- tissue growth - tissue repair - asexual reproduction

- cell continues to increase in size - spindle fibres form - proteins for mitosis produced - increase energy stores - duplicated DNA checked for errors and corrected

- differentiation - damaged DNA (not viable) - cells become senescent (old/only go through the cell cycle a limited number of times)

- cell size - nutrients - growth factors - DNA damage

- cell size - DNA replication - DNA damage

- outer ball of totipotent cells (umbilical chord and placenta) - pluripotent embryonic cells inside

- totipotent - pluripotent - multipotent

Cell division Flashcards by Chloe Harris

roles of mitosis

tissue growth
tissue repair
asexual reproduction

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roles of meiosis

production of haploid gametes with genetic variation:
- crossing over
- independent assortment
- random fertilisation

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what occurs during G1?

organelles replicate
protein synthesis
respiration
cell increases in size (cytoplasm increases in volume)

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what occurs during the synthesis stage of the cell cycle?

DNA replicated in the nucleus

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what occurs in G2?

cell continues to increase in size
spindle fibres form
proteins for mitosis produced
increase energy stores
duplicated DNA checked for errors and corrected

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reasons for G0

differentiation
damaged DNA (not viable)
cells become senescent (old/only go through the cell cycle a limited number of times)

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give an example of a type of cell that can reenter the cell cycle after G0

lymphocytes (B memory cells)

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name three cell cycle checkpoints and their position

G1 checkpoint (after G1, before S or G0)
G2 checkpoint (after G2, before mitosis)
spindle assembly checkpoint/metaphase checkpoint (during metaphase)

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G1 checkpoint roles

cell size
nutrients
growth factors
DNA damage

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G2 checkpoint roles

cell size
DNA replication
DNA damage

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spindle assembly checkpoint roles

chromosome attachment and alignment to spindle fibres

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why can’t cells keep growing indefinitely?

as size increases, SA:V decreases and gas exchange, transport of nutrients etc would be inefficient

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blastocyst structure

outer ball of totipotent cells (umbilical chord and placenta)
pluripotent embryonic cells inside

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three potencies

totipotent
pluripotent
multipotent

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totipotent

stem cells that can differentiate into any type of cell including placenta and umbilical chord cells

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pluripotent

stem cells that can form all body cells (excluding cells to make an umbilical chord or placenta)

multipotent

stem cells that can only form a range of cells within a certain type of tissue

example of multipotent animal cells

haemopoetic stem cells in bone marrow can differentiate into any blood cell

what are iPSC?

induced pluripotent stem cells - adult stem cells which have been genetically modified to behave like embryonic stem cells

why are embryos a better source than umbilical chords and bone marrow for stem cells?

embryomic cells are pluripotent whereas the other two are only multipotent
adult stem cells (umbilical and bone marrow) are likely to have accumulated more mutations

prophase

nuclear envelope breaks down
chromatin fibres condense
spindle fibres (microtubules) form from centrioles
spindle fibres attach to centromeres of chromosomes

metaphase

chromosomes align on the metaphase plate/equator

anaphase

spindle fibres contract
centromeres split and sister chromatids pulled to opposite poles

telophase

nuclear envelope forms around chromosomes
chromatids/chromosomes uncoil to form chromatin

cytokinesis in animal cells

microfilament ring (cytoskeleton) pulls plasma membrane inwards to create a cleavage furrow

cytokinesis in plant cells

- golgi apparatus produces vesicles - vesicles assemble in the centre of the cell - vesicles fuse to split the cell - cell wall forms along new sections of membrane formed by vesicles

prophase 1

- nuclear envelope breaks down - chromatin condenses to form chromosomes - homologous chromosomes pair up and cross over to form bivalents - spindle fibres assembled by centrioles and attached to centromeres of bivalents

metaphase 1

- bivalents align on the metaphase plate/equator - independent assortment ( random which poles maternal and paternal chromosomes will face)

anaphase 1

- spindle fibres contract - homologous chromosomes pulled to opposite poles

recombiant chromatids

chromatids that have swapped alleles during crossing over

chiasmata

the point where chromatids break and rejoin

telophase 1

- nuclear envelope forms around chromosomes at opposite poles - chromosomes uncoil into chromatin - cytokinesis occurs

prophase 2

- nuclear envelope breaks down - chromatin condenses into chromosomes - spindle fibres assemble from centrioles and attach to centromeres of chromosomes

metaphase 2

- individual chromosomes align on the metaphase plate/equator - independent assortment (sister chromatids are not identical due to crossing over)

anaphase 2

- spindle fibres contract - centromeres split and sister chromatids are pulled to opposite poles

telophase 2

- nuclear envelope forms around chromatids at either pole - chromatids/chromosomes uncoil to form chromatin