eukaryotic cells
animal, plant cells. alage and fungi cells
specialised cells
Multicellular eukaryotic organism- cells become specialised (specific function)
cell structure helps carry out its function
specialised cells>tissue>organs>organ system
Viruses are acellular. not cells
- viruses are nucleic acid surrounded by protein, not alive
- no plasma membrane, no cytoplasm, no ribosomes
- all viruses invade and reproduce inside the cells of another organism (host cell)
- viruses contain a core of genetic material, either dna or rna
- protein coat around the core is a capsid
- attachment proteins stick out from the - - edge of the capsid, these let a virus cling onto a host cell
prokaryotic cells replicate by binary fission
in binary fission, the cell replicates of its genetic material
- 1, circular dna and plasmids replicate, the main dna loop is only replicated once, but plasmids can be replicated many times.
- 2, the cell gets bigger and the dna moves to opposite poles of the cell
- 3, cytoplasm begin to devide, new cell wall begins to form
- 4, cytoplasm divides, two daughter cells are produces, each daughter cell has a copy of the circular dna, but can have a varied number of plasmids
Virus replication
- use attachment proteins to bind to a complementary receptor protein on the surface of host cells.
- different viruses have different attachment proteins and so a different receptor protein is needed on the host cell-> some viruses can only infect certain cells, some can infect many
- viruses arent alive so they dont undergo cell division, they instead inject their dna or rna into the host cell, which uses it enzymes or ribosomes to replicate the virus
Magnification= image size/actual size
Magnification- the size, how much bigger the image is compared to the specimen/sample
Resolution- how detailed the image is, how well a microscope distinguishes between two points that are close together
Optical microscopes (light microscopes)
-use light to form an image
- max resolution of 0.2 micrometers (can’t view ribosomes, endoplasmic reticulum, lysosomes) may be able to see nucleus and mitochondria
- max mag is x1500
Electron microscopes
- use electrons to form an image
- higher resolution than optical, can look at more organelles
- max resolution of 0.0002 micrometers (1000x higher than optical)
- max mag is about 1,500,000x
- can be scanning or transmission
Electron microscopes, Transmission, electron microscopes (TEMs)
- use electromagnets to focus beams of electrons which are then transmitted through the specimen
- denser parts absorb more electrons, which make them look darker on the final image
- good bc they give high res images, you can see the internal structure of the organelles eg chloroplast
- can only be used on thin specimens
Electron microscopes, Scanning Electron Microscopes (SEMs)
- SEMs scan a beam of electrons across the specimen. This knocks off electrons from the specimen, which are then gathered in a cathode ray tube to form an image
- this image shows the surface of the specimen, and can be 3D
- SEMs are good because they can be used on thick specimens
- they give lower resolution images than TEMs
you can view specimens under an optical microscope using slides
- ‘temporary mount’ of specimen on slide
- pippet a small drop of water on the slide, use tweezers to place a thin section of specimen on top of the waterdrop
- add a drop of stain, which highlights objects in the cell. eg eosin is used to make cytoplasm show up. Iodine in potassium iodine solution stains starch grains of plant cells
- add the cover slip to protect the specimen. be careful of air bubbles
Cell fractionation, Homogenisation/breaking up the cell (step one)
- can be done by vibrating or grinding up the cells in a blender to break up the plasma membrane and release the organelles into the solution
- must be in an ice cold solution to reduce the activity of enzymes that break down organelles
- must be an isotonic solution, meaning it has the same concentration of chemicals as the cells being broken down in order to prevent damage to the organelles through osmosis
- ## a buffer solution should be added to maintain the pH
Cell fractionation, filtration (step two)
- the homogenised solution is filtered through a gauze to separate any large cell debris or tissue debris, eg connective tissue from the organelle
- organelles are smaller than debris so they pass through the gauze
Cell fractionation, separating the organelles (step 3)
After filtering, you’re left w a solution w a mixture of organelles- separating one from another needs ultracentrifugation
- poured into a tub then put into a centrifuge, which separates material by spinning. Spin at a low speed so the heavier organelles like nuclei got flung to the bottom. this forms a thick sediment at the bottom (the pellet) the rest are in the fluid above the sediment (supernatant)
- supernatant is drained off and poured into another tube, then spun at a higher speed, heaviest organelle (mitochondria) from a pellet at the bottom. supernatant is drained off and spun at a higher speed
- repeated at higher and higher speeds until all of the organelles have been separated. each time the pellet is made of lighter organelles.
Mitosis, produces genetically identical cells
- mitosis: parent cell divides to produce two genetically identical daughter cells
- Mitosis is needed for the growth of multicellular organism and for repairing damaged tissue
- cells that are able to keep their ability to divide follow a cell cycle, mitosis is part of the cycle.
What are the four stages of mitosis?
Interphase
Prophase
Metaphase
Anaphase
Telophase
What is Anaphase?
The centromeres divide, seperating each pair of sister chromatids.
The spindles contract, pulling chromatids to opposite poles of the spindle, centromere first. This makes chromatids appear v-shaped
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what is telophase? - The chromatids reach the opposite poles on the spindle, they uncoil to be long and thin again, they are now chromosomes again.
- a nuclear envolope forms around each group of chromosomes, now there are two nuclei
- division of the cytoplasm, (aka, cytokinesis~anaphase) finishes in telophase
- there are now two genetically identical daughter cells. mitosis is finished and the daughter cells start interpahse ready for another mitosis.
new card. how do you calculate mitosis?
observed that 10/100 cells are in metaphase, suggests that metaphase must be 10/100th of a cell cycle. told a cell cycle last 15 hours, convert into mins, then times by the division.
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what is the cause of cancer?
- uncontrolled cell divison.
- mitosis and the cell cycle are controlled by genes
- normally when cells have divided enough times to make enough new cells, they stop but if theres a mutation in the gene that control cells division, it grows out of control
- the cells keep on dividing to make more cells, which form a tumour
- cancer is a tumour that invades surrounding tissue
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Some cancer treatment targets the cell cycle
- some treatments for cancer are designed to control the rate of cell division in tumour cells by disrupting the cell cycle which kills tumour cells but cant distinguish from a normal cell so kills dividing body cells
- tumour cells divide more frequently so the treatment is more likely to kill them
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what do cell cycles do cancer treatments target?
- G1, cell growth and protein production, chemical drugs like chemotherapy preent
What is Interphase?
The cell carries out normal functions, preprases to divide
- the cells dna is unravalled and replicated to double its genetic content
- the organelles are also replicated
- ATP content is increased to provide energy for cell division
What is prophase?
- chromosomes condense, get shorter and fatter
- centrioles (tiny bundles of protien) start moving to the opposite end of the cell. This forms a network of protien fibres across it called the spindle
- The nuclear envelope (membrane around the nucleus) breaks down and chromosomes lie free in the cytoplasm
What is the metaphase?
Chromosomes, each w two chromatids, line up along the middle of the cell and become fully attached to the spindle by their centromere
Cell cycle
consists of a period of cell growth and dna replication which is interphase, mitosis happens after that. Interphase is divided into three separate growth stages. G1, S, and G2
Cell membranes control what passes through them
Exchange across cell membranes, active transport needs energy
active transport uses energy to move molecules and ions across membranes
It involves carrier proteins, sim to facilitated diffusion, a molecule attaches to the carrier protein, the protein changes shape and this moved the molecule across the membrane and releases it on the other side
2 main differences:
- active transport usually moves the solute from a low to high conc, but fac dif is a high to low
- act tr requires energy, fac dif does not. ATP- common source of energy in the cell, produced by resp, ATP undergoes a hydrolysis reaction, which splits into ADP and Pi (inorg phosphate) which releases energy so the solute can be transported
