bio quiz #6
Chlorophyll
A green pigment found in the chloroplasts of plants, algae, and some bacteria
How Energy is Produced?
Breaking bonds between Phosphate molecules releases stored energy!
Chrolophyll
Chlorophyll is the pigment that reflects green light
1st law of thermodynamics
Energy cannot be created or destroyed
Light-dependent
- needs sunlight -makes NADPH -uses electron transport chain
Light Independent (Calvin Cycle)
-carbon dioxide, ATP and NADPH go into Calvin Cycle -Sugar (glucose) is the product
ADP
ADP stands for adenosine diphosphate: Di = two ADP is similar to ATP but it has 2 'P's - Phosphates
ATP
ATP: A high energy molecule Sugars have to be converted into ATP so our body can use energy. ATP stands for Adenosine Triphosphate
During photosynthesis, light energy is used to synthesize carbon dioxide (CO2) and water (H2O) into glucose (C6H12O6) and oxygen (O2). The complex series of chemical reactions is summarized by the following formula: 6CO2 + 6H2O + light energy 🡪 C6H12O6 + 6O2 In the Gizmo, what light intensity and CO2 level do you think will maximize the rate of photosynthesis?
I think the highest light intensity and CO2 levels will maximize the rate of photosynthesis because that would cause the greatest amount of oxygen production, which will cause a rapid rate of photosynthesis.
Move the Temperature slider up and down. Were you able to increase oxygen production? (Return the slider to 24°C when finished.)
I was not able to increase the oxygen production.
Suppose you were a farmer trying to grow plants in a greenhouse. Why would it be important to know what the limiting factor is?
If I were a farmer trying to grow plants in the greenhouse it would be important for me to know the limiting factor of the plants so I don't have to spend unnecessary money. Which would be because I would be able to know what parts are crucial to the results I want. From knowing the limiting factor it would be faster to produce a certain plant I want to grow.
Why would it be hard to find the ideal CO2 level if the light intensity were very low?
If the light intensity was very low, this would cause the oxygen production to be very low near to zero, no matter what the CO2 level you use.
The human body is about two-thirds oxygen Oxygen's influence and its role in Human Body
In the human body, the oxygen is absorbed by the blood stream in the lungs, being then transported to the cells where an elaborated change process takes place. Oxygen plays a vital role in the breathing processes and in the metabolism of the living organisms. Probably, the only living cells that do not need oxygen are some anaerobic bacteria that obtain energy from other metabolic processes. The nutrient compounds, inside of the cell, are oxidized through complex enzymatic processes. This oxidation is the source of energy of most of the animals, mainly of mammals. The products are carbon dioxide and water (exhaled air has a relative humidity of 100%), which are eliminated by the human body through the lungs.Click the link below to read more about: The Physiology of Respiration in human and oxygen transport Appropriate levels ofoxygenare vital tosupport cell respiration. Oxygen plays an important role in the energy metabolism of living organisms. The living cell is the site of tremendous biochemical activity called metabolism. This is the process of chemical and physical change which goes on continually in the human body: build-up of new tissue, replacement of old tissue, conversion of food to energy, disposal of waste materials, reproduction - all the activities that we characterize as "life." Research shows that cells have only a "limited number" of cell divisions possible in a human lifetime. Studies show that by the time you're 20 most of the cells that make up your body have used up half of the divisions available in their cell lifespan. By the time you're 40, there are maybe only 30% of your possible cell divisions left. When the cells use up their natural allotted cell divisions, the end is death! Cellular respiration Molecular oxygen, O2, is essential for cellular respiration in all aerobic organisms. Oxygen is used as an electron acceptor in mitochondria to generate chemical energy. Take a look inside the cell to see these "powerhouses" of the cell, petite organelles mitochondria, click here. In the human body, oxygen uptake is carried out by the following processes: Oxygen diffuses through membranes and into red blood cells after inhalation into the lungs. The heme group (that consists of an iron) of hemoglobin binds oxygen when it is present, changing haemoglobin's color from bluish red to bright red. A liter of blood can dissolve 200 cc of oxygen gas, which is much more than water can dissolve. After being carried in blood to a body tissue in need of oxygen, O2 is handed-off to an enzyme (monooxygenase) that also has an active site with an atom of iron. The enzyme uses oxygen to catalyze many oxidation reactions in the body (metabolism). Carbon dioxide, a waste product, is released from the cell and into the blood, where it combines with bicarbonate and hemoglobin for transport to the lungs. Blood circulates back to the lungs and the process repeats. Find out more about cell, click here A small part of the waste that comes from our body cells is watery, or easily dissolved in water; Furthermore, this is transported in the blood to a specific set of filter organs—the liver and the kidneys—and poured out of the body as the urine. Another part of waste is passed off through the skin in the form of watery vapor as perspiration, or sweat. But part of the waste can be gotten rid of only by burning, and what we call burning is another name for combining with oxygen, or to use one word—oxidation; Moreover, this is precisely the purpose of the carrying of oxygen by the little red blood cells from the lungs to the deeper parts of the body—to burn up, or oxidize, these waste materials which would otherwise poison our cells. When they are burnt, or oxidized, they become almost harmless. While oxygen supports our life, and "oxidizes" or "burns" food to create energy and heat for our bodies, certain types of altered oxygen molecules called "Free Radicals" which are ever-present in our bodies, will damage our own cells and even our DNA, causing degeneration and diseases such as cancer. A "radical" is an atom with an unbalanced electrical charge, and it will seek to steal electrons from other atoms - such as the atoms of our body cells! As Dr. Tai likes to say, the oxidation of cells by free radicals makes the human body "rust" like oxidation of metal makes it rust - and you know what rust does to the strength and natural beauty of the metal. Our bodies need the help of "antioxidants" to neutralize the oxidation properties of those invading free radicals. There are thousands of research papers that point to the production of free radicals as the primary cause of aging. Free radicals are unstable molecules in the body created as part of the waste products or normal cellular metabolic activities. YOU ARE ONLY AS OLD AS YOUR CELLS! Recent research has given new hope to the task of rejuvenating and extending the lifespan of cells. This cellular rejuvenation, life extension, and improved vitality has been achieved using special antioxidants that can actually keep cells looking and acting younger - and may even reverse the aging process ! The human body represents one of the most perfectly designed and coordinated structures. However, all these structures are held in position by a dense network of systems which constantly work together to keep us going.The brain represents only 2% of the human body weight; it receives 15% of the cardiac output, 20% of total body oxygen consumption, and 25% of total body glucose utilization. The energy consumption for the brain to simply survive is 0.1 calories per minute, while this value can be as high as 1.5 calories per minute during crossword puzzle-solving. When neurons in a particular region of the brain are highly active, they consume a great deal of oxygen, which results in recruitment of extra blood flow to that region. Neurodegenerative diseases, such as Alzheimer's disease, Parkinson's disease, motor neurone disease, and Huntington's disease are caused by the gradual death of individual neurons, leading to decrements in movement control, memory, and cognition. Mental performance in the human body can be improved by "feeding" the brain with extra oxygen or glucose, according to research published today that could have implications for the treatment of dementia. It's well known that after about nine minutes of no oxygen, from drowning or whatever, you can kiss your brain good-bye. Brain cells are extremely sensitive to oxygen deprivation and can begin to die within five minutes after oxygen supply has been cut off. Decrease of oxygen supply to the brain even though there is adequate blood flow caused by carbon monoxide poisoning, pollution in our cities, choking or suffocation can create conditions like tiredness, depression, irritability, poor judgment and health problems. Increasing the oxygen supply to the brain and nervous system will reverse these conditions. The oxygen regimen improves alertness, reflexes, memory and apparently intelligence, and may offer the elderly a new weapon against senility and related disorders. Alzheimer's and Parkinson's are reported to be responding to it. Alcoholics who start taking oxygen supplement soon loose interest in alcohol. To read more about Brain, click here! Chemical composition of the human body The size of the human body is firstly determined by diet and secondly by genes. Body type (slim, fat, tall, petite, wide-shouldered, etc) and body composition (percentages of fat, bone and muscle) are influenced by postnatal factors such as diet and exercise. By the time the human reaches adult-hood, the body consists of close to 100 trillion cells. Each is part of an organ system designed to perform essential life functions. By mass, human cells consist of 65-90% water (H2O), and a significant portion is composed of carbon-containing organic molecules. Oxygen therefore contributes a majority of a human body's mass, followed by carbon. 99% of the mass of the human body is made up of the six elements: oxygen, carbon, hydrogen, nitrogen, calcium, and phosphorus. In order to understand the relation of food to the sustenance and repairing of the body, it will be necessary to learn, first, of what the human body is composed, and the corresponding elements contained in the food required to build and keep the body in a healthy condition. The following table gives the approximate analysis of a man weighing 148 pounds: ElementPercent by massOxygen (O)65Carbon (C)18Hydrogen (H)10Nitrogen (N)3Calcium (Ca)1.5Phosphorus (P)1.2Potassium (K)0.2Sulfur (S)0.2Chlorine (Cl)0.2Sodium (Na)0.1Magnesium (Mg)0.05Iron (Fe), Cobalt (Co), Zinc (Zn), Iodine (I)<0.05 eachSelenium (Se), Fluorine (F)<0.05 each As food contains all these elements, and as there is constant wearing and repair going on in the body, it will be readily seen how necessary some knowledge of the relation of food to the body is, in order to preserve health.Oxygen is found in almost all biomolecules that are important to (or generated by) life. Only a few common complex biomolecules, such as squalene and the carotenes, contain no oxygen. Of the organic compounds with biological relevance, carbohydrates contain the largest proportion by mass of oxygen. All fats, fatty acids, amino acids, and proteins contain oxygen (due to the presence of carbonyl groups in these acids and their ester residues). Read further here about: periodic table of the chemical elements and dietary minerals in the human body."The molecules of hydrogen, oxygen, carbon, nitrogen, iron, phosphorus, calcium, and so on, in a living body, are themselves no more alive than the same molecules in inorganic matter. Nearly nine tenths of a living body is water; Is not this water the same as the water we get at the spring or the brook? Is it any more alive? Does water undergo any chemical change in the body? Is it anything more than a solvent, than a current that carries the other elements to all parts of the body? There is any number of chemical changes or reactions in a living body, but are the atoms and molecules that are involved in such changes radically changed? Can oxygen be anything but oxygen, or carbon anything but carbon? Is what we call life the result of their various new combinations? Chemistry is all-potent. A mechanical mixture of two or more elements is a simple affair, but a chemical mixture introduces an element of magic. Free or single atoms are very rare; they all quickly find their mates or partners. This eagerness of the elements to combine is one of the mysteries. A living thing is more than a machine, more than a chemical laboratory. Life comes to matter as the flowers come in the spring, — when the time is ripe for it, — and it disappears when the time is over-ripe. Man appears in due course and has his little day upon the earth, but that day must as surely come to an end. Yet can we conceive of the end of the physical order? The end of gravity? Or of cohesion? The air may disappear, the water may disappear, combustion may cease; but oxygen, hydrogen, nitrogen, and carbon will continue somewhere. There is no life without chemistry, but there is chemistry without life." Fragments from the book: The Breath of Life by John Burroughs
Why would it be hard to find the ideal light intensity if the temperature were very hot or cold?
It would be hard to find the ideal light intensity if the temperature were too hot or cold because the environmental conditions of the plant would prevent the reactions to be accurate.
Pigments
Light absorbing substance is called a pigment. Pigments absorb some forms of light and reflect others. Chlorophyll absorb Red and blue and reflect green and Yellow rays.
Select the BAR CHART tab. On the graph, notice the Oxygen flow bar. Move the Light intensity slider back and forth. How does light intensity affect oxygen production?
Light intensity affects oxygen production because when there isn't enough light little no oxygen is being produced, when there is a lot of light more oxygen is being produced.
Heterotroph:
Organisms that CANNOT use the sun's energy to make sugar— Ex: animals and most microorganisms
Autotrophs (auto = self)
Organisms that use light energy from the sun to produce chemical energy - sugar. Ex: plants, algae
Inside the chloroplast
Outer membrane, inner membrane, thylakoids; single green disc, Stroma; liquid space between green stacks, Granum; stack of green discs
How does oxygen production relate to the rate of photosynthesis?
Oxygen production relates to the rate of photosynthesis because when there is a high oxygen production there is a high rate of photosynthesis.
Chemical formula for photosynthesis
Reactants Products Carbon dioxide+water+ light------> glucose +oxygen 6CO2 + 6H2O + light --------> C6H12O6 + 6O2
Carotenoids:
Reflect red, yellow and orange
Anthocyanin:
Reflects blue and purple
Carbohydrates (sugar) help make other molecules in your body
Sugars can break down or connect to other elements (ingredients) to form: 1. amino acids 2. saturated fat 3. ATP 4. Nitrogenous bases (DNA)
Challenge: In each of the situations below, use the Gizmo to find the limiting factor.
Temperature; 25°C, Light intensity; 60%,CO2 level;700ppm, Limiting factor; light intensity Temperature; 15°C, 30°C, Light intensity; 20%, 50%,CO2 level; 200ppm, 400ppm, Limiting factor; temperature
the color of a light wave is determined by its wavelength. On the COLOR tab, slowly drag the Light wavelength slider back and forth and observe the effect on oxygen production. How does the color of light affect the rate of photosynthesis?
The color of light has a large effect on the rate of the photosynthesis because the chlorophyll absorbs certain colors of the spectrum and blocks other colors of the spectrum.
Photosynthesis:
The process where sunlight is converted into chemical energy = glucose
How does CO2 level affect oxygen production?
When the CO2 levels are low there is little to no oxygen production, when the CO2 levels are higher there is lots of oxygen production.
How does temperature affect oxygen production?
When the temperature slider is at its highest 50℃, there is no oxygen production, when the temperature is at its lowest 0℃ there is no oxygen production. This means that when the temperature is in between 0℃ - 50℃ there is oxygen production.
So How Does A Cell Use Glucose for Energy? cell respiration
You need to know what molecule we actually get energy from in our cells... ATP
glucose
a sugar that is an important energy source in living organisms
Where does all energy come from?
all energy comes from the sun
limiting factor
anything that constraints somethings size/slows or stops it from growing
Cellular energy
energy from living things comes from food. Originally the energy in food comes from the sun.
Nanometer(nm)
one billionth of a meter
Photosythesis
only uses "visible light" to make glucose
Photosynthesis
process used by plants to harness energy from the sunlight and turn it into chemical energy
reactants of photosynthesis
sunlight, carbon dioxide, and water
Energy moves up through each level
top predators carnivores herbivores producers energy
Observe the left pane closely. What do you think the bubbles are?
I think the bubbles are the oxygen being released into the air.
Use the Gizmo to find the ideal conditions for photosynthesis. Use any method you like. When you think you have the answer, list the conditions below.
Temperature: 25℃ Light intensity: 90% CO2 level: 1000ppm Oxygen production: 51.8
Form hypothesis: Which color of light do you think will maximize the rate of photosynthesis?
The color of light that will maximize the rate of photosynthesis would be orange.
Which colors were absorbed best by the plant?
The colors that were absorbed the best were blue-violet and red-orange.
Which colors were absorbed the worst?
The colors that were absorbed the worst were green-yellow.
In this situation, what was the limiting factor?
The limiting factor was CO2 because when it was decreased or increased, it was still able to increase the oxygen production. I know that CO2 is the limiting factor because it always increases oxygen production..
carbon dioxide
a chemical compound composed of one carbon and two oxygen atoms
products of photosynthesis
oxygen and glucose (sugar)
Wavelength
the distance through two waves
When we look at a leaf, we see the colors of light that are reflected off its surface. How does this explain the relatively low flow of oxygen in green light?
This helps explain the relatively low flow of oxygen in green light because it isn't absorbed by the chlorophyll, and photosynthesis doesn't work well in green light since it doesn't actually absorb the needed light.
Move the CO2 level slider back and forth. Were you able to increase oxygen production? (Return the slider to 200 ppm when finished.)
I was able to increase the oxygen production.
Move the Light intensity slider back and forth. Were you able to increase oxygen production? (Return the slider to 50% when finished.)
I was not able to increase the oxygen production.