phosphatases
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  • Phosphorylation Example
    • Glycogen phosphorylase is activated by phosphorylation during glycogen breakdown
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  • Proteolytic Activation
    One-Time Activation: Irreversible activation mechanism
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  • Proteolytic Activation Example
    • Trypsinogen is activated to trypsin in the digestive tract, which then activates other digestive enzymes
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  • Protein Purification is necessary for functional and structural studies
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  • Enzyme Regulation is essential for efficient and controlled metabolic processes
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  • Regulatory Strategies
    • Controlling enzyme amounts
    • Controlling enzyme activity through allosteric regulation
    • Isoenzymes
    • Covalent modifications
    • Proteolytic activation
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