Chapter 2: Biochemistry of the Cell Back To Chapter

2.11: pH Regulation in Cells

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pH Regulation in Cells

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pH is a measure of H⁺ concentration in a solution and indicates its level of acidity or alkalinity.

The pH scale ranges from 0 to 14, where seven is considered neutral, a value below seven is acidic, and a value above seven is basic.

The typical cytoplasmic pH lies in a slightly alkaline range of 7.0 to 7.4. Large variations in this intracellular pH can affect critical cellular processes, such as metabolism, membrane potential, and signaling pathways.

For instance, CO₂ – the end product of cellular respiration, combines with H₂O to form H₂CO₃.

H₂CO₃ is a weak acid that readily dissociates, slowly acidifying the cytoplasm and leading to cellular stress.

Therefore, cells regulate their internal pH using ion exchangers to alter the hydrogen ion concentration.

The Na⁺/H⁺exchanger helps to balance the intracellular pH by coupling the efflux of H⁺ with the influx of Na⁺.

Similarly, Cl⁻-HCO₃⁻ exchangers play an important role in maintaining intracellular pH by effluxing HCO₃⁻ ions in exchange for Cl⁻ ions.

2.11: pH Regulation in Cells

pH plays a critical role in maintaining normal cellular activities. It helps maintain the structure and function of various proteins, dictates the charge on cellular membranes, and is crucial for metabolic reactions inside the cell. Moreover, cells use the energy from the proton motive force to generate ATP.

Cytosolic pH

Under physiological conditions, the cytosolic pH is slightly more acidic than the extracellular pH. However, cells must prevent further acidification of their cytosol to maintain their membrane potential and carry out normal functioning. Therefore, they employ several specialized proton-translocating machinery—antiporters, symporters, and proton-pumping ATPases—to tightly regulate the steady-state pH.

Cellular Organelles and pH Homeostasis

The compartmentalization inside the eukaryotic cells helps to provide distinct environmental conditions to carry out specific functions within different membrane-enclosed organelles. The internal pH in these different compartments is highly variable, but it is an important determinant of their effective functioning.

For example, cytochromes located on the inner mitochondrial membrane efflux protons using energy from electron flow. This helps to establish a proton gradient across the mitochondrial membrane that is used to generate chemical energy in the form of ATP. Similarly, lysosomes maintain an internal acidic pH by pumping protons from the cytosol using energy from ATP hydrolysis. This is essential for the functioning of the lysosomal enzymes.

However, some organelles, including the nucleus, endoplasmic reticulum, and peroxisomes, need to maintain their internal pH in equilibrium with the cytoplasm. Therefore, they lack intrinsic pH-regulatory systems and are highly permeable to protons.

Dysregulation of Intracellular pH

Certain metabolic or genetic conditions may disrupt the steady-state pH of the cytoplasm or the organelles inside the cell and lead to disease. For example, mutations in chloride carriers, such as CLCN6 and CLCN7, present on late endosomes and lysosomes have been linked to osteoporosis and lysosomal storage disease. Similarly, mutations in the CLCN5 channel hinder luminal acidification and production of early endosomes in renal epithelial cells and can eventually lead to kidney failure.

2.11: pH Regulation in Cells

Chapter 1: Cells, Genomes, and Evolution

Chapter 2: Biochemistry of the Cell

Chapter 3: Energy and Catalysis

Chapter 4: Introduction to Metabolism

Chapter 5: Protein Structure

Chapter 6: Protein Function

Chapter 7: Structure and Organization of DNA

Chapter 8: DNA Replication and Repair

Chapter 9: Transcription: DNA to RNA

Chapter 10: Translation: RNA to Protein

Chapter 11: Control of Gene Expression

Chapter 12: Membrane Structure and Components

Chapter 13: Membrane Transport and Active Transporters

Chapter 14: Channels and the Electrical Properties of Membranes

Chapter 15: Transmembrane Transport in Endoplasmic Reticulum and Peroxisomes

Chapter 16: Intracellular Compartments and Protein Sorting

Chapter 17: Intracellular Membrane Traffic

Chapter 18: Endocytosis and Exocytosis

Chapter 19: Mitochondria and Energy Production

Chapter 20: Chloroplasts and Photosynthesis

Chapter 21: Principles of Cell Signaling

Chapter 22: Signaling Networks of G Protein-coupled Receptors

Chapter 23: Signaling Networks of Kinase Receptors

Chapter 24: Alternative Signaling Routes in Gene Expression

Chapter 25: The Cytoskeleton I: Actin and Microfilaments

Chapter 26: The Cytoskeleton II: Microtubules and Intermediate Filaments

Chapter 27: Extracellular Matrix in Animals

Chapter 28: Cell-Matrix Interactions

Chapter 29: Cell-Cell Interactions

Chapter 30: Cell Polarization and Migration

Chapter 31: Plant Cell Structure and Organization

Chapter 32: Analyzing Cells and Proteins

Chapter 33: Visualizing Cells, Tissues, and Molecules

Chapter 34: Cell Proliferation

Chapter 35: Cell Division

Chapter 36: Meiosis

Chapter 37: Cell Death

Chapter 38: Cancer

Chapter 39: Stem Cell Biology And Renewal in Epithelial Tissue

Chapter 40: A Hierarchical Stem-Cell System: Blood Cell Formation

Chapter 41: Fibroblast Transformation and Muscle Stem Cells

Chapter 42: Regeneration and Repair

Chapter 43: Embryonic and Induced Pluripotent Stem Cells

2.11: pH Regulation in Cells

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