photosynthesis - Teaching Biology Project

... Photosynthesis is the chemical change which happens in the leaves of green plants. It is the first step towards making food not just for plants, but ultimately for every animal on the planet as well. ...

photosynthesis

... ATP. These now are in the Stroma outside the Thylakoid membrane and ready to fuel the Calvin Cycle which occurs there. ...

photosynthesis in bacteria

... The sources of hydrogens are hydrogen sulphide and, organic molecules. The major oxidation product is elemental sulphur, and not sulphate. Dubinina and Gorlenko (1975) established a new genus, Chloronema, with two species, C . giganteum and C . spiroideum. These are planktonic forms in fresh water l ...

Nitrogen Cycle

... to the plant. Overuse destroys crumb structure of the soil. It also increases the acidity and pollution. ...

Helpful and Harmful Bacteria

... releasing essential nutrients into the soil. • These nutrients can then be used for plant growth. ...

Note 16

... At low light intensity, when light intensity increases, the rate of photosynthesis increases because the amount of light energy controls the rate of photosynthesis. This shows that light intensity is the limiting factor. At high light intensity, when light intensity increases, the rate of photosynth ...

Lesson Objectives - Life Learning Cloud

... Can be made into insoluble starch which can be stored inside cells and used later Can be converted into cellulose used in call walls Can be converted to proteins Can be made into fats and oils ...

Photosynthesis Script of Narration Our fellow humans, the many

... But regardless of where it is, when sunlight falls on chlorophyll, light energy is absorbed and a series of complex chemical reactions begins. These reactions split some of the carbon dioxide molecules plants take in into carbon and oxygen atoms. The same thing happens to some of the water molecule ...

Studying photosynthetic organisms from different angles

... Franck Michoux ([email protected]), Niaz Ahmad ([email protected]) ...

How much glucose does a plant make?

... Light is needed for photosynthesis to occur. The plant’s leaves use the light to make a sugar called glucose. ...

Hematodinium - University of Maryland Eastern Shore

... • According to the endosymbiotic hypothesis, (advanced by Lynn Margulis and also Sarah Gibbs), eukaryotes arose from a symbiotic relationship between various prokaryotes. - Heterotrophic bacteria became mitochondria. (Heterotrophs are organisms that feed off of other organisms) - Cyanobacteria (phot ...

Photosynthesis - Madison Public Schools

... to produce their own food Because plants can “manufacture” their own energy directly, they are self-sufficient. ...

Photosynthesis

... Well photosynthesis allows plants and other organisms to take what is commonplace- sunlight, water, and carbon dioxide– and turn them into gold. ...

Microscopy

... • To identify a bacterial pathogen it is necessary to transfere it as a biological sample from site of infection on artificial medium simulating its requirement for growth and isolate grown bacteria in pure culture • A panel of tests are applied to identify the unknown colony • This is possible in g ...

3 Processes Necessary for Plants to Survive

... 2. The main function of the leaf is to: a. use sunlight to make food. b. to store water and minerals. c. to transport water and minerals. d. to make plants green. ...

C454_lect6 - University of Wisconsin

... 2.1 Bacteria vs. Green Plants Plants have two photosystems Photosystem I ...

PowerPoint 簡報

... 3. Three major metabolic pathways are used by bacteria to catabolize glucose: Glycolysis (EMP pathway), TCR cycle, & Pentose phosphate pathway ...

WS - Endosymbiotic Theory cells

... ancient single-celled organisms. At this time, there were only bacteria living on earth. Remember, bacteria are prokaryotes, this means that they have no organelles, no nucleus, and have circular DNA. Also, prokaryotes are small, singlecelled organisms. There is great diversity in bacteria and alway ...

Document

... a. using nitrogen to build molecules such as proteins and nucleic acids b. converting nitrogen in the air into a form usable by plants c. recycling nitrogen from organic matter in the soil d. absorbing N2 from the soil e. an unhealthy interest in nitrogen 25. The most abundant gas in our atmosphere ...

Understanding Our Environment

... Effects of Light and Temperature on Photosynthesis ...

Biology 123 SI- Dr. Raut`s Class Session 11

... 1. Why is the amount of ATP formed so variable? (Several answers. List them all) Pyruvate actually requires active transport to get into the mitochondria which means it uses some ATP. NADH that is produced in glycolysis cannot cross the mitochondria’s membrane and must use a shuttle system and give ...

Questions - National Biology Competition

... The conversion of nitrogen gas to nitrite by bacteria in a process called nitrification. The conversion of ammonium to nitrite by bacteria in a process called nitrification. The conversion of nitrogen gas to ammonia by bacteria in a process called nitrogen fixation. The conversion of nitrogen gas to ...

CHLOROPLASTS, CALVIN CYCLE, PHOTOSYNTHETIC …

... Several of these reactions in the Calvin cycle and gluconeogenesis (synthesis of 6C) are shared with glycolysis (breakdown of 6C), except the essentially irreversible reactions in glycolysis have to be bypassed by new reactions. These steps in the Calvin cycle consume 2ATP and 2NADPH per 6C formed f ...

Slide 1

... in photosynthesis exceeds the energy released by respiration. Which of the following situations is occurring? a. Community biomass is increasing. b. Community biomass is decreasing. c. A climax community has been reached. d. The first law of thermodynamics is not in effect. e. The second law of ther ...

Adaptations II

... 2) Make a diagram of the ligh dependent reaction of photosynthesis. Why is water needed? Why os oxygen produced? What are the two useful products, and what are they used for in the light Independent reaction? 3) Diagram the light independent reaction of C3 plants. 4) What is photorespiration and why ...

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Cyanobacteria

Cyanobacteria /saɪˌænoʊbækˈtɪəriə/, also known as Cyanophyta, is a phylum of bacteria that obtain their energy through photosynthesis. The name ""cyanobacteria"" comes from the color of the bacteria (Greek: κυανός (kyanós) = blue). They are often called blue-green algae (but some consider that name a misnomer, as cyanobacteria are prokaryotic and algae should be eukaryotic, although other definitions of algae encompass prokaryotic organisms).By producing gaseous oxygen as a byproduct of photosynthesis, cyanobacteria are thought to have converted the early reducing atmosphere into an oxidizing one, causing the ""rusting of the Earth"" and causing the Great Oxygenation Event, dramatically changing the composition of life forms on Earth by stimulating biodiversity and leading to the near-extinction of anaerobic organisms (that is, oxygen-intolerant). Symbiogenesis argues that the chloroplasts found in plants and eukaryotic algae evolved from cyanobacterial ancestors via endosymbiosis. Cyanobacteria are arguably the most successful group of microorganisms on earth. They are the most genetically diverse; they occupy a broad range of habitats across all latitudes, widespread in freshwater, marine, and terrestrial ecosystems, and they are found in the most extreme niches such as hot springs, salt works, and hypersaline bays. Photoautotrophic, oxygen-producing cyanobacteria created the conditions in the planet's early atmosphere that directed the evolution of aerobic metabolism and eukaryotic photosynthesis. Cyanobacteria fulfill vital ecological functions in the world's oceans, being important contributors to global carbon and nitrogen budgets.– Stewart and Falconer

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Cyanobacteria