Biochemistry

🧬Biochemistry Unit 11 – Introduction to Metabolism

Metabolism is the engine of life, driving all chemical reactions in living organisms. It encompasses catabolism, which breaks down molecules for energy, and anabolism, which builds complex molecules. These processes are tightly regulated to maintain cellular balance and respond to changing needs. Key players in metabolism include enzymes, which speed up reactions, and ATP, the energy currency of cells. Catabolic pathways like cellular respiration break down nutrients, while anabolic pathways like photosynthesis build complex molecules. Understanding metabolism is crucial for treating disorders and developing new technologies.

What's Metabolism All About?

  • Metabolism encompasses all chemical reactions involved in maintaining living cells and organisms
  • Includes two main categories: catabolism (breaking down molecules) and anabolism (building up molecules)
  • Catabolism releases energy by breaking down complex molecules into simpler ones
    • Includes processes like digestion and cellular respiration
  • Anabolism consumes energy to construct complex molecules from simpler ones
    • Includes processes like protein synthesis and DNA replication
  • Metabolic reactions are organized into metabolic pathways, series of linked enzymatic reactions
  • Energy released from catabolic pathways (cellular respiration) is used to drive anabolic pathways (biosynthesis)
  • Metabolism is tightly regulated to maintain homeostasis and respond to cellular needs

Key Players: Enzymes and Cofactors

  • Enzymes are biological catalysts that speed up chemical reactions without being consumed
  • Lower activation energy required for reactions to occur, making them more energetically favorable
  • Highly specific, typically catalyzing a single reaction or a set of closely related reactions
  • Active site is the region where the substrate binds and the reaction takes place
    • Substrate specificity is determined by the shape and chemical properties of the active site
  • Cofactors are non-protein molecules required for enzyme function
    • Can be inorganic (metal ions like Fe2+, Mg2+) or organic (coenzymes like vitamins)
  • Coenzymes are organic molecules that assist enzymes in catalyzing reactions
    • Examples include NAD+ (nicotinamide adenine dinucleotide) and FAD (flavin adenine dinucleotide)
  • Enzyme activity can be regulated by various factors (pH, temperature, inhibitors, activators)

Energy Currency: ATP and Friends

  • ATP (adenosine triphosphate) is the primary energy currency in living organisms
  • Consists of adenosine (adenine base + ribose sugar) and three phosphate groups
  • Energy is stored in the high-energy phosphate bonds between the phosphate groups
  • Hydrolysis of ATP to ADP (adenosine diphosphate) + Pi (inorganic phosphate) releases energy for cellular processes
  • ATP is regenerated from ADP + Pi through substrate-level phosphorylation or oxidative phosphorylation
  • Other high-energy compounds also play important roles in energy transfer
    • GTP (guanosine triphosphate) is involved in protein synthesis and signal transduction
    • Phosphocreatine serves as an energy reservoir in muscle cells
  • NADH and FADH2 are electron carriers that transfer electrons during cellular respiration

Catabolic Pathways: Breaking It Down

  • Catabolic pathways break down complex molecules into simpler ones, releasing energy
  • Cellular respiration is a major catabolic pathway that breaks down glucose to release energy
    • Occurs in three stages: glycolysis, Krebs cycle (citric acid cycle), and electron transport chain
  • Glycolysis takes place in the cytoplasm and breaks down glucose into two pyruvate molecules
    • Produces a net gain of 2 ATP and 2 NADH molecules
  • Pyruvate enters the mitochondria and is converted to acetyl-CoA, which enters the Krebs cycle
  • Krebs cycle oxidizes acetyl-CoA, generating CO2, 3 NADH, 1 FADH2, and 1 GTP (or ATP) per cycle
  • Electron transport chain (ETC) is the final stage of cellular respiration
    • NADH and FADH2 donate electrons to the ETC, creating a proton gradient across the inner mitochondrial membrane
    • Proton gradient drives ATP synthesis through oxidative phosphorylation via ATP synthase
  • Other catabolic pathways include beta-oxidation of fatty acids and amino acid catabolism

Anabolic Pathways: Building It Up

  • Anabolic pathways construct complex molecules from simpler ones, requiring an input of energy
  • Photosynthesis is a major anabolic pathway in plants that converts light energy into chemical energy
    • Light-dependent reactions capture light energy and generate ATP and NADPH
    • Calvin cycle (light-independent reactions) uses ATP and NADPH to fix CO2 into glucose
  • Gluconeogenesis is the synthesis of glucose from non-carbohydrate precursors (amino acids, lactate, glycerol)
    • Occurs primarily in the liver and is important for maintaining blood glucose levels during fasting
  • Lipogenesis is the synthesis of fatty acids and triglycerides from excess carbohydrates
    • Occurs in the liver and adipose tissue, storing energy for later use
  • Amino acid synthesis pathways produce essential and non-essential amino acids
    • Essential amino acids cannot be synthesized by the body and must be obtained from the diet
  • Nucleotide synthesis pathways generate purine and pyrimidine nucleotides for DNA and RNA synthesis

Regulation: Keeping Things in Check

  • Metabolic regulation ensures that cells maintain homeostasis and respond to changing energy needs
  • Allosteric regulation involves the binding of effectors (activators or inhibitors) to enzymes at sites other than the active site
    • Effector binding causes conformational changes that alter enzyme activity
    • Example: ATP allosterically inhibits phosphofructokinase (PFK) in glycolysis to prevent excessive ATP production
  • Feedback inhibition occurs when the end product of a pathway inhibits an earlier enzyme in the pathway
    • Helps prevent accumulation of excess products and maintains homeostasis
    • Example: Isoleucine inhibits threonine deaminase, the first enzyme in its own biosynthetic pathway
  • Hormonal regulation allows for long-term control of metabolic pathways
    • Insulin promotes glucose uptake and storage (glycogenesis) while inhibiting glucose production (gluconeogenesis)
    • Glucagon stimulates glucose production (glycogenolysis and gluconeogenesis) during fasting
  • Transcriptional regulation controls the expression of genes encoding metabolic enzymes
    • Transcription factors (activators or repressors) bind to specific DNA sequences to regulate gene expression
    • Example: SREBP (sterol regulatory element-binding protein) activates genes involved in lipid synthesis when cellular cholesterol levels are low

Connecting the Dots: Metabolic Integration

  • Metabolic pathways are interconnected and work together to maintain cellular homeostasis
  • Glucose-6-phosphate is a central metabolite that connects several pathways
    • Can enter glycolysis for energy production, pentose phosphate pathway for NADPH and ribose production, or glycogenesis for storage
  • Acetyl-CoA is another key metabolite that links carbohydrate, lipid, and amino acid metabolism
    • Produced from pyruvate (carbohydrates), fatty acids (lipids), and certain amino acids
    • Can enter the Krebs cycle for energy production or be used for fatty acid and cholesterol synthesis
  • Amino acids can be used for protein synthesis or catabolized for energy production
    • Glucogenic amino acids can be converted to glucose via gluconeogenesis
    • Ketogenic amino acids can be converted to ketone bodies or fatty acids
  • Metabolic flexibility allows organisms to adapt to different fuel sources depending on availability
    • During fasting, the body shifts from glucose to fatty acids and ketone bodies for energy production
    • Exercise promotes the use of glucose and fatty acids for energy production in skeletal muscle

Real-World Applications

  • Understanding metabolism is crucial for developing treatments for metabolic disorders
    • Type 2 diabetes is characterized by insulin resistance and impaired glucose metabolism
    • Obesity is associated with dysregulation of lipid metabolism and increased risk of metabolic diseases
  • Metabolic engineering involves modifying metabolic pathways to produce desired compounds
    • Genetically engineered bacteria can produce insulin, biofuels, and other valuable products
    • Plants can be engineered to enhance nutrient content (golden rice with increased vitamin A) or resistance to environmental stresses
  • Cancer metabolism is a key target for developing new therapies
    • Cancer cells exhibit altered metabolism, relying heavily on aerobic glycolysis (Warburg effect)
    • Targeting metabolic vulnerabilities in cancer cells can lead to new treatment strategies
  • Personalized nutrition and precision medicine take into account individual metabolic differences
    • Genetic variations can influence enzyme activities and nutrient requirements
    • Tailoring diets and treatments based on metabolic profiles can optimize health outcomes
  • Athletic performance can be enhanced by understanding exercise metabolism
    • Training adaptations improve the efficiency of energy production and utilization in skeletal muscle
    • Nutritional strategies (carbohydrate loading, ketone supplementation) can support optimal performance


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© 2024 Fiveable Inc. All rights reserved.
AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.