Ficha de revisão: Human Cell Structure and Function

📋 Course Outline

1. Human cell organization and protoplasm
2. Nucleus and nucleoli functions
3. Ribosomes and protein translation
4. Endoplasmic reticulum and Golgi processing
5. Lysosomes, peroxisomes, and secretory vesicles
6. Mitochondria and ATP energy production
7. Cytoskeleton and cell membrane transport
8. Endocytosis and intracellular digestion
9. Cell signaling: juxtacrine, paracrine, endocrine

📖 1. Human cell organization and protoplasm

🔑 Key Concepts & Definitions

• Cell membrane : A cell membrane is a selectively permeable boundary that controls what enters and leaves the cell and helps maintain internal conditions.
• Cell membrane proteins : Cell membrane proteins are specialized molecules embedded in the membrane that enable transport, signaling, and cell-to-cell interactions.
• Endoplasmic reticulum : The endoplasmic reticulum is an internal membrane network that supports synthesis and processing of proteins and lipids.
• Golgi apparatus : The Golgi apparatus is a membrane organelle that modifies, sorts, and packages proteins and lipids for their final destinations.
• Mitochondria : Mitochondria are organelles that generate chemical energy by producing ATP through cellular respiration.

📝 Essential Points

• The cell membrane’s selective permeability depends on its lipid bilayer and embedded proteins, which together regulate transport.
• Endocytosis moves material into the cell by invagination of the membrane, allowing uptake of external substances.
• Pinocytosis is endocytosis of fluid and small solutes, whereas phagocytosis is endocytosis of larger particles.
• The endoplasmic reticulum has distinct roles: one region supports protein synthesis and another supports lipid-related synthesis.
• The Golgi apparatus modifies cargo after ER delivery, then sorts it into vesicles for secretion or delivery to other organelles.
• Mitochondria convert energy stored in nutrients into ATP, linking cellular metabolism to energy supply.

💡 Memory Hook

Membrane controls entry; ER builds; Golgi edits and ships; mitochondria power the cell.

📖 2. Nucleus and nucleoli functions

🔑 Key Concepts & Definitions

• Nucleus : The nucleus is the cell compartment that stores genetic material and coordinates key control processes for the cell.
• Nuclear membrane : The nuclear membrane is the boundary that separates the nucleus from the cytoplasm.
• Nucleolus : The nucleolus is a specialized nuclear region involved in producing ribosomal components for protein synthesis.
• Cytoplasm : The cytoplasm is the region outside the nucleus that includes cytosol and organelles where many cellular activities occur.

📝 Essential Points

• A cell has two major compartments under light microscopy: nucleus and cytoplasm (cytosol plus organelles).
• The nuclear membrane separates the nucleus from the cytoplasm.
• The cytoplasm is separated from the outside environment by the cell (plasma) membrane.
• The nucleolus functions in making ribosomal components needed for building ribosomes.
• Nucleus and cytoplasm compartmentalization supports organized control versus execution of cellular processes.

💡 Memory Hook

Nucleus = “control center”; nucleolus = “ribosome workshop” inside the nucleus.

📖 3. Ribosomes and protein translation

🔑 Key Concepts & Definitions

• Ribosomes : Ribosomes are small RNA–protein particles present in large numbers that carry out translation by reading mRNA to build proteins.
• Translation : Translation is the process that converts the mRNA code into a chain of amino acids that forms a protein.
• Ribosome subunits : Ribosomes are built from two parts, a large subunit and a small subunit, that together perform translation.
• Nucleolus : The nucleolus is a darker nuclear structure made mainly of RNA and proteins that forms in response to nuclear transcription.

📝 Essential Points

• Ribosomes are found in great number in all human cells.
• Ribosomes are primarily composed of RNA plus some small proteins.
• Each ribosome has two subunits: one large and one small.
• Translation uses the mRNA sequence to assemble amino-acid chains (proteins).
• The nucleolus contains accumulated RNA and proteins.
• The nucleolus enlarges when the cell is actively synthesizing proteins.

💡 Memory Hook

Ribosomes = RNA machines: mRNA → amino acids → proteins.

📖 4. Endoplasmic reticulum and Golgi processing

🔑 Key Concepts & Definitions

• Endoplasmic reticulum : The endoplasmic reticulum is a cytoplasmic network of tubules and vesicles that processes and transports molecules made by the cell.
• Rough endoplasmic reticulum : Rough endoplasmic reticulum is the ER region with ribosomes attached that synthesizes new proteins for the cell.
• Smooth endoplasmic reticulum : Smooth endoplasmic reticulum is the ER region without ribosomes that synthesizes lipid substances for the cell.
• Golgi apparatus : The Golgi apparatus is an organelle made of stacked, flattened vesicle layers that receives ER transport vesicles for further processing.

📝 Essential Points

• The ER membrane is continuous with the outer nuclear membrane, so ER lumen connects with the space between nuclear membrane layers.
• The ER surface area can reach about 30–40× the surface area of the cell membrane.
• Rough ER ribosomes translate mRNA from the nucleus, sending many proteins into the ER tubule interior rather than only into cytosol.
• Many rough-ER proteins are enzymes that help detoxify potentially damaging substances.
• Smooth ER mainly synthesizes phospholipids and cholesterol, which are inserted into the ER membrane to drive ER growth.
• Transport vesicles pinch off from the ER and rapidly fuse with the Golgi for additional processing into lysosomes, secretory vesicles, or other components.

💡 Memory Hook

Rough ER = Ribosomes + Proteins; Smooth ER = no Ribosomes + Lipids; Golgi = packages ER cargo.

📖 5. Lysosomes, peroxisomes, and secretory vesicles

🔑 Key Concepts & Definitions

• Lysosomes : Lysosomes are vesicular organelles that act as the cell’s internal digestive system for unwanted materials.
• Secretory vesicles : Secretory vesicles are Golgi-derived transport packets that carry substances toward the cell membrane for release.
• Peroxisomes : Peroxisomes are vesicular organelles that detoxify compounds using oxidizing chemistry.
• Hydrolase enzymes : Hydrolase enzymes are digestive enzymes inside lysosomes that break down damaged structures and ingested material.
• Oxidases : Oxidases are enzymes in peroxisomes that drive oxidation reactions using hydrogen peroxide.

📝 Essential Points

• Lysosomes form when the Golgi processes transported ER products into lysosomal components.
• Secretory vesicles form when the Golgi packages ER secretions into concentrated packets.
• Secretory vesicles move to the cell membrane and release contents to the exterior by exocytosis.
• Calcium entry is generally the external trigger that initiates exocytosis and helps replenish the membrane bilayer.
• Lysosomes digest damaged structures, endocytosed food particles, and foreign objects such as bacterial cells.
• Lysosomes contain hydrolase enzymes, which enable intracellular digestion of their targets.

💡 Memory Hook

Lysosomes = “Hydrolase” (break down); Peroxisomes = “Oxidase + H2O2” (detox); Secretory vesicles = “Exocytosis” (release).

📖 6. Mitochondria and ATP energy production

🔑 Key Concepts & Definitions

• Mitochondria : Mitochondria are organelles that generate most of the cell’s chemical energy needed for cellular activity.
• Cristae : Cristae are folds of the inner mitochondrial membrane that increase surface area for ATP-producing reactions.
• Adenosine Triphosphate : Adenosine triphosphate (ATP) is a high-energy molecule that serves as the cell’s primary energy currency.
• Krebs Cycle : The Krebs cycle is a mitochondrial pathway that contributes to producing ATP by generating energy-rich intermediates.
• Electron Transport : Electron transport is a mitochondrial process that uses electrons to drive ATP production.

📝 Essential Points

• Mitochondria are present in every body cell, but their number and distribution vary with local energy demand.
• Mitochondria have two lipid bilayers: an outer membrane and an inner membrane.
• ATP production depends on the inner membrane’s large surface area created by cristae.
• Cells obtain energy mainly from foods, which are converted into glucose, fatty acids, and amino acids before entering cells.
• Krebs cycle and electron transport together produce ATP inside mitochondria.
• ATP energy is used for membrane transport against gradients, synthesis of chemical compounds, and mechanical work such as muscle contraction.

💡 Memory Hook

Cristae = “more folds, more ATP”: inner-membrane shelves expand the reaction surface for ATP-making.

📖 7. Cytoskeleton and cell membrane transport

🔑 Key Concepts & Definitions

• Cytoskeleton : The cytoskeleton is a cell structure that supports the cell and certain cell parts, helping maintain cell shape.
• Cell membrane : The cell membrane, also called the plasma membrane, is a thin elastic barrier made mostly of lipids and proteins.
• Phospholipid bilayer : The phospholipid bilayer is the membrane’s basic lipid arrangement that creates a barrier to many water-soluble substances.
• Integral proteins : Integral proteins are membrane proteins that span the membrane and often form channels for passage of water-soluble substances, especially ions.
• Peripheral proteins : Peripheral proteins are membrane proteins attached to the membrane surface rather than spanning it through the bilayer.

📝 Essential Points

• The cytoskeleton helps maintain cell shape by providing internal support for the cell.
• The plasma membrane is largely composed of lipids and proteins and is thin and elastic.
• Because the membrane is a phospholipid bilayer, it blocks penetration by water-soluble substances.
• Fat-soluble substances such as oxygen, CO2, and ethanol cross the plasma membrane easily.
• Water-soluble substances like ions, glucose, and urea cannot cross freely and typically require membrane proteins to move in or out.
• Integral proteins pass through the membrane and many act as structural channels for ions and other water-soluble solutes.

💡 Memory Hook

Phospholipid bilayer = “fat passes, water stalls.”

📖 8. Endocytosis and intracellular digestion

🔑 Key Concepts & Definitions

• Phagocytosis : Phagocytosis is an endocytic process where a cell engulfs pathogens or particles into a vesicle for internal breakdown.
• Pinocytosis : Pinocytosis is an endocytic process where a cell internalizes extracellular fluid and dissolved substances into small vesicles.
• Lysosome–vesicle fusion : Lysosome–vesicle fusion is the bilayer fusion event that rapidly attaches lysosomes to newly formed endocytic vesicles.
• Digestive vesicle : A digestive vesicle is the endocytic compartment formed after lysosome enzymes are released into the ingested material.
• Autophagy : Autophagy is intracellular digestion where damaged or worn organelles are enclosed in an autophagosome and then fused with a lysosome.

📝 Essential Points

• Only certain cells can perform phagocytosis, including tissue macrophages and some other white blood cells.
• After pinocytotic or phagocytic vesicles appear, lysosomes attach very quickly via bilayer fusion.
• Lysosome enzymes are emptied into the vesicle, turning the vesicle into a site of digestion.
• Autophagy uses autophagosomes to engulf worn or damaged organelles, which then fuse with lysosomes.
• The digested products from endocytosis and autophagy can be reused by the cell as nutrients.

💡 Memory Hook

Endocytosis makes a vesicle; lysosomes fuse fast; enzymes dump; digestion happens; autophagy recycles organelles.

📖 9. Cell signaling: juxtacrine, paracrine, endocrine

🔑 Key Concepts & Definitions

• Juxtacrine signaling : Cell signaling where a signal acts at very short range through direct contact between neighboring cells.
• Paracrine signaling : Cell signaling where a cell releases a local messenger that diffuses to nearby target cells.
• Endocrine signaling : Cell signaling where hormones are released into the bloodstream to act on distant target cells.
• G6PD deficiency : An X-linked recessive enzyme disorder in which red cells are vulnerable to oxidative stress from triggers.

📝 Essential Points

• Juxtacrine signaling requires physical proximity or direct cell-to-cell interaction rather than diffusion through body fluids.
• Paracrine signaling affects nearby cells because the messenger concentration falls with distance from the secreting cell.
• Endocrine signaling can reach distant targets because hormones travel systemically via the bloodstream.
• G6PD deficiency is associated with hemolytic anemia when oxidative stress occurs, while baseline health is often normal.
• Oxidative stress triggers include certain drugs and infections, which lead to RBC damage and hemolysis.
• In G6PD deficiency, oxidized hemoglobin forms Heinz bodies and damaged RBCs are removed by the spleen, causing anemia with ↑LDH, ↑bilirubin, and reticulocytosis.

💡 Memory Hook

Juxta = touch, Para = nearby, Endo = blood (distant).

📊 Synthesis Tables

Endocytosis types

Juxtacrine vs Paracrine vs Endocrine

⚠️ Common Pitfalls & Confusions

1. Mixing up compartments: the nucleus is separated from cytoplasm by the nuclear membrane, while the cytoplasm is separated from outside fluid by the cell (plasma) membrane.
2. Confusing ER regions: rough ER has ribosomes and primarily synthesizes proteins, while smooth ER lacks ribosomes and primarily synthesizes lipids (phospholipids and cholesterol).
3. Assuming all endocytosis is the same: pinocytosis ingests minute particles/fluids, whereas phagocytosis involves large particles (only certain cells can do phagocytosis).
4. Forgetting the trigger and outcome of exocytosis: calcium entry generally triggers exocytosis, and secretory vesicles replenish the membrane bilayer by adding bilayer.
5. Thinking lysosomes and peroxisomes do the same chemistry: lysosomes contain hydrolase enzymes for digestion, while peroxisomes contain oxidases that use hydrogen peroxide for oxidation/detoxification.
6. Misstating ATP production: ATP is produced in mitochondria via Krebs cycle and electron transport, and cristae increase inner-membrane surface area for these reactions.
7. Overlooking the G6PD mechanism: oxidative stress oxidizes hemoglobin causing Heinz bodies and membrane damage, leading to hemolytic anemia with elevated LDH, bilirubin, and reticulocytosis.

✅ Exam Checklist

1. Identify the two major compartments under light microscopy and state what separates the nucleus from cytoplasm and cytoplasm from the outside (nuclear membrane vs cell/plasma membrane).
2. List the five protoplasm substances (water, ions, proteins, lipids, carbohydrates) and state the main roles given (e.g., lipids form membrane barriers; carbohydrates mainly provide nutrition).
3. Describe nucleus functions as the control center for messages managing growth, maturation, replication, or apoptosis, and connect gene expression to lifelong cell function.
4. Explain nucleolus composition and trigger: nucleolar RNA and proteins are produced by nuclear transcription, and nucleoli enlarge during active protein synthesis.
5. Explain ribosome structure and function: ribosomes are RNA plus some small proteins, have large and small subunits, and perform translation converting mRNA code into amino-acid chains (proteins).
6. Explain ER organization and connectivity: ER membrane is continuous with the outer nuclear envelope, and ER lumen connects with the space between nuclear membrane layers.
7. Differentiate rough vs smooth ER by appearance and primary products: rough ER has ribosomes and synthesizes new proteins (often enzymes for detoxification), while smooth ER lacks ribosomes and synthesizes lipids (phospho
8. cholesterol) that drive ER growth.
9. Trace the ER-to-Golgi-to-vesicle pathway: transport vesicles pinch off from ER, fuse quickly with Golgi, and Golgi processes cargo into lysosomes, secretory vesicles, or other components.
10. Describe secretory vesicle release: secretory vesicles drift to the cell membrane, fuse, and empty contents to the exterior by exocytosis, generally triggered by calcium entry and replenishing the membrane bilayer.
11. Describe lysosome and peroxisome roles and enzymes: lysosomes digest damaged structures/food/foreign objects using hydrolase enzymes, while peroxisomes use oxidases and hydrogen peroxide to oxidize substances that could/
12. otherwise be poisonous.
13. Explain mitochondria energy production: two lipid bilayers with cristae increasing surface area, ATP as primary energy currency, and ATP production via Krebs cycle and electron transport; state three categories of ATP-re
14. quiring cellular functions (membrane transport against gradients, synthesis of chemical compounds, mechanical work).