Cellular organelles are the tiny powerhouses that keep our cells running smoothly. From the nucleus calling the shots to mitochondria cranking out energy, each organelle has a crucial job. Without them, our cells would be a chaotic mess.

These microscopic machines work together like a well-oiled factory. The endoplasmic reticulum and Golgi apparatus team up to make and ship proteins, while lysosomes and peroxisomes handle waste management. It's a complex dance that keeps our cells alive and kicking.

Eukaryotic Cell Organelles

Key Organelles and Their Functions

• Eukaryotic cells contain membrane-bound organelles performing specialized functions distinguishing them from prokaryotic cells
• Major organelles include nucleus, mitochondria, endoplasmic reticulum, Golgi apparatus, lysosomes, and peroxisomes
• Plant cells possess additional organelles
  • Chloroplasts enable photosynthesis
  • Central vacuoles maintain cell turgor pressure
  • Cell walls provide structural support
• Cytoskeleton provides structural support and facilitates intracellular transport
  • Composed of microfilaments (actin), intermediate filaments, and microtubules
• Ribosomes synthesize proteins
  • Found free in cytoplasm and attached to endoplasmic reticulum
  • Composed of ribosomal RNA and proteins

Organelle Diversity and Specialization

• Organelle number and morphology vary depending on cell type and function
  • Muscle cells contain numerous mitochondria for energy production
  • Secretory cells have extensive endoplasmic reticulum and Golgi apparatus
• Specialized organelles exist in certain cell types
  • Melanosomes in melanocytes produce and store melanin pigments
  • Weibel-Palade bodies in endothelial cells store clotting factors (von Willebrand factor)
• Some organelles work together in functional units
  • Endoplasmic reticulum and Golgi apparatus form the endomembrane system
  • Mitochondria and peroxisomes collaborate in fatty acid metabolism

Structure and Function of the Nucleus

Nuclear Envelope and Chromatin

• Nuclear envelope encloses nucleus
  • Double membrane structure with nuclear pores
  • Nuclear pores regulate molecular passage between nucleus and cytoplasm
• Chromatin contained within nucleus
  • Composed of DNA and associated proteins (histones)
  • Condenses into chromosomes during cell division
• Nucleolus synthesizes ribosomal RNA and assembles ribosomes
  • Dense region within nucleus
  • Site of rRNA transcription and ribosome subunit assembly

Gene Regulation and Nuclear Transport

• Nucleus functions as cell's control center
  • Houses genetic material
  • Regulates gene expression through transcription and RNA processing
• Nuclear localization signals (NLS) direct proteins into nucleus
  • Short amino acid sequences recognized by importin proteins
• Nuclear export signals (NES) facilitate protein export from nucleus
  • Leucine-rich sequences recognized by exportin proteins
• Nuclear transport occurs through nuclear pore complexes
  • Large protein assemblies spanning nuclear envelope
  • Allow selective passage of molecules based on size and signals

Mitochondria in Energy Production

Mitochondrial Structure and Organization

• Double-membrane organelles with highly folded inner membrane (cristae)
  • Cristae increase surface area for energy production
• Mitochondrial matrix contains multiple copies of mitochondrial DNA
  • Circular DNA encoding essential proteins for electron transport chain
• Matrix houses enzymes for citric acid cycle
  • Key metabolic pathway producing NADH and FADH2 for electron transport chain
• Mitochondrial number and morphology vary by cell type
  • More metabolically active cells (muscle, liver) contain higher numbers
  • Mitochondria can fuse and divide (fission) to adapt to cellular energy demands

Oxidative Phosphorylation and ATP Production

• Oxidative phosphorylation occurs in inner mitochondrial membrane
  • Electron transport chain generates proton gradient
  • ATP synthase uses proton gradient to produce ATP
• Mitochondria serve as primary site of cellular respiration
  • Convert glucose and other organic molecules into usable energy (ATP)
• ATP production efficiency varies by substrate
  • Glucose oxidation yields ~30-32 ATP molecules
  • Fatty acid oxidation produces more ATP per carbon atom than glucose

Protein Synthesis and Transport

Endoplasmic Reticulum Functions

• Endoplasmic reticulum (ER) exists in two forms
  • Rough ER studded with ribosomes
  • Smooth ER lacks ribosomes
• Rough ER involved in protein synthesis and processing
  • Synthesizes proteins destined for secretion or membrane incorporation
  • Facilitates protein folding and initial glycosylation
• Smooth ER performs diverse functions
  • Synthesizes lipids (phospholipids, cholesterol)
  • Stores and regulates calcium levels
  • Detoxifies drugs and harmful substances (liver cells)

Golgi Apparatus and Protein Modification

• Golgi apparatus consists of stacked, flattened membrane sacs (cisternae)
  • Cis face receives proteins from ER
  • Trans face packages and ships modified proteins
• Modifies proteins received from ER
  • Glycosylation adds and modifies sugar chains
  • Phosphorylation adds phosphate groups to proteins
  • Proteolytic cleavage cuts proteins into active forms
• Sorts and packages proteins for various destinations
  • Secretory vesicles for exocytosis
  • Lysosomes for intracellular digestion
  • Plasma membrane for integration

Cellular Waste Management

Lysosomal Structure and Function

• Lysosomes contain hydrolytic enzymes for cellular debris breakdown
  • Digest damaged organelles, cellular waste, and ingested materials
• Maintain acidic environment (pH ~4.5-5.0)
  • Proton pumps in lysosomal membrane maintain acidity
  • Acidic pH optimal for lysosomal enzyme activity
• Play critical role in autophagy
  • Cell's self-eating process for recycling components
  • Important during stress or starvation periods

Peroxisome Metabolism and Detoxification

• Single-membrane organelles containing oxidative enzymes
  • Break down fatty acids and amino acids
• Catalase enzyme decomposes hydrogen peroxide (H2O2)
  • Protects cell from oxidative damage
  • H2O2 + H2O2 → 2H2O + O2
• Collaborate with mitochondria in fatty acid metabolism
  • β-oxidation of very long-chain fatty acids
• Synthesize specialized lipids
  • Plasmalogens important for cell membrane structure
  • Bile acids for lipid digestion (liver cells)