Differences between eukaryotic and prokaryotic cells
Prokaryotic cells are much smaller than eukaryotic cells
Eukaryotic cells contain membrane bound-organelles and a nucleus containing genetic material, while prokaryotes do not
Prokaryotic cell wall
Composed of peptidoglycan
Genetic information storage in prokaryotic cells
Found free within the cytoplasm as: Chromosomal DNA (single large loop of circular DNA), Plasmid DNA
Plasmids
Small, circular loops of DNA found free in the cytoplasm and separate from the main DNA, carry genes that provide genetic advantages e.g. antibiotic resistance
Order of magnitude
A power to the base 10 used to quantify and compare size
Centimetre (cm)
1 x 10-2 metres
Millimetre (mm)
1 × 10-3 metres
Micrometre (µm)
1 × 10-6 metres
Nanometre (nm)
1 x 10-9 metres
Components of both plant and animal cells
Nucleus
Cytoplasm
Cell membrane
Mitochondria
Ribosomes
Additional cell components found in plant cells
Chloroplasts
Permanent vacuole
Cell wall
Function of the nucleus (other than storing genetic information)
Controls cellular activities
Structure of the cytoplasm
Fluid component of the cell, contains organelles, enzymes and dissolved ions and nutrients
Function of the cytoplasm
Site of cellular reactions e.g. first stage of respiration, Transport medium
Function of the cell membrane
Controls the entry and exit of materials into and out of the cell
Function of the mitochondria
Site of later stages of aerobic respiration in which ATP is produced
Function of the ribosomes
Joins amino acids in a specific order during translation for the synthesis of proteins
Function of the plant cell wall
Provides strength, Prevents the cell bursting when water enters by osmosis
Contents of the permanent vacuole
Cell sap (a solution of salts, sugars and organic acids)
Function of the permanent vacuole
Supports the cell, maintaining its turgidity
Function of chloroplasts
Site of photosynthesis
Adaptations of sperm cells in animals
Haploid nucleus contains genetic information
Tail enables movement
Mitochondria provide energy for tail movement
Acrosome contains enzymes that digest the egg cell membrane
Adaptations of nerve cells in animals
Long axon allows electrical impulses to be transmitted all over the body from the central nervous system
Dendrites from the cell body connect to and receive impulses from other nerve cells, muscles and glands
Myelin sheath insulates the axon and speeds up the transmission of impulses along the nerve cell
Adaptations of muscle cells in animals
Arrangement of protein filaments allows them to slide over each other to produce muscle contraction
Mitochondria to provide energy for muscle contraction
Merged cells in skeletal muscle allow muscle fibre contraction in unison
Adaptations of root hair cells in plants
Large surface area to absorb minerals and water from surrounding soil
Thin walls that do not restrict water absorption
Adaptations of xylem cells in plants
No upper or lower margins between cells to provide a continuous route for water to flow
Thick, woody side walls strengthen their structure and prevent collapse
Adaptations of phloem cells in plants
Sieve plates let dissolved amino acids and sugars be transported up and down the stem
Companion cells provide energy needed for active transport of substances along the phloem
Cell differentiation
The process by which cells become specialised
Importance of cell differentiation
Allows production of different tissues and organs that perform various vital functions in the human body
Timing of cell differentiation in animals
Early in their life cycle
Timing of cell differentiation in plants
Throughout their entire life cycle
Purpose of cell division in mature animals
Repair and replacement of cells
Changes during cell differentiation
Becomes specialised through acquisition of different sub-cellular structures to enable a specific function to be performed by the cell
Magnification
The number of times bigger an image appears compared to the size of the real object
What is the purpose of cell division in mature animals?
Repair and replacement of cells
Cell differentiation
Becomes specialised through acquisition of different sub-cellular structures to enable a specific function to be performed by the cell
Resolution
The smallest distance between two objects that can be distinguished
How does a light microscope work?
Passes a beam of light through a specimen which travels through the eyepiece lens, allowing the specimen to be observed