光合作用 - web

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Transcript 光合作用 - web 

Photosynthesis
• Plants use water and carbon dioxide
from the air to synthesize glucose (葡萄
糖) and other carbohydrates (醣類). The
synthesis of organic compounds
begins in the chloroplast (葉綠體) with
photosynthesis.
•
The chloroplasts capture the energy from
light and fabricate (製造) glucose
molecules from carbon dioxide from the
air and water from the soil.
• The implementation of the electron
transport system (電子傳遞鏈) provides
energy for organic synthesis in the
form of ATP (腺嘌令核苷三磷酸) and the
reduced coenzyme (輔脢) NADPH (菸鹼
醯胺腺嘌呤二核苷酸磷酸).
• Along with the carbon dioxide and
water, this energy can be used in the
Calvin Cycle (卡爾文循環) to produce
glucose.
glucose (葡萄糖)
• Glucose is a carbohydrate, and is the most
important simple sugar (單糖) in human
metabolism (代謝作用).
• Glucose is also sometimes called dextrose
(右旋葡萄糖). Corn syrup is primarily
glucose.
• Glucose is one of the primary molecules
which serve as energy sources (能源) for
plants and animals. It is found in the sap
(汁液) of plants, and is found in the human
bloodstream where it is referred to as
“blood sugar“ (血糖).
• The normal concentration of glucose in the
blood is about 0.1%, but it becomes much
higher in persons suffering from diabetes.
• Energy from glucose is obtained from the
oxidation (氧化) reaction:
C6H12O6 + 6O2 --> 6CO2 + 6H2O
• When oxidized in the body, glucose
produces carbon dioxide, water, and some
nitrogen (氮) compounds and in the
process provides energy which can be
used by the cells.
• As a primary energy source in the body, it
requires no digestion and is often provided
intravenously (靜脈注射) to persons in
hospitals as a nutrient.
• In living organisms, the oxidation of
glucose contributes to a series of complex
biochemical reactions which provides the
energy needed by cells. The first step in
the breakdown of glucose in all cells is
glycolysis (糖解), producing pyruvate (丙酮
酸) which is the starting point for all other
processes in cellular respiration (呼吸作用).
• In cells where oxygen is present (aerobic
respiration,有氧呼吸) these processes
have been modeled in the TCA or Krebs
cycle (檸檬酸或克列伯循環). A major part
of the use of the energy from glucose
oxidation is the conversion of ADP to ATP,
with the energy-rich molecule ATP being
subsequently used as the energy currency
of the cell.
Fructose (果糖)
• Fructose is a carbohydrate, and is a
simple sugar found in fruits. It is often
called just "fruit sugar".
• Fructose is also found in honey. It is
classified as the sweetest of all the sugars.
Comparison of Glucose and
Fructose
• Glucose and fructose are the two most
important simple sugars for human
consumption. They have the same
molecular formula, C6H12O6, but have
different structures,hence, an isomer (同
分異構物).
• Glucose being classified as an aldehyde
(醛糖) and fructose as a ketone (酮糖).
Cellulose (纖維素)
• Cellulose is a form of carbohydrate in
which some 1500 glucose rings chain
together. It is the chief constituent of cell
walls (細胞壁) in living organisms. Wood
(木材) is mostly cellulose, making cellulose
the most abundant type of organic
compound on the Earth.
• Even though human digestion cannot
break down cellulose for use as a food,
animals such as cattle and termites (白蟻)
rely on the energy content of cellulose.
They have protozoa (單細胞原生動物) and
bacteria (細菌) with the necessary
enzymes (酵素) in their digestive (消化)
systems. Cellulose in the human diet is
needed for fiber (纖維).
Comparison of Starch and
Cellulose
• Both starches and cellulose are
carbohydrates which are classified as
polysaccharides (多醣類) since they are
composed of chains of glucose molecules.
While they are similar, starches can be
used as energy sources by the human
body while cellulose cannot.
• Enzymes are important in the metabolism
of foods, and these enzymes are very
specific. They are somewhat like keys
which will fit the geometry (幾何結構) of
the starch bonds, but not those of the
cellulose bonds.
Calvin Cycle (卡爾文循環)
• Carbon dioxide is captured in a cycle of
reactions known as the Calvin cycle or the
Calvin-Benson cycle after its discoverers.
It is also known as just the C3 cycle. Those
plants that utilize just the Calvin cycle for
carbon fixation are known as C3 plants.
• The fact that this 3-carbon molecule is the
first stable (穩定的) product of
photosynthesis leads to the practice of
calling this cycle the C3 cycle.
C3 plants
• In C3 plants the photosynthesis, carbon
fixation and Calvin cycle all occur in a
single chloroplast.
• About 85% of plant species are C3 plants.
They include the cereal grains: wheat, rice,
barley, oats. peanuts, cotton, sugar beets,
tobacco, spinach, soybeans, and most
trees are C3 plants. Most lawn grasses
such as rye and fescue are C3 plants.
C4 plants
• In C4 plants the photosynthesis takes
place in a chloroplast of a thin-walled
mesophyll (葉肉) cell and a 4-carbon acid
(malic acid,蘋果酸) is handed off to a
thick-walled bundle sheath (維管束鞘) cell
where the Calvin cycle occurs in a
chloroplast of that second cell. This
protects the Calvin cycle from the effects
of photorespiration (光呼吸).
• Only about 0.4% of the 260,000 known
species of plants are C4 plants. But that
small percentage includes the important
food crops corn, sorghum (高粱),
sugarcane and millet (小米).
CAM (景天酸) plants
• In CAM (Crassulacean Acid Metabolism)
plants the photosynthesis and initial
carbon fixation occur at night and a 4carbon acid is stored in the cell‘s vacuole
(液泡). During the day, the Calvin cycle
operates in the same chloroplasts.
• They represent about 10% of the plant
species and include cacti (仙人掌), orchids
(蘭花), maternity plant (落地生根), wax
plant (球蘭), pineapple (鳳梨), Spanish
moss (松蘿菠蘿), and some ferns (蕨類).
The only agriculturally significant CAM
plants are the pineapple and an Agave (龍
舌蘭) species used to make tequila (龍舌
蘭酒) and as a source of fiber.