AP Biology Unit 2: Cell Structure and Function
flaccid
has a water potential of 0 megapascals Water diffuses out of the cell if the solute in the external environment is more concentrated (plasmolysis)- which causes it to shrink
hydrophilic substances
Hydrophilic substances such as large polar molecules and ions cannot move freely across the membrane Hydrophilic substances move with help from transfer proteins
Chloroplast comparmentalization
Same membrane folding Thylakoids are highly folded membrane compartments that increase the efficiency of light dependent reactions
What can go through the cell membrane?
Small molecules can pass freely: N2, O2, CO2
integral proteins
Spans the membrane Hydrophilic with charged and polar side groups Hydrophobic with nonpolar side groups penetrate hydrophobic interior of bilayer
symplast
entire mass of cytosol of all the living cells in a plant, and has the plasmodesmata (cytoplasmic channels that connects them)
isotonic
equal concentration of solvent and solute an equilibrium exists and there is is an equal ratio between water moving in and out of the cell
solute potential
-iCRT -i= ionization- depends on how many components the chemical dissociates into(ie. sucrose is 1 because its one unit, but NaCl is 2 because it dissociates into Na and Cl), always 1 in an open container C= molarity R=constant- 0.0831 T= temp in Kelvin directly proportional to molarity
sodium-potassium pump process
1. Cytoplasmic sodium binds to the sodium-potassium pump. The affinity for sodium is high when the protein has this shape 2. sodium binding stimulates phosphorylation by ATP 3. Phosphorylation leads to a change in protein shape, reducing its affinity for NA which is released outside 4. the new shape has a high affinity for potassium which binds on the extracellular side and triggers release of the phosphate group 5. loss of the phosphate group restores the protein's original shape, which has a lower affinity for potassium 6. potassium is released, affinity for sodium is high again and the cycle repeats
fluid mosaic model
A mosaic of protein molecules in a fluid bilayer of phospholipids Not static and held together by hydrophobic interactions (weaker than covalent bonds) Most lipids and some proteins can shift and flow along the surface of the membrane or across the bilayer
Chemiosmosis
A process for synthesizing ATP using the energy of an electrochemical gradient and the ATP synthase enzyme.
Phagocytosis
A type of endocytosis in which a cell engulfs large particles or whole cells
cell compartmentalization in prokaryotic vs eukaryotic cells
Both have plasma membranes that separate the internal from the external environments Prokaryotic cells have an internal region, nucleoid region, that contains genetic material Eukaryotic cells have additional internal membranes and membrane-bound organelles that compartmentalize the cell Genetic material is contained within the nucleus which is membrane bound
What does the folding of the mitochondrial inner membrane, shown here, provide?
Folding of the inner membrane increases surface area→ more ATP can be made
peripheral proteins
Loosely bound to the surface of the membrane Hydrophilic with charged and polar side groups
Mitochondria comparmentalization
Membrane folding maximizes surface area for metabolic reactions to occur Electron transport and ATP synthesis occur in the inner mitochondrial membrane Folding of the inner membrane increases the surface area which allows for ATP to be made
factors that increase surface area of cell
Membrane folding, Root hairs on the surface of plant roots (increased absorption), The villi has microscopic projections called microvilli that aid absorption
Lysosome compartmentalization
Membrane minimizes competing interactions Hydrolytic enzymes of the lysosome function at an acidic environment Inside of the lysosme can remain acidic and allow for hydrolysis to occur, while the rest of the cytoplasm can have a more neutral environment
hydrogen ions in transport in plant cells
Membrane potential is established by pumping hydrogen ions via proton pumps rather than sodium ions in sodium potassium pumps H is cotransported in plants- absorbs neutral solutes by phloem cells by moving it against the concentration gradient Also helps with uptake of nitrate by root cells Semipermeable channel- only lets certain ions pass through
osmosis
Osmosis: the diffusion of free water across a selectively permeable membrane Moves via aquaporins
phospholipids
Polar head and nonpolar tail Forms a bilayer in aqueous environments Tails are in the bilayer and heads are exposed to the outside environment
Mitochondria
Powerhouse of the cell, organelle that is the site of ATP (energy) production. Captures its energy from macromolecules.
cell wall
Structural boundary: Protects and maintains the shape of the cell, Prevents cellular rupture when internal water pressure is high, Helps plant stand up against gravity Comprised of complex carbohydrates: Cellulose- polysaccharide Fungi- chitin, polysaccharide Prokaryotes: peptidoglycan
cell size
The larger the cell, the harder it is to transport things in and out of the cell
surface area to volume ratio
The larger the ratio, the more efficient the cell will be
nuclear lamina
a netlike array of protein filaments that maintains the shape of the nucleus by mechanically supporting the nuclear envelope
membrane protein functions
Transport, Cell-cell recognition, Enzymatic activity, Signal transduction, Intercellular joining, Attachment for cellular matrix or cytoskeleton
how does water move
Water diffuses out of a hypotonic solution into a hypertonic solution via osmosis (inversely related) Solutions diffuse along their concentration gradient from hyper to hypotonic
nuclear matrix
a framework of protein fibers extending throughout the nuclear interior.
Pinocytosis
cell takes in extracellular fluid containing dissolved substances
endocytosis
cell uses energy to take in macromolecules and particulate matter by forming new vesicles derived from the plasma membrane
ligand-gated channels
channel that opens when a neurotransmitter attaches
chromatin
consists of DNA and proteins. The chromatin fibers condense when a cell prepares to divide so that it becomes thick enough to be distinguished as separate structures.
apopplast
consists of everything external to the plasma membrane- cell wall, ECM, interior of dead cells
Electronegativity
decreases from left to right on a gradient
maintaining membrane potential
diffusion of ions across the membrane helps maintain resting potential, microenvironment of membrane determines channels opening/closing, channels are passive, ion pumps actively use energy to transport ions across the cell membrane
Smooth ER
doesn't have ribosomes attached, carries out detoxification and lipid synthesis
aquaporins
facilitates the transport of water molecules across the plasma membrane Mediated by aquaporin channels
stroma
fluid between the inner chloroplast membrane and outside thylakoids; carbon fixation reactions occur here
Chloroplast
found in eukaryotic cells (algae/plants) and has a double outer membrane Function: capturing energy from the sun and producing sugar for the organism
stoma (plant)
found on leaf surface; used for gas exchange; opening controlled by guard cells
Rough ER
has ribosomes attached to its membrane, compartmentalizes the cell, associated with packaging the newly synthesized proteins made by attached ribosomes for possible export from the cell; carries out protein synthesis on ribsomes bound to its membrane
thylakoid
highly folded membrane compartments that are organized into stacks (grana) Membranes contain chlorophyll pigments that comprise the photosystems and electron transport proteins can be found between the photosystems embedded in the thylakoid membrane Light-dependent reactions occur there Folding of these internal membranes increases the efficiency of these reactions
channel proteins
hydrophilic tunnel spanning the membrane that allow specific target molecules to pass through
exocytosis
internal vesicles use energy to fuse with the plasma membrane and secrete large macromolecules out of the cell Signaling proteins, hormones, and waste
glycolipids
lipid with one or more carbohydrate attached
osmoregulation in plant cells
maintains water balance and controls solute composition/water potential Environmental hypertonicity: less solute and more cellular water, Plasmolysis Isotonic Solutions: equal solute and water, flaccid Environmental hypotonicity: more solute less water, turgid Cell wall helps maintain homeostasis for the plant to maintain environmental hypotonicity Osmotic pressure is high outside the plant cell due to environmental hypotonicity Water flows into the plant vacuoles via osmosis causing the vacuoles to expand and press against the cell wall Cell wall expands until it exerts pressure back on the cell (turgor pressure) Turgidity: optimum state for plant cells
vacuoles
membrane-bound sacs found in eukaryotic cells Function: Storage, release of macromolecules, water, and cellular waste products
lysosomes
membrane-enclosed sacs found in some eukaryotic cells that contain hydrolytic enzymes used in: Intracellular digestion, Recycling of organic materials, Programmed cell death
turgid
more concentration than its surroundings, very firm
hypertonic
more solute, less solvent, more concentrated
hypotonic
more solvent less solute, outside environment
glycoproteins
one or more carbohydrates attached to a membrane protein
Golgi complex
organelle found in eukaryotic cells that modifies, packages, and transports material out of the cell.
pressure potential
physical pressure on a solution Can be positive or negative Water in living cells is under positive pressure because the protoplast presses against the cell wall (turgor pressure)- helps maintain stiffness
Eukaryotic cell compartmentalization
plasma membrane: allow the cell to establish and maintain internal environments that are different from their external environment, has additional internal membranes and membrane bound organelles that compartmentalize the cell The compartments allow for various metabolic processes and specific enzymatic reactions to occur simultaneously, increasing the efficiency of the cell
Cholesterol in fluid mosaic model
randomly distributed and wedged between phospholipids in the cell membrane of eukaryotic cells Regulates bilayer fluidity under different environmental conditions Diversity and location of the carbohydrates and lipids enable them to function as markers
receptor-mediated endocytosis
receptor proteins on the cell membrane are used to capture specific target molecules
osmoregulation in animal cells
regulates water balance and allows control of inner solute composition/water potential Environmental hypertonicity: less solute more water , shriveled Isotonic solution: cell is normal Environmental hypotonicity: cell is lysed (burst)
active transport
requires the direct input of energy (ATP) to move molecules from regions of low concentration to high concentration- against concentration gradient
free ribosomes
ribosomes suspended in the cytosol
cotransport
secondary active transport that uses the energy from an electrochemical gradient to transport two different ions across the membrane through a protein
Plasmodesmata
small holes between plant cells that allow the transfer of nutrients, waste, and ions, helps with permeability
water potential
solute potential + pressure potential Water moves from a high to low potential Values of water potential can be positive, negative, or zero The more negative, the more likely it will move into the area Pure water has a value of zero because it has no solute in it Increasing solute: increases solute potential, decreases water potential (and vice versa) Increasing water potential: increase in pressure potential Decreasing pressure potential: decrease in water potential
carrier proteins
spans the membrane and change shape to move a target molecule from one side of the membrane to another
Ribosomes
synthesize proteins, composed of RRNA and proteins, and is composed of 2 subunits that are NOT membrane enclosed
what processes occur in the mitochondria?
the Krebs cycle occurs in the matrix of the mitochondria and electron transport/ATP synthesis occur in the inner mitochondria membrane
tonicity
the measurements of the relative concentrations of solute between 2 solutions (inside and outside the cell)
bulk flow
the movement of liquid in response to a pressure gradient, which occurs from high to low pressure Independent of solute concentration Conducted through the xylem and phloem
facilitated diffusion
the movement of molecules from a higher concentration to a lower concentration through transport proteins Allows for hydrophilic molecules and ions to pass through the cell membrane
diffusion
the movement of molecules from a higher concentration to a lower concentration- small non-polar molecules, requires energy
passive transport
the net movement of molecules from a high concentration to a low concentration Plays an important role in the import of materials and export of wastes
cytoplasm
the region between the nucleus and the cell membrane organized in small compartments
osmolarity
the total solute concentration in a solution Water has high solvency abilities Solute is being dissolved Solvent dissolves a solute A solution is a solute mixed with a solvent
phloem
transports photosynthetic products from sources to sinks
xylem
transports water and minerals from roots to shoots
antiport
two different ions are transported in opposite directions
symport
two different ions are transported in the same direction
symplastic transport
water/solutes move along the cytosol by crossing the plasma membrane and then moving via the plasmodesmata
transmembrane transport
water/solutes moves out of one cell and into a neighboring cell, which is repeated
Apoplastic transport (in an organ/tissue)
waters/solutes move along the continuum of the cell wall and extracellular spaces
concentration gradient
when a solute is more concentrated in one area than another A membrane separates two different concentrations of molecules
flagella
whiplike tails found in one-celled organisms to aid in movement
