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1238386
ENZYMES AND CELL PROCESSES
Descripción
Christine Lee 6th Sept 2014
Sin etiquetas
respiration
photosynthesis
enzymes
celldivision
biology
cells
high school
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CChristine
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Resumen del Recurso
ENZYMES AND CELL PROCESSES
ENZYMES
enzymes are proteins
act as biological catalysts
controlling speed of chemical reactions in all organisms
increasing rate of chemical reactions
without enzymes, metabolism would take place too slowly for life to exist
are specific
1 enzyme catalyses only 1 type of reaction
each enzyme has a particular shape determined by sequence of amino acids
active site of an enzyme corresponds that of the substance it catalyses
the 'lock and key model'
in the way a key fits into a particular lock, the substrate fits into the active site of the enzyme
as the enzyme and substrate fit together,
chemical bonds are formed or broken
not consumed or broken down in reactions
i.e. 1 enzyme molecule can be reused at a fast rate
e.g. peroxidase in liver cells can catalyse breakdown of several million hydrogen peroxide molecules per min
shape maintained by weak H bonds.
susceptible to denaturing at high temp
as H bonds break, active site shape changes
enzyme unable to function
ENZYME ACTIVITY: FACTORS
Temperature
warmer the temp, faster the enzymes catalyse the reaction
at low temp, both enzyme and reactants move slowly
i.e. low kinetic Energy
less successful collisions between enzymes' active site and substrate
a slow ROR
as temp increases, both reactant and enzyme gain more kinetic energy
move faster and more successful collisions -> faster ROR
at high temp, enzyme active site changes shape (denatures)
substrate can no longer fit into active site
enzyme is unable to function
ROR decreases
(ROR= rate of reaction)
Substrate concentration
low substrate conc: less substrate
less chance of enzyme active site and substrate collisions
slow ROR
as substrate conc increases, more substrate is present
more chance of successful collisions with enzyme active site
faster ROR
at high substrate concentration
other factors will become limiting factors
ROR wont increase and levels off
e.g. enzyme conc, temperature
pH
enzymes work best at a specific pH
if pH is outside the range for an enzyme it denatures
substrate can then no longer fit and no longer acts as a catalyst
ROR decreases
e.g. amylase=7 pepsin=1~2
Co-factors
assist in catalysis
small inorganic ions or vitamins- coenzymes
necessary when only weak bonds form between enzyme and substrate
co-enzyme acts as a bridge, locking enzyme and substrate more tightly together
Inhibitors
substances that prevent enzymes catalysing reactions
poisons
can take over active site of enzyme
stop substrate from binding to active site
bonding to another part of enzyme
altering shape of active site
can no longer bind to substrate
usually temporary
PHOTOSYNTHESIS
occurs in chloroplasts of plant cells
process which plants produce GLUCOSE from CARBON DIOXIDE and WATER in presence of light Energy and chlorophyll
carbon dioxide + water ---------------> glucose + oxygen
light E and chlorophyll on the arrows
6CO2 + 6H2O -------------> C6H12O6 + 6O2
Light Phase
occurs in grana
electrons in chlorophyll are excited by solar E striking them
passed along series of carrier molecules and synthesises ATP from ADP
electrons return to chlorophylll
water is split to Hydrogen has and oxygen gas
Dark phase
light independent reaction
occurs in stroma
CO2 and H enter a complex biochemical cycle
are rearranged to form C6H12O6 (glucose) as a final product
ATP used to run the cycle
Glucose Produced
stored as insoluble starch in cells of roots
used in respiration
used to make other needed organic chemicals
e.g. fats, amino acids
Importance of Photosynthesis
converts solar E into chemical E as organic molecules
plants= autotrophs, producers
i.e. self feeders
starting point of food chains.
photosynthesis by plants accounts for increase in level of O2 in atmosphere
O2 is essential for aerobic respiration
(as O2 is a waste product of Photosynthesis)
RATE OF PHOTOSYNTHESIS
Temperature
increasing temperature increases R.O.Photosynthesis up to an optimum temp
when temp increases too far above optimum temp,
enzymes controlling photosynthesis denature and can no longer catalyse reaction
therefore photosynthesis ceases
Light Intensity
increasing light intensity increases R.O.Photosynthesis up to a maximum
above this maximum/limit, further increase in light intensity will have no further effect on R.O.P
because either
(i) light absorbing pigments are saturated
(ii) other factors becoming limiting factors
e.g. conc of CO2 or temperature
CO2 concentration
increasing CO2 conc increases R.O.P up to a maximum
above this maximum/limit, further increase in CO2 conc has no further effect on photosynthetic rate
due to other limiting factors
e.g. temperature, light intensity
because 3 factors combine to determne R.O.P
R.O.P can alter if one of the other factors change
ADAPTATIONS OF THE PLANT
Adaptations of Chloroplasts
grana have large S.A to absorb light, maximising Photosynthesis
stoma is clear to allow light to pass through to grana, maximising Photosynthesis
oval in shape
increase S.A : Vol ratio so it can take in more CO2 and H2O faster
faster rate of diffusion
maximising Photosynthesis
Adpatations of the Leaf
waxy cuticle and epidermal layer is clear
so that maximum light can penetrate to palisade layer
maximising photosynthesis
thin and flat
reduce distance for gases and substances to diffuse through stomata to photosynthesising cells
thin
allows light to pass through
flat
maximises S.A exposed to light
air spaces in spongy mesophyll
allows gases to diffuse faster to photosynthesising cells
palisade cells
richly supplied with chlorophyll
on upper surface of leaf to capture light
packed tightly
RESPIRATION
process that occurs in mitochondria of all living cells, breaking down glucose to produce ATP to be utilised for cell processes
GLUCOSE + OXYGEN -----------------> CARBON DIOXIDE + WATER + ENERGY
C6H12O6 + O2 ---------------> CO2 + H20 + ENERGY
Aerobic Respiration
requires oxygen for complete breakdown of glucose to CO2 H2O and Engergy in the form of ATP and heat
Gylcolysis
occurs in cytoplasm (no oxygen required)
changes glucose -----> pyruvate
produces 2 molecules of ATP
Krebs cycle
occurs in matrix (requires oxygen)
pyruvate + O2 ----> CO2 + H+ ions
(CO2 is released as a waste product)
H+ ions enter the electron transfer chain and 2 ATP molecules are produced
Electron transfer
occurs in cristae (requires oxygen)
H+ ions passed along chain releasing Energy
34~36 ATP molecules produced
carried out actively in cells with high E demands
e.g. muscle cells- contract and release - need ATP therefore have high no. of mitochondira
e.g. kidney tubules reabsorb nutrients (glucose) in filtrate using ATP through active transport therefore have high no. of mtochondria
CELL DIVISION
DNA (deoxyribonucleic acid) : large molecule in chromosomes that carries genetic info
double helix shape
each strand is made of many repeating units = nucleotides
bas pairs held together by weak H bonds
base pairing rule (A=T) (G=C)
2 strands are anti parallel
3' -> 5' and 5' -> 3'
DNA Replication
essential so that chromosomes are copied and give same genetic code to every new cell made
occurs prior to cell division
1 identical DNA molecules are produced
semi-conservative
1 side of final DNA strand = original
other side is new
Factors affecting DNA Replication
controlled by enzymes
any factor affecting enzymes affects rate of DNA replication
i.e. temp, amount of nucleotides, amount of enzymes
plants grow more in spring
warm and unlimited resources
animals grow more at certain stages of their life cycle
e.g. foetus or at young
during interphase
1. DNA molecule unzipped by DNA helicase breaking H bonds b/w complementary base pairs
2. nucleotides from within nucleus used to produce new strand of DNA
3. as DNA unzipps, DNA polymerase adds new nucleotides to 3' end of original strand producing a continuous strand
4. DNA polymerase only adds to nucleotides to 3' end of original strand
DNA polymerase must work from the replication down the strand producing Okazaki fragments
5. Okazaki fragments bonded by enzyme ligase to form a continuous strand
6. 2 identical complete DNA molecules twist into a helix
Mitosis
cell division process producing 2 genetically identical cells for growth and repair
so that same cell functions and processes continue
Mitosis is rapid when:
new cells are forming during periods of growth
e.g. zygote, embryo, infant and young organism or plants coming our of periods of dormacy
repairing after tissue damage
e.g. dermis of skin dividing rapidly to form replacement cells
in the bone marrow
constantly producing red blood cells
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