Download Chapter 6 - Advanced Biology

Chapter 6
Energy for Life: Photosynthesis
Plants do photosynthesis for us,
right???
NOPE!
 Plants do photosynthesis because they
are solar powered—for their own benefit
 It is not some sort of altruistic gesture on
their part for our benefit
 We and other heterotrophs benefit from
their leftovers
Overview
Solar (light) energy chemical energy
 Organisms:

◦ Plants
◦ Algae
◦ Cyanobacteria

If all of the carbohydrate energy made by
autotrophs was instantly converted into
coal, it would fill 100 cars/second!
Flowering Plants
Photosynthesis carried out by green parts,
mainly leaves
 CO2 in through stomata

◦ Delivered to mesophyll cells: photosynthesis
specialists

H2O in through the root system
◦ Delivered through veins (xylem)

Combine in chloroplasts
The Chloroplast
Space inside=stroma
 Disks=thylakoids
 Stacks of disks=grana (sing. granum)
 All thylakoids are probably linked
together=thylakoid space
 Chlorophyll is found embedded in the
membranes of the thylakoid disks

◦ Other pigments too
Carbohydrates
Sole source of energy for most of life on
earth
 CO2 carbohydrate CO2 etc…

The Process

Carbohydrate has more energy than just
the CO2 and H2O ingredients that go
into it.
◦ More than the sum of its parts. Why?

Electrons from H2O are energized by
photons of light before they are given to
CO2
◦ That extra energy is what makes the
difference
Redox reaction
Redox = oxidation/reduction reaction
 Involves addition/subtraction of energized
electrons


Final product of photosynthesis is actually
a molecule called G3P
◦ (glyceraldehyde-3-phosphate)
Two sets of reactions
Light reactions and Calvin cycle
 Like many metabolic processes, there are
many steps to each one
 Light reactions: in thylakoid membranes

◦ Produces ATP and NADPH using light energy

Calvin cycle: in stroma
◦ CO2 taken up and converted to G3P using
energy from ATP and NADPH
Light Reactions
Light-involves a whole spectrum of
wavelengths with different amounts of
energy
 Visible light a small part of whole
spectrum
 Violet=most energy, red=least energy
 Only about 42% of light energy that hits
the Earth’s atmosphere reaches the
surface
 Most of that is in the visible spectrum

Photosynthetic Pigments
Chlorophylls and carotenoids
 Each type of molecule is only capable of
absorbing a small portion of the spectrum
 Plants have a range of pigments in order
to cover absorption of most of the
spectrum

◦ Chlorophyll a & b mostly absorb light in violet,
blue and red range
◦ Carotenoids can absorb some green, mostly
violet and blue
The Electron Pathway
Plants don’t use photons to energize ATP
and NADPH directly
 Use special collections of pigments and
proteins to collect and concentrate the
energy from photons

◦ Reaction centers
Electron Pathway (cont.)

Photosystem II (PSII) (named in order of
discovery)—splits water
◦ Absorbs photon energy and uses it to excite
electrons
◦ Excited electrons escape to near-by molecule
 Sent down electron transport chain
◦ Missing electrons are replaced by splitting
H2O
 Releases O and H+
Electron Pathway (cont.)

Electron Transport Chain
◦ A series of molecules pass the excited
electron from PSII down the line
◦ This energy is used to pull the H+ ions from
the split water into the thylakoid space in the
disks
◦ Creates a concentration gradient—lots of H+
builds up inside the disks (More on this
later…)
Electron Pathway (cont.)

Photosystem I (PSI)—makes NADPH
◦ Has another set of pigment molecules
◦ Photons energize electrons
◦ They escape and attach to NADP+NADPH
 Kind of like ATP
◦ Electrons are replaced by those coming off of
the electron transport chain
What about all of those H+ ions?

ATP synthase complex
◦ Adjacent to the photosysem/electron
transport chain area of the thylakoid
membrane
◦ Remember the Law of Entropy?
◦ H+ have been building up in the thylakoid
space, creating a concentration gradient
◦ They diffuse out of the thylakoid through the
path of least resistance—the ATP synthase
complex
ATP synthase
H+ ions flowing out of the thylakoid
release energy, just like a river or
waterfall
 ATP synthase harnesses that energy much
like an old-fashioned mill or a
hydroelectric turbine
 ATP synthase is an enzyme whose job is
to hook ADP and free phosphatesATP

Light Reactions Summary

PSII pigment absorbs light energy
◦ Excites electrons for transport chain

H2O is split at PSII to replace lost e◦ Makes H+ and O2 (waste)

e- transport chain pulls H+ into thylakoid
space
◦ Creates concentration gradient

PSI pigment absorbs light energy
◦ Excited e- charge up NADPH

H+ diffuses out through ATP synthase
◦ Makes ATP
Got it????
Good news: We’re halfway done!
Bad news: We’re not done yet!
We still don’t have any carbohydrate!
The Calvin Cycle
Out in the stroma of the chloroplast
 Use the energy from ATP and NADPH to
hook CO2 into chains of G3P
 Melvin Calvin use radioactive 14C to figure
out the steps involved
 Simplified: 3 Steps

◦ CO2 fixation
◦ CO2 reduction
◦ Regeneration of beginning substrate (RuBP)
Step 1: CO2 Fixation

Constant supply of RuBP hangs out in the
stroma of the chloroplast
◦ Made of 5 carbons

In step 1, CO2 is attached (fixed) to RuBP
◦ Enzyme that does this = rubisco
Makes a 6C molecule
 Immediately splits into 2 x 3C molecules

Step 2: CO2 reduction
More redox reactions!
 Step 2 is actually a series of reactions
 Energy (excited electrons) from NADPH
& ATP used to rearrange the 3C molecule
 Ends with G3P

◦ ADP and NADP+ sent back to thylakoid
membrane to get recharged
Step 3: Regeneration of RuBP
Step 1 & 2 change original RuBP molecule
to other forms
 Need to regenerate RuBP for the next
CO2 molecules coming in so the cycle can
start over
 Some carbon leaves the cycle as G3P,
most of it stays and gets rearranged back
into the starting material so the cycle can
keep going

The Fate of G3P
Plant cells are much more versatile than
animal cells
 They can do a lot with the raw ingredient of
G3P
 Mostly they put two G3P’s together to make
glucose
 Also:

◦ Fatty acids & glycerolsoils
◦ Add nitrogenamino acidsprotien
◦ Other sugars (fructose)
 Glucose + fructosesucrose
 Glucosestarchcellulose
But wait, there’s more!



Other types of photosynthesis
Adaptations for living in a dry environment
C4
◦ Rearranges location of cells where
photosynthesis happens
◦ Corn, sugarcane, Bermuda grass, crabgrass

CAM
◦ Rearranges time when parts of photosynthesis
happen—CO2 only fixed at night
◦ Most succulents in deserts, including cactuses.
Pineapple.
◦ More adaptive and widespread than C4