Cell physiology

Question 1

Animal cells – 3 compartments

Answer 1

1) cell membrane

2) cytoplasm

3) nucleus

protoplasm = cytoplasm + nucleus

Question 2

functions of plasma membrane

Answer 2

1) barrier b/w cell & environment
(cells, ISF/plasma)

2) SELECTIVELY PERMEABLE MEMBRANE

3) I.e. UNIQUE internal cell environment

Question 3

cell membrane structure

Answer 3

75% phospholipids

Question 4

phospholipids are…

Answer 4

amphipathic

both polar and non-polar components

nonpolar fatty acid tails
polar phosphate head

Question 5

cell membrane structure (bilayer)

Answer 5

high amounts of phospholipids in aqueous solution

= phospholipid bilayer

= phosphate heads towards water, FA tails away from water (towards each other)

Question 6

majority of phospholipid bilayer is (hydrophilic? hydrophobic?)

Answer 6

hydrophobic (tails)

Question 7

consequence of majority hydrophobic bilayer

Answer 7

only hydrophobic (non-polar) molecules can pass through

hydrophilic (polar) molecules need carrier/channel mediation

Question 8

exception to what can/can’t typically pass through lipid bilayer

Answer 8

Size is important variable

some small polar molecules can pass through – even though polar

some large nonpolar molecules may need transport (?) – even though nonpolar

Question 9

permeable to…

Answer 9

Non-polar, hydrophobic, uncharged, (small?) – E.G. STEROIDS, O2, CO2

Question 10

impermeable to…

Answer 10

polar, hydrophilic, charged – E.G. IONS, LARGE PROTEINS

Question 11

example of exception

Answer 11

H2O – permeable to some degree – even though POLAR, HYDROPHILIC

Question 12

what happens if lose selective permeability?

Answer 12

cell would no longer be able to maintain homeostasis – would be destroyed

Question 13

lipid bilayer is composed of which lipids?

Answer 13

75% phospholipids

20% cholesterol

5% glycolipids

Question 14

cholesterol in the lipid bilayer

Answer 14

carries a (polar) OH group (HYDROXIL GROUP)

attaches to phosphate group (polar head)

Question 15

function of cholesterol in lipid bilayer

Answer 15

structure @ high temp
fluidity @ low temp

1) maintains structure @ high temperatures

(by keeping phospholipids locked together)

2) maintains fluidity of membrane @ low temperatures

(Non-polar portion prevents phospholipids (tails?) interacting)

Question 16

GLYCOLIPIDS in the lipid bilayer

Answer 16

sugar attached to lipid

FOUND ON EXTRACELLULAR SIDE

Question 17

which side are glycolipids?

Answer 17

extracellular side

Question 18

function of GLYCOLIPIDS in cell membrane

Answer 18

SIGNAL TRANSDUCTION (convert signal type)

CELL TO CELL ADHESION

Question 19

what is GLYCOCALYX composed of?

Answer 19

“sugary coat”

composed of carbohydrate portion of glycolipids (& glycoproteins)

Question 20

function of GLYCOCALYX

Answer 20

1) cell recognition/signalling

2) protection

3) regulates cell behaviour

Question 21

Cell membrane PROTEIN categories

Answer 21

1) Integral proteins

2) Peripheral proteins

Question 22

integral proteins

Answer 22

crosses bilayer (“embedded”)

contains both polar/nonpolar parts (AMPHIPATHIC?)

complex/large

Question 23

peripheral proteins

Answer 23

on surface of membrane (external or internal side)

attach to polar head of phospholipid

or attach to integral proteins

less complex/large

Question 24

membrane proteins functional types

Answer 24

1) Transporters

2) Ion Channels

3) Receptors

4) Enzymes

5) Linkers

6) Markers

Question 25

1) Transporters

Answer 25

INTEGRAL

transports POLAR molecules

E.g.
GLUCOSE transporter
AMINO ACID transporter

Question 26

2) Ion Channels

Answer 26

INTEGRAL

transports IONS

can be…
ONE WAY
TWO WAY
SINGLE ION
MULTI ION

Question 27

3) Receptors

Answer 27

INTEGRAL

“lock & key”

Takes specific LIGAND

E.G
INSULIN & IT’S RECEPTOR

“ligare” – to bind

HORMONE IS LIGAND, BUT LIGAND NOT ALWAYS HORMONE

Hormone = type of ligand

Question 28

4) Enzymes

Answer 28

INTEGRAL OR PERIPHERAL
Active side faces inside or outside cell

Acts on SUBSTRATE

1) Breaks down SUBSTRATE –> products

2) CATALYZES REACTIONS (accelerate/cause)

E.G.
LACTASE protruding from EPITHELIAL cells of small intestine
–> breaks down lactose

Question 29

5) Linker

Answer 29

Integral or peripheral

attach/link other proteins
attach/link other cells

STRUCTURAL STABILITY of membrane

E.G.
Blood clots via fibrinogen and platelets

holds filaments inside/outside membrane

Question 30

6) Markers

Answer 30

cell identity

MAJOR HISTOCOMPATIBILITY PROTEINS

MHC proteins
–> ON OUTSIDE OF IMMUNE CELLS (e.g. macrophage)

Display peptide fragment from PATHOGENS to T-cells for recognition

Question 31

miscellaneous fact about drugs and membrane proteins

Answer 31

membrane proteins are target of over 60% of all drugs

Question 32

Fluid mosaic model

Answer 32

fluid movement of phospholipids

= membrane fluidity

Question 33

cell types examples

Answer 33

nerve cell

sperm cell

egg cell

skin

muscle

bone

immune

fat

epithelial

etc.

Question 34

two types of transport

Answer 34

1) Passive transport
2) Active transport

Question 35

passive transport does not require

Answer 35

energy, ATP

uses potential energy

Question 36

passive transport, where does energy come from?

Answer 36

electric gradient
concentration gradient

solutes move down gradient

potential energy (gradient) becomes kinetic

Question 37

how is membrane gradient created

Answer 37

selective permeability

Question 38

resting membrane potential

Answer 38

neurons and muscle fibres

facilitates Action Potentials (nerve impulse)

Question 39

2 Types of Passive transport

Answer 39

1) Diffusion (solutes)

2) Osmosis (water)

Question 40

Variables affecting Rate of Diffusion

Answer 40

1) Temperature

2) Surface area

3) Ratio of gradient

4) Size of particles

5) Thickness of membrane
(distance)

Question 41

2 types of Diffusion

Answer 41

1) Simple Diffusion
(directly through membrane)

2) Facilitated Diffusion
(transmembrane (integral) protein)

Question 42

why facilitate diffusion?

Answer 42

larger, polar, hydrophilic/charged molecules

e.g.
Ions
hormones
drugs

Question 43

Facilitated diffusion via..

A) (Ion) Channel protein or
B) Carrier (transporter) protein

Answer 43

(ion) channel…
DOES NOT CHANGE SHAPE
OPENS OR CLOSES
E.g.
Calcium ion
Potassium ion

carrier (tranporter)…
CHANGES SHAPE
E.g.
glucose
fructose
vitamins

Question 44

gated channel protein

Answer 44

gate determines when ions can/can’t flow in

Question 45

types of gated Channel proteins

(a type of facilitated diffusion, a type of passive transport)

Answer 45

LIGAND gate
(ligand, e.g. hormone)

VOLTAGE gate
(voltage change)

MECHANICAL gate
(pressure)

Question 46

Leak channels (in contrast to gated channels)

Answer 46

leak channels always open

Question 47

OSMOSIS (passive transport)

Answer 47

water from high concentration to low

When membrane impermeable to solutes

Via membrane directly
or
Via AQUAPORINS (channel proteins for water)
(“water pores”)

Question 48

OSMOTIC PRESSURE

Answer 48

minimum pressure that needs to be applied to SOLVENT to prevent it from passing into a solution VIA OSMOSIS

measure of concentration of solution (?)
I.e. pressure is directly proportional to concentration of solute

Pressure is against SOLUTE-heavy (?) side

(Pressure required to return to starting conditions)

Question 49

ONCOTIC pressure

Answer 49

colloid osmotic pressure

pressure in BLOOD PLASMA

via proteins (E.g. ALBUMIN)

ALBUMIN controls blood osmotic pressure
–> prevents fluid leaking out of Blood Vessels

PULL WATER BACK INTO VENOUS CIRCULATION

Question 50

BCOP

Answer 50

Blood Colloid Osmotic Pressure

Question 51

HYDROSTATIC PRESSURE

Answer 51

Pressure exerted by fluid on surroundings

EQUILIBRIUM–> HYDROSTATIC PRESSURE = OSMOTIC PRESSURE

in U-tube e.g. –> EQUILIBRIUM = UNEVEN WATER LEVELS

Question 52

TONICITY & osmosis

Answer 52

CONCENTRATION of solutes in solution

measures ability to change volume by changing water content

HYPOTONIC solution
ISOTONIC solution
HYPERTONIC solution

“hypertonic” EXTERNAL solution relative to INTERNAL cell environment

Question 53

hypertonic solution

Answer 53

= cell shrinks

“CRENATION”

Question 54

hypotonic solution

Answer 54

= cell bulges (if beyond tolerated force, cell will rupture)

“LYSIS”

Question 55

Active transport

Answer 55

Sodium Potassium Pump

Question 56

Sodium Potassium Pump – which cell not found in

Answer 56

RBC

Question 57

Sodium Potassium Pump – function

Answer 57

maintains resting membrane potential (RMP)

REMOVES 3 NA+ (ions)
BRINGS 2 K+ (ions)

Requires ATP

Question 58

Sodium Potassium Pump establishes…

Answer 58

CONCENTRATION GRADIENT

ELECTRICAL GRADIENT
(i.e. RMP)

Question 59

Concentration gradient via Na+K+ pump

Answer 59

more Na+ outside cell
more K+ inside cell

Question 60

Electrical gradient via Na+K+ pump

Answer 60

more positive outside cell

more negative inside cell

Question 61

RMP

Answer 61

every cell negative inside (negative RMP)

Question 62

why negative RMP inside cell?

Answer 62

1) Na+K+ pump

2) more K+ (diffusion) channels (more permeable to K+ within cell

3) many negatively charged organic molecules inside cell (e.g. Proteins)

Question 63

examples of RMP of various cells

Answer 63

neurons = -70mV
skeletal muscles = -90mV
smooth muscles = -60mV

photoreceptor cells = -40mV

RBC = -10mV

Question 64

2 types of Active transport

Answer 64

Primary Active transport
(via ATP)

Secondary Active transport
(via kinetic energy released by concentration gradient (passive movement) of other solutes)

Question 65

example of primary active transport

Answer 65

Na+K+ pump

Question 66

2 types of Secondary Active transport

Answer 66

Symporters (move 2 substances in same direction)

Antiporters (2 substances in opposite direction)

Question 67

Vesicular transport

Answer 67

Active (requires ATP)

1) ENDOCYTOSIS
2) EXOCYTOSIS

Question 68

exocytosis

Answer 68

1) secretion of hormones
E.g.
insulin
oxytocin

2) excretion of wastes
E.g.
Urea (kidneys)

Question 69

endocytosis

Answer 69

1) phagocytosis

2) pinocytosis

3) receptor-mediated endocytosis

Question 70

1) phagocytosis

Answer 70

eat large particles

E.g.
cells, bacteria, virus

E.g.
WBC, PSEUDOPODS
monocyte
macrophage
neutrophil
dendritic cells
osteoclasts
eosinophil

Question 71

2) pinocytosis

Answer 71

bulk-phase endocytosis

intake of fluid+solutes inside

Question 72

function of pinocytosis

Answer 72

Controls cell volume

transports molecules

proves nutrients to cell via digestion of molecules (Via DIGESTIVE ENZYMES INSIDE VESICLE/lysosome)

Question 73

receptor mediated endocytosis

Answer 73

selective endocytosis

targets specific LIGANDS (ions/molecules) –
Via receptor proteins?

receptor proteins recycled

goes to endosome

digested/destroyed in lysosome

Question 74

TRANSCYTOSIS

Answer 74

combo of exocytosis and endocytosis

e.g.
antibodies cross placenta
(endocytosis to cell of placenta
exocytosis to other side toward fetus)

Question 75

note terms:

Answer 75

phagosome
pinosome

lysosome
endosome

exosome

Question 76

cytoplasm consists of

Answer 76

cytosol (fluid)

organelles

Question 77

cytosol % of cell volume

Answer 77

55%

Question 78

cytosol % that is water

Answer 78

70-90%

Question 79

list of organelles

Answer 79

Cytoskeleton

Centrosome

Cilia & flagella

Ribosomes

Endoplasmic reticulum

Golgi complex

Vesicles

Mitochondria

Nucleus

Nucleolus

Question 80

vacuole vs vesicle

Answer 80

Vacuoles are somewhat larger than vesicles, and the membrane of a vacuole does not fuse with the membranes of other cellular components

Question 81

cytoskeleton 3 types

Answer 81

Microfilaments

Intermediate filaments

Microtubules

Question 82

microfilament, intermediate filament, microtubule

orientation (?)

Answer 82

microfilaments close to membrane (?)

intermediate filaments in b/w (?)

microtubules closest to centre (?)

Question 83

Microfilaments (protein?)

Answer 83

smallest of 3

ACTIN protein

usually near cell membrane

Question 84

microfilaments functions

Answer 84

1) movement and support

2) Cytokinesis (cell division)

3) muscle contraction

4) connect cytoskeleton to integral proteins

5) form microvilli

Question 85

intermediate filaments (protein?)

Answer 85

medium size

protein KERATIN

Question 86

intermediate filaments function

Answer 86

1) internal stability

2) organelles in specific position

3) bind adjacent cells (cell junctions)

Question 87

microtubules

Answer 87

largest

protein TUBULIN

long/hollow

made in CENTROSOME

Question 88

microtubules functions

Answer 88

1) Cell’s shape

2) movement of organelles (e.g. vesicles)

3) movement of chromosomes during cell division

4) Cilia and the Flagellum
(9 + 2 arrangement of microtubules)

Question 89

centriole vs centrosome

Answer 89

A centriole is a barrel-shaped organelle which lives normally within the centrosome.

Centrosomes are structures found inside of cells. They are made from two centrioles. Centrioles are microtubule rings. The main purpose of a centrosome is to organize microtubules and provide structure for the cell, as well as work to pull chromatids apart during cell division.

Question 90

centrosome

Answer 90

Microtubule organize

mitosis & meiosis (cell division)

2 centrosomes in each cell

near the nucleus

Question 91

centrosome consists of

Answer 91

Centrioles
= a pair of cylindrical structures composed of 9 clusters of 3 microtubules

Question 92

pericentriolar material

Answer 92

Pericentriolar material

contains TUBULIN protein to help build microtubules

Surrounds the centrioles and forms the starting point for mitotic spindles during mitosis

Question 93

cilia

Answer 93

cilium singular

1) cell mobility (egg cells down the fallopian tubes)

2) sweep foreign particles along an epithelial lining (respiratory tract)

MADE OF MICROTUBULES

Question 94

flagella

Answer 94

flagellum singular

propels cell forward

only in sperm cells

Question 95

ribosomes made of

Answer 95

made of…
ribosomal proteins
rRNA

50% protein 50% rRNA in eukaryotes

Question 96

ribosome functions

Answer 96

protein synthesis (TRANSLATION)

free-floating vs attached to ROUGH ER

Question 97

free floating vs rough ER ribosomes function

Answer 97

floating =
produce proteins for use in cytosol

rough ER ribosomes =
proteins for…
A) organelles
B) cell membrane
C) exocytosis

Question 98

ribosome composition

Answer 98

2 subunits of rRNA
(Large unit and small unit)

made in nucleus
assembled in cytosol

tiny granules under a microscope

Question 99

ribosomes also found in…

Answer 99

mitochondria

for ENZYME synthesis
(one of SIX membrane protein types)

Question 100

Endoplasmic reticulum

Answer 100

network of flattened sacs

extend from nuclear membrane

smooth ER (no ribosomes)
rough ER

Question 101

smooth ER function

Answer 101

lipid production

phospholipids, cholesterol

Question 102

smooth ER in liver cells…

Answer 102

detoxify drugs

breaks down glycogen to glucose

Question 103

smooth ER in muscle cells…

Answer 103

called SARCOPLASMIC RETICULUM

stores/releases CA2+

Question 104

rough ER

Answer 104

protein synthesis

e.g.
integral membrane proteins

hormones

structural proteins

Question 105

rough ER continuous with…

Answer 105

nuclear membrane

Question 106

proteins of rough ER exported via

Answer 106

“secretory pathways”

Question 107

golgi complex

Answer 107

AKA
golgi apparatus
golgi body

Receive/modify/transport proteins from the rough ER

more complex/numerous Golgi body = larger secretory role.

Question 108

golgi complex sacs

Answer 108

has 3 small sacs (cisternae):

Entry/cis face
= CONVEX
= facing rough ER
= receives protein via transport vesicles

intermedias (medial) cisternae
= protein becomes glycoproteins or lipoproteins (via ENZYME)

Exit/trans face
= concave side
= releases product

Question 109

vesicles

Answer 109

formed by a lipid bilayer

separating contents from the cytoplasm or ECF

Question 110

vesicles examples

Answer 110

Lysosome

Peroxisome

Secretory Vesicles

Question 111

lysosome

Answer 111

digest substances (via enzymes)

Acidic pH for optimal enzyme function –> pH <7

A) Autophagy :
Removal of unnecessary or dysfunctional organelles

B) Autolysis:
self-digestion (destruction of entire cell)

Question 112

autophagy

Question 113

autolysis

Question 114

peroxisome

Answer 114

breakdown of some organic molecules (very long FAs)

Contains many digestive proteins

peroxisomes neutralize H2O2 (hydrogrenperoxide – byproduct of metabolism)

Question 115

Secretory vesicles

Answer 115

to the plasma membrane for exocytosis

e.g. proteins, hormones

Question 116

mitochondria

Answer 116

ATP via aerobic metabolism (requires O2)

via glucose, protein, lipids —> ATP

note gluconeogenesis

Question 117

mitochondria more numerous in…

Answer 117

muscle and nerve cells (active)

Question 118

mitochondria not present in…

Answer 118

RBC

Question 119

mitochondria structure

Answer 119

Structure:
outer and inner membrane

CRISTAE (folds) of inner membrane

between cristae is MATRIX
= most reactions take place
= Analogous with cytoplasm of the cell

Contain ribosomes
own set of DNA

ability to self-replicate proteins

Question 120

mitochondria DNA

Answer 120

DNA is different from the main set of chromosomes in the nucleus

Only one “mitochondrial chromosome”
many per mitochondria

Much small than DNA in nucleus (?)

Circular DNA (same as bacteria)

Maternal inheritance only

Question 121

mitochondria theory of origin

Answer 121

mitochondria are of bacterial origin

Question 122

nucleus

Answer 122

“Brain” of cell

responsible for…
genetics
protein synthesis

(analogous to the CPU of a computer)

The nucleus is where we find the DNA, our genetic material

Question 123

found in nucleus

Answer 123

the DNA, our genetic material

Question 124

how many nuclei?

Answer 124

Most cells have 1 nucleus (UNINUCLEATE)

some have more (i.e. muscle cells) = (MULTINUCLEATE)

some have NONE (i.e. mature red blood cells)

Question 125

nucleus structure

Answer 125

NUCLEAR ENVELOPE
= double membrane
= separates from cytoplasm
= like plasma membrane

NUCLEAR PORES
= substances in/out
= Proteins/hormones in
= RNA out

Question 126

Nucleolus

Answer 126

largest structure in the nucleus

spherical body

made of clusters of RNA & protein

Function is to make rRNA (ribosomes)

Question 127

DNA

Answer 127

double stranded helix

backbone of alternating pentose sugars and phosphate group

complementary nitrogenous base pairs form hydrogen bonds

Question 128

stretch out DNA in a cell

DNA in body

Answer 128

would be 6 feet long

would be 108 billion KM
(150,000 round trips to moon)

Question 129

genes

Answer 129

segments of DNA

encode for traits

codes for proteins that change structure/function/appearace

Question 130

how many genes in human genome

Answer 130

20,000 genes

less than 1/2 function is known

Question 131

genes examples

Answer 131

124 genes for hair colour
16 genes for eye colour
4 genes for freckles

Question 132

Allele

Answer 132

variation of DNA sequence at a GENOMIC location

E.g.
Allele for red hair
Allele for blonde hair
Allele for brown hair

Question 133

Genotype

Answer 133

sequence of base pairs in gene

“what genes say you should look like”

Question 134

Phenotype

Answer 134

observable traits form genotype

“what you look like”

Question 135

Histones

Answer 135

protein balls

DNA double helix coils around “

Question 136

Nucleosome

Answer 136

combination of histone and DNA double helix

Question 137

Linker DNA

Answer 137

section of DNA that links NUCLEOSOMES together

Question 138

Chromatin

Answer 138

DNA/RNA/proteins prior to cell division

scattered throughout nucleus before cell division

granular mass when cell not dividing

chromatin clusters –> forms chromosomes before cell division

Question 139

groups of NUCLEOSOMES = chromatin (???)

groups of CHROMATIN
=chromatin fibre (???)

Question 140

chromatin fibre

Answer 140

composed of chromatin

section of many NUCLEOSOMES & Linker DNA

Question 141

chromatin condensation

Answer 141

forms chromosome

Question 142

chromosomes

Answer 142

arrangement of chromatin fibres during cell division

Question 143

humans have…

Answer 143

46 chromosomes
23 from each parent

Question 144

pairs of chromosomes =

Answer 144

HOMOLOGOUS CHROMOSOMES

Question 145

AUTOSOMAL CHROMOSOMES

Answer 145

1-22

Question 146

chromosome 23

Answer 146

SEX CHROMOSOME

Question 147

SEX CHROMOSOME…

Answer 147

determines gender

female = xx
male = xy

Question 148

CHROMATIDS

Answer 148

1/2 of chromosome

1 pair chromatid = chromosome

Question 149

centromere

Answer 149

centre portion of chromosome

holds two CHROMATIDS together

(or 2 sister chromatids)

Question 150

TELOMERES

Answer 150

non-coding

terminal portion of chromosomes

protects end of chromosome

prevents genetic material loss when cell divides

become short eventually –> Cell can’t divide –> cell dies

Question 151

short telomere

Answer 151

increased disease/aging

Question 152

GENOME

Answer 152

total genetic info of organism

carried in nucleus of cells

Question 153

human genome project

Answer 153

2003
mapped out most of genome of human

20,000 genes

took 13 years

2022 –> genome almost entirely mapped

Question 154

number of genes correlation to intelligence

Answer 154

does NOT correlate with intelligence

Question 155

PROTEIN SYNTHESIS

Answer 155

new proteins from genome

ONLY IN CELLS W/ NUCLEUS

No nucleus = no DNA = no protein synthesis

E.g. RBC no nucleus

PROTEIN SYNTHESIS begins in NUCLEUS, end in CYTOPLASM

Question 156

protein synthesis 2 steps

Answer 156

1) Transcription
DNA –> mRNA

2) Translation
mRNA –> protein

Question 157

Transcription (Protein Synthesis)

Answer 157

transcribing DNA into RNA

all 3 types of RNA

occurs in NUCLEUS

Question 158

Transcription (RNA POLYMERASE)

Answer 158

RNA POLYMERASE
@ PROMOTER REGION

UNZIPS small section of DNA

(two strands separated)

Question 159

TEMPLATE STRAND

CODING STRAND

Answer 159

template strand is transcribed

coding strand is not

complementary nucleotide bases are matched

Question 160

on template strand, new nucleotides can only be added to which end?

Answer 160

3’ (3 prime) end

moves along strand in 3’ to 5’ (5 prime) direction

Question 161

complementary nucleotide bases (nitrogenous bases)

Answer 161

e.g.
A–> U (T replaced in RNA)
G–> C
T–> A
C–> G

Question 162

PROMOTER REGION
CODING SEQUENCE
TERMINATOR REGION

Answer 162

regions of gene

RNA polymerase starts at PROMOTER

ends at TERMINATOR region

RNA polymerase then detaches from DNA & pre-mRNA molecule

Question 163

SPLICING of pre-mRNA molecule (INTRONS and EXONS)

Answer 163

pre-mRNA molecule & snRNPs (Small Nuclear RiboNuclear Proteins)

snRNPs splice pre-mRNA
= moves non-coding segments (introns)
= splices coding segments (exons) together

Question 164

Alternative Splicing

Answer 164

same pre-mRNA molecule

different mRNA strands

different proteins

snRNPs will splice a pre-mRNA strand differently at different times to produce different mRNA strands which are then translated to different proteins (from the same pre-mRNA molecule)

Question 165

5’ (5 prime) cap

Answer 165

modified guanine nucleotide

1) “REGULATION of nuclear export”

2) structural stability

3) improve translation

Question 166

3’ (3 prime) poly-A tail

Answer 166

adenine nucleotides

1) REGULATION of nuclear export

2) structural stability of mRNA

3) facilitate translation

Question 167

where does mRNA go after?

Answer 167

after splicing & cap/tail –> pre-mRNA becomes mRNA –> EXITS NUCLEUS VIA NUCLEAR PORES

goes to cytoplasm

TRANSLATION OCCURS NEXT

Question 168

Codon

Answer 168

three nucleotide (nitrogenous) bases

each CODON in mRNA strand
= Codes for specific AMINO ACID

Question 169

start codon

vs

stop codon

Answer 169

start codon = translation initiates

stop codon = translation stops

Question 170

Translation

Answer 170

translating mRNA to polypeptide

NUCLEIC ACID –> AMINO ACID

performed by RIBOSOMES

in CYTOPLASM

Question 171

mRNA & Ribosome

Answer 171

mRNA attaches to SMALL ribosomal subunit (of 2)

ANTICODON of INITIATOR tRNA
binds to…
CODON of mRNA

(complementary bases)

Question 172

tRNA

Answer 172

takes appropriate AMINO ACID to POLYPEPTIDE

ANTICODON on tRNA binds to CODON of mRNA

anticodon determines AMINO ACID

Question 173

what happens after tRNA and mRNA connect?

Answer 173

LARGE RIBOSOMAL SUBUNIT attaches to SMALL SUBUNIT & mRNA

Creates functional ribosome

Question 174

functional ribosomes – 3 binding sites (for tRNA + AA)

Answer 174

A site
P site
E site

A site:
binds tRNA carrying next amino acid (“acceptor” site)

P site:
binds initiator tRNA
= tRNA carrying polypeptide chain

E site:
binds tRNA just before released from ribosome (“Exit” site)

Question 175

A site after P site

Answer 175

anticodon of another tRNA + AA pairs with mRNA Codon (in A site)

Peptide bond occurs between two AMINO ACIDS of two tRNAs

di-peptide attaches to tRNA on A-site

Question 176

shifting from A-site to P-site

Answer 176

Ribosome shifts both mRNA (and attached tRNAs) by ONE codon

A-site becomes open again

tRNA that enters E site EXITS

Question 177

when does translation end?

Answer 177

When Ribosome reaches STOP Codon on mRNA

protein detaches from final tRNA

ribosomal subunits separate

Question 178

which RNA types involved in TRANSLATION?

Answer 178

mRNA, tRNA

also rRNA because ribosomes made of rRNA

Question 179

what determines orders of AMINO ACIDS (& therefore structure of protein)

Answer 179

CODONS in mRNA (determined by DNA)

Question 180

free vs attached ribosomes

Answer 180

free produce proteins for cell

attached produce proteins for membrane, or exocytosis
(Enter ER & sent to Golgi body for processing before wrapped by VESICLE)

Question 181

POLYRIBOSOME (or POLYSOME)

Answer 181

multiple ribosomes TRANSLATING simultaneously

Why?
more proteins quicker
more efficient (less mRNA)

Question 182

2 types of cell division

Answer 182

1) MITOSIS
exact replica for growth/repair

2) MEIOSIS
creates gametes (sperm, ova)

Question 183

diploid vs haploid

Answer 183

2 sets of chromosomes = 46
= 2n or diploid
= n is number of distinct chromosomes

1 set of chromosomes = 23
= n or haploid

nearly all cells have 46 chromosomes
= 2 sets of 23
= one from each parent
= diploid

Gametes have 23
= sperm/ova
= haploid

Question 184

mitosis vs meiosis

Answer 184

mitosis:
= diploid SOMATIC cells replicate
= diploid becomes diploid

meiosis:
= diploid GERM cells replicate
= produce GAMETES
= diploid becomes haploid

Question 185

cell cycle

Answer 185

cycle for mitosis/meiosis to occur

Question 186

2 phases of cell cycle

Answer 186

1) INTERPHASE
2) MITOTIC PHASE (meiotic phase for meiosis)

(meiosis goes through cell cycle twice)

Question 187

mitosis

Answer 187

division of cell produces DAUGHTER CELLS

occurs in SOMATIC CELLS
occurs in GERM CELLS

diploid –> diploid

Question 188

mitosis and cell cycle

Answer 188

INTERPHASE
duplicate material

MITOSIS
divide contents

CYTOKINESIS
2 daughter cells separate

Question 189

1) INTERPHASE (mitosis)

Answer 189

1) increase cell size
2) duplicate organelles
3) duplicate DNA

Question 190

3 PHASES of INTERPHASE (mitosis)

Answer 190

G1 phase (growth 1)
S phase (Synthesis)
G2 phase

Question 191

G1 PHASE of interphase (mitosis)

Answer 191

cell grow
organelle duplicate

CENTROSOME duplication begins
(centrosome for division)

Note cell is metabolically active

Question 192

S PHASE of interphase (mitosis)

Answer 192

DNA duplicate (copy for each daughter cell)

1) DNA is unraveled via…
DNA HELICASE

2) complementary strands made via…
DNA POLYMERASE

3) = two identical copies of DNA

I.E.
92 CHROMOSOMES

Question 193

SISTER CHROMATIDS

Answer 193

I.E.
92 CHROMOSOMES(??? TYPO? SHOULD BE 92 CHROMATIDS INSTEAD?)

identical duplicate chromosomes

Question 194

G2 PHASE of interphase (mitosis)

Answer 194

growth

proteins/enzymes made

CENTROSOME duplication FINISHES

…

Question 195

MITOTIC PHASE of mitosis

Answer 195

PMAT (Mitosis) + Cytokinesis = MITOTIC PHASE

Prophase
Metaphase
Anaphase
Telophase

followed by CYTOKINESIS

Question 196

(early) PROPHASE (PMAT) phase of Mitotic phase (of Cell cycle)

Answer 196

early prophase:
CHROMATIN forms Chromosomes (via chromatin fibres)

Sister chromatids join to form X via Centromere

KINETOCHORE:
protein that stabilizes Centromere

REMINDER:
(histone –> nucleosome –> Linker DNA –> Chromatin –> Chromatin fibre –> Chromosome)

Question 197

(histone –> nucleosome –> Linker DNA –> Chromatin –> Chromatin fibre –> Chromosome)

Question 198

KINETOCHORE

Answer 198

KINETOCHORE:
protein that stabilizes Centromere

Question 199

(late) PROPHASE

Answer 199

nuclear envelope breaks

2 pairs of Centrosomes go to opposite ends

CENTRIOLES of centrosomes connect to CENTROMERES via…
MITOTIC SPINDLES

Question 200

MITOTIC SPINDLES

Answer 200

CENTRIOLES of centrosomes connect to CENTROMERES via…

Question 201

2) METAPHASE phase of Mitotic phase (cell cycle)

Answer 201

chromosomes aligned on METAPHASE PLATE (aka equatorial plate)

aligned in single line along middle of cell

Question 202

3) (early and late) ANAPHASE phase of mitotic phase (cell cycle)

Answer 202

early:
centromeres split apart via MITOTIC SPINDLES pull

towards Centrosomes

sister chromatids pulled apart

late anaphase:
plasma membrane begins to separate
= small CLEAVAGE FURROW

Question 203

4) TELOPHASE phase of mitotic phase (cell cycle)

Answer 203

Early telophase:
CLEAVAGE FURROW grows larger
–> chromatids at opposite ends (poles)

Late telophase:
separate NUCLEAR ENVELOPES form on each side

Question 204

Cytokinesis

Answer 204

plasma membrane forms separately around each DAUGHTER CELL

cells move apart

cell cycle / Mitosis complete

Question 205

Meiosis

Answer 205

division of single cell produce FOUR GAMETES

germ cells to gametes

diploid germ cells to haploid gametes

Question 206

meiosis differences from mitosis

Answer 206

meiosis cell division TWICE

takes place in gonads (testes males, and ovaries females)

Question 207

interphase of meiosis

Answer 207

same as interphase for mitosis

spermatogonia (precursor to sperm cell)
ova cells
1) Increase in cell size
2) Duplication of organelles
3) Replication of DNA

Question 208

PMAT for meiosis (Prophase)

Answer 208

major difference b/w mitosis and meiosis:

HOMOLOGOUS chromosomes join to form TETRAD

Question 209

tetrad and crossing over of chromosomes

Answer 209

“cross over” to exchange genetic materials

crossing over creates genotypic diversity (GENETIC DIVERSITY)

Question 210

Prophase (Continued)

Answer 210

same as mitosis:
nuclear envelope break
centrosome move
mitotic spindles

Question 211

metaphase

Answer 211

only difference is that TETRADS (not single chromosomes) line up

same:
on metaphase plate

Question 212

anaphase (meiosis)

Answer 212

sister chromatids stay together in meiosis

(mitosis, sister chromatids pulled apart)

Question 213

telophase + cytokinesis

Answer 213

results in 2 gametes with haploid chromosome (1n = 23)

have 23 chromosomes, but each have sister chromatid (?)

46 chromatids total –> 23 chromosomes

1/2 chromosome from each parent

in mitosis –> 46 chromatids total –> 46 chromosomes (single chromatid)

Question 214

meiosis 2

Answer 214

two haploid daughter cells enter meiosis 2

Question 215

meiosis 2 PMAT

Answer 215

same prophase, but no TETRADS –> I.e. same as mitosis (?)

METAPHASE 2 – same as mitosis (?)

ANAPHASE – same as mitosis –> sister chromatids split

TELOPHASE –> same as mitosis

result = 4 gametes (23 chromosomes each, 23 chromatids)

4 gametes similar but not identical

Question 216

stem cells called germ cells

Answer 216

born with many stem cells (called GERM cells)

they undergo MEIOSIS and form GAMETES

Question 217

what are the germ cells?

Answer 217

SPERMATOGONIA

OOGONIA

precursors to ova and sperm

Question 218

spermatogonia and oogonia, diploid or haploid?

Answer 218

diploid

Question 219

spermatocytes and primary oocytes

Answer 219

spermatogonia and oogonia create PRIMARY SPERMATOCYTES,
and PRIMARY OOCYTES

via…
many rounds of MITOSIS

these primary cells become sperm and ova via MEIOSIS

Question 220

spermatogonia –> Primary spermatocyte –> secondary spermatocyte –> spermatid –> mature sperm cell

oogonia –> primary oocyte –> secondary oocyte –> mature ovum

Question 221

how do primary spermatocytes become sperm cells?

Answer 221

males at puberty –> increase in T

primary spermatocytes enter MEIOSIS 1 & 2

results in SPERMATIDS

Question 222

SPERMIOGENESIS

SPERMATOZOA

Answer 222

spermatid becomes spermatozoa via SPERMIOGENESIS

Question 223

Oogenesis

Answer 223

In females, mitosis of the oogonium is complete prior to birth
Limited supply of primary oocytes
About 2 million at birth, 400,000 by puberty

The primary oocyte begins meiosis I in fetal development but it is arrested here until puberty

Each month, 6-20 primary oocytes complete meiosis I and enter meiosis II

These cells (usually only one) will finish meiosis II when and only if it is fertilized

Question 224

terms

Answer 224

While we are on the topic of gametes, let’s add in a few more terms that will pop up over the next few terms

Gamete: sperm or ovum with with 23 chromosomes

Zygote: is the union of 2 gametes (now 46 chromosomes)

Blastocyst: The zygote will divide into 8 celled blastocyst that implants into the uterine wall