Membrane Dynamics

Homeostasis

Homeostasis refers to the maintenance of a stable internal environment within the body, despite changes in external conditions. It is essential for proper cellular function and overall health.

• Extracellular Fluid (ECF): The fluid outside cells, including interstitial fluid (between cells) and plasma (in blood vessels).

• Intracellular Fluid (ICF): The fluid within cells.

• Chemical Composition: ECF and ICF differ in their concentrations of ions and molecules, which is crucial for cellular processes.

• Equilibria:

  • Osmotic Equilibrium: Water moves freely between compartments to balance solute concentrations.

  • Chemical Disequilibrium: Solute concentrations differ between ECF and ICF.

  • Electrical Disequilibrium: There is a difference in charge across the cell membrane.

Transport Processes

Transport processes move substances across cell membranes, either passively or actively, and are vital for maintaining homeostasis.

• Penetrating vs. Non-penetrating Solutes: Penetrating solutes can cross the membrane, while non-penetrating solutes cannot.

• Osmosis: Movement of water across a semipermeable membrane from low to high solute concentration.

  • Isosmotic: Solutions with equal osmolarity.

  • Hyperosmotic: Solution with higher osmolarity.

  • Hyposmotic: Solution with lower osmolarity.

• Tonicity: The effect of a solution on cell volume.

  • Isotonic: No net movement of water; cell volume remains unchanged.

  • Hypertonic: Water leaves the cell; cell shrinks.

  • Hypotonic: Water enters the cell; cell swells.

• Osmolarity and Tonicity of Saline: Important for IV solutions to avoid damaging cells.

• Gradients:

  • Chemical Gradient: Difference in solute concentration.

  • Electrochemical Gradient: Combined effect of chemical and electrical gradients.

• Diffusion: Passive movement of molecules from high to low concentration.

• Protein-Mediated Transport:

  • Carrier Proteins: Transport specific molecules.

    • Water Channels

    • Ion Channels (open/gated)

    • Transporter specificity, competition, saturation

  • Facilitated Diffusion: Passive transport via carrier proteins.

  • Active Transport: Requires energy (ATP).

    • Primary: (direct use of ATP)

    • Secondary: (uses gradient created by primary transport)

    • Sodium-Potassium Pump: Maintains gradients by pumping Na+ out and K+ in.

• Vesicular Transport:

  • Phagocytosis:

  • Endocytosis:

  • Exocytosis:

• Epithelial Transport:

  • Paracellular: (between cells)

  • Transcellular: (through cells)

  • Transcytosis: (combination of endo- and exocytosis)

Energy Requirements: Passive transport does not require energy; active transport and vesicular transport do.

The Resting Membrane Potential

The resting membrane potential is the electrical charge difference across the cell membrane when the cell is at rest.

• Chemical Disequilibrium: Difference in ion concentrations between ICF and ECF.

• Leak Channels: Allow ions to move down their gradients, contributing to membrane potential.

• Membrane Potential: Typically -70 mV in neurons.

  • Generated by Na+/K+ pump and leak channels.

Equation:

(Nernst equation for potassium)

Cellular Communication

Types of Cellular Communication

Cells communicate to coordinate functions and respond to changes. Communication can be local or long-distance.

• Local Communication:

  • Contact-dependent: (cell-to-cell)

  • Paracrine: (nearby cells)

  • Autocrine: (self-signaling)

• Long-distance Communication:

  • Hormones: (endocrine system)

  • Neurocrines: (nervous system)

• Cytokines: Regulatory proteins for immune responses.

Signal Pathways

Signal pathways involve the transmission of information from the cell surface to intracellular targets, resulting in a cellular response.

• Signaling Molecules:

  • Lipophilic: (can cross membranes)

  • Lipophobic: (cannot cross membranes)

• Membrane Receptor Proteins:

  • G Protein-Coupled Receptors (GPCR):

    • 3-part transducer receptor:

    • ATP converted to cAMP:

    • cAMP activates PKA:

    • PKA phosphorylates other proteins:

  • Receptor-Enzymes: Protein kinases (e.g., tyrosine kinase)

• Intracellular Signal Molecules:

  • Second messengers (e.g., calcium ions, cAMP)

• Target Proteins: Proteins that carry out the response.

• Response: The final effect of the signaling pathway.

Signal Transduction

Signal transduction is the process by which a cell converts an extracellular signal into a functional response.

• Amplification: One signal molecule can activate many downstream molecules.

• Signaling Cascades: Series of steps leading to a response.

Novel Signal Molecules

Some signaling molecules are unique and play specialized roles in communication.

• Gases (e.g., nitric oxide):

• Lipids:

• Calcium:

Modulation of Signal Pathways

Cells can regulate their sensitivity to signals by upregulating or downregulating receptors.

• Upregulation: Increase in receptor number.

• Downregulation: Decrease in receptor number.

• Agonists: Molecules that activate receptors.

• Antagonists: Molecules that block receptors.

Homeostatic Reflex Pathways

Homeostatic reflex pathways maintain internal stability through feedback mechanisms.

• Cannon's Postulates: Principles describing homeostatic regulation.

• Tonic Control: Ongoing regulation by a single system.

• Antagonistic Control: Opposing effects by different systems.

• Homeostatic Control Systems: Integrate signals to maintain balance.

Additional Review Questions

• Does homeostasis mean that your body is in equilibrium?:

• How do substances get moved against their concentration gradient?:

• Do exocytosis and endocytosis require an input of cellular energy?:

• What is responsible for the resting membrane potential?:

• What makes up the ECF?:

• Explain what it means for an enzyme to be saturated.:

• What are the 5 steps of a general signaling pathway?:

• Give some examples of signaling molecules, receptor subtypes, and second messengers:

• What are some novel signaling molecules?:

• What does it mean for a receptor to be up or down regulated?:

• What are Cannon's postulates?:

Example: The sodium-potassium pump is an example of primary active transport, using ATP to move sodium and potassium ions against their concentration gradients, which is essential for maintaining the resting membrane potential.

Additional info: Some explanations and examples have been expanded for clarity and completeness based on standard Anatomy & Physiology curriculum.