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The fungus can not be carried outPhotosynthesisHere's why:
Fungi are all heteroxigen, that is, they do not produce energy on their own.
Fungal cells do not have chloroplasts, cannot carry out photosynthesis, and the cell wall contains chitin (molds, chitin, chitin, chitin, dextran (yeasts, which carry out saprophytic or parasitic nutrition, and mostly grow in an acidic environment.
Composition of the fungus:
Fungi are heterotrophs with a nucleus and a cell wall. Except for a few lower types that are single-celled, most of the vegetative bodies are mycelium composed of slender tubular hyphae. The most characteristic of the cell walls of most fungi is the presence of chitin, followed by cellulose.
Common fungal organelles are: mitochondria.
microsomes, ribosomes, vacuoles, lysosomes, vesicles, endoplasmic reticulum, microtubules, flagella, etc.; Common inclusions include liver glucose, crystals, liposomes, etc.
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Fungal multicellular branched filaments (e.g., most molds) and single-celled individuals (e.g., most yeasts).
There are no chloroplasts in the fungal cells, they cannot photosynthesize, the cell wall contains chitin (mold, chitin, chitin), dextran (yeast), saprophytic or parasitic nutrition, and most of them grow in an acidic environment, in which molds are more terrestrial and yeast are more aquatic.
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Most of them can't, and there are exceptions.
Thank you for the trouble to adopt!
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It cannot be said that fungi cannot photosynthesize without chloroplasts, and cyanobacteria with phycocyanin can also carry out photosynthesis.
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The bacteria that can photosynthesize are mainly sulfur bacteria.
Photosynthetic bacteria can perform photoinward in an environment with light and hypoxia.
Synthesis, the use of light capacitance energy for photosynthesis, the use of light energy to assimilate carbon dioxide, unlike green plants, their photosynthesis does not produce oxygen. There is only one photosystem in the cell of photosynthetic bacteria, that is, PSI, and the original hydrogen donor of photosynthesis is not water, but H2S (or some organic matter), so that the result of its photosynthesis is to produce H2, which decomposes organic matter, and at the same time immobilizes the molecule nitrogen in the air to produce ammonia. In the process of assimilation and metabolism, photosynthetic bacteria have completed the three extremely important chemical processes in the natural material cycle: hydrogen production, nitrogen fixation, and decomposition of organic matter.
These unique physiological characteristics make their place in the ecosystem extremely important.
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Although photosynthetic bacteria do not have chloroplasts, they all have enzymes and pigments related to photosynthesis! So photosynthesis can also be carried out, and the process is basically the same as in chloroplasts!
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Photosynthetic pigments are otherwise similar to chloroplasts.
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Photosynthetic bacteria (referred to as photosynthetic bacteria) are a general term for a class of microorganisms that use light as energy and carbon dioxide or small molecule organic matter as carbon source, and hydrogen sulfide as hydrogen donor to carry out completely autotrophic or photoheterotrophic growth but do not produce oxygen. In nature, photosynthetic bacteria are extremely widely distributed and have strong vitality.
Photosynthetic bacteria: It is mainly used to quickly reduce COD and ammonia nitrogen in the water body of black and odorous rivers, eliminate hydrogen sulfide in the sediment, inhibit the generation of harmful bacteria and cyanobacteria, improve the transparency of the water body, play the role of water purification, and make the water quality of rivers, landscape water, lake water, black and odorous water bodies clear and transparent.
Gando photosynthetic strains.
02.Analysis of the main efficacy.
1. Water purification: It can greatly improve the transparency of the water body, so that the water quality of rivers, landscape water, lake water, black and odorous water bodies becomes clear and transparent.
2. Improve the underwater sediment: decompose the organic substances, hydrogen sulfide, ammonia nitrogen, COD and other harmful substances in the underwater sediment.
3. Improve water quality: quickly degrade bait, fish and shrimp feces and other organic wastes in the water body, absorb and convert ammonia nitrogen, nitrite, hydrogen sulfide and other harmful substances, and promote the healthy growth of breeding animals.
Gandu photosynthetic strains have a very miraculous effect on improving water quality, with: fast effect; High efficiency; High concentration (low dosage means low cost); Strong comprehensive treatment capacity (suitable for black and odorous water bodies, river treatment, municipal reservoirs, lake treatment, park landscape lakes, aquaculture farms); Simple operation; It can grow normally in extremely low temperature and rainy low-light environment, and can still multiply in large numbers under the conditions of weak light intensity or low dissolved oxygen, and has super adaptability.
Its disadvantage is different from other powdered strains of Gandhi, and the light synthesis of bacterial water-based agent does not have an advantage in packaging and transportation costs. As a result, some customers will reduce the amount of water purification in order to save costs, which will directly lead to a significant reduction in the effect of water purification.
River management, aquaculture management, looking for Gandu strains can be explored on site!
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With the development of aquaculture, the output of aquaculture units has increased significantly, but the water pollution is serious, especially in the later stage of rearing, the content of organic matter, ammonia and nitrite in the water is high, which seriously affects the growth of fish.
After photosynthetic bacteria are applied to the water body, it can degrade the residual feed, fish feces and other organic matter in the water body, and at the same time, it can also absorb and utilize ammonia, nitrite, hydrogen sulfide and other harmful substances in the water body.
The application of photosynthetic bacteria can effectively avoid the accumulation of solid organic matter and harmful substances, and play a role in purifying water quality.
Indirect oxygenation. The harmful substances in the substrate consume oxygen during the decomposition and transformation, and the photosynthetic bacteria absorb the ozone-depleting substances and play an indirect role in oxygenation.
Feed additives.
Due to the high nutritional value of photosynthetic bacteria, it can be used as a feed additive to supplement the nutritional imbalance of feed and promote growth.
Cultivating zooplankton bait.
Algae that fish like to feed on such as photosynthetic bacteria, diatoms, chlorella, etc., which are applied to the water body, become dominant algae, while harmful algae such as cyanobacteria are inhibited.
Photosynthetic bacteria can make a large use of ammonia nitrogen in water, which can effectively avoid the production of blooms, such as the large number of cyanobacteria.
Maintain the balance of the microecology.
On the one hand, it replenishes the microflora and decomposes harmful organic matter.
On the other hand, the fungal phase and algae phase of the pond mouth reach a balance, the water quality is not easy to change, it plays a role in stabilizing the water quality, and always maintains the balance of the aquaculture pond ecosystem.
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Photosynthetic bacteria are a class of microorganisms that have photosynthetic pigments and can carry out photosynthesis. It is a highly nutritious, high-efficiency, multi-purpose biological product. Photosynthetic bacteria are rich in nutrients, including proteins, fats, soluble sugars, carotene, vitamin B and 16 kinds of amino acids.
While absorbing light energy and carbon dioxide, photosynthetic bacteria can also use the organic acids, hydrogen sulfide and ammonia produced by the decomposition of residual organic matter in the water area by abnormal microorganisms, so as to not only purify the water body, but also provide food for organisms in the upper layer of the food chain, thus becoming an important link in the food chain in the water. Light and bacteria have a strong ability to harness light energy, and microorganisms are 100 times more capable of absorbing carbon dioxide than forests in terms of the volume of living organisms. Due to the abundant nutrition and peculiar functions of photosynthetic bacteria, photosynthetic bacteria are widely used in various industries such as breeding, planting, medicine, and environmental protection.
Effect of photosynthetic bacteria in aquaculture: 1. Purify water quality and prolong the time of water change; 2. Maintain the micro-ecological balance of the water environment; 3. Absorb the oxygen consumption factor in the water and increase the oxygen in the water; 4. Reduce the use of antibiotics and improve the quality of aquatic products; 5. Increase zooplankton in the water body as bait.
The role of photosynthetic bacteria in planting: 1. As an opsonin and fertilizer for plants; 2. Separate the hydrogen in the soil, and synthesize sugars, amino acids, vitamins, nitrogen compounds and physiological substances with the secretions of plant heels, organic matter in the soil, harmful gases (hydrogen sulfide, etc.), carbon dioxide, nitrogen, etc., to provide plant nutrition and promote plant growth; 3. The metabolites of the photosynthetic flora can not only be directly absorbed by plants, but also become nutrients for the reproduction of other microorganisms and increase the beneficial bacteria in the soil; 4. Help plants to photosynthesize, absorb nitrogen, phosphorus, potassium and other elements in the atmosphere and soil, thereby reducing the use and residues of pesticides and fertilizers, improving the quality of agricultural and sideline products, and improving economic benefits.
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Colored bacteria that use light energy and carbon dioxide to maintain autotrophic life Photosynthetic bacteria are widely distributed in soils, paddy fields, swamps, lakes, rivers and seas in nature, and are mainly distributed in anoxic areas where light can be transmitted in the aquatic environment.
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Fungi are a large group of lower plants that are extremely widely distributed and diverse in nature.
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Of course, there are many autotrophic bacteria in bacteria, there are chemoautotrophs (the use of chemical energy to synthesize organic matter) and photoautotrophic (the use of light energy to synthesize organic matter), photoautotroph, such as cyanobacteria, can carry out photosynthesis, photosynthesis does not have to be chloroplasts, as long as there are photosynthesis-related enzymes, pigments and other substances.
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Some! Have you ever watched a BBC show? Some bacteria will glow at night, which is the release of energy during the day!
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Let's talk about which organisms can photosynthesize!
1.Green. It's the leafy plants we usually see, the greens we eat every day, and so on. Note that mushrooms and other classes do not belong to this, mushrooms are fungi, saprophytic and cannot carry out photosynthesis.
2.Cyanobacteria. Although it is a prokaryotic organism and is just a small cell, it can carry out photosynthesis due to the presence of leaf green and cyanophycin.
As a result, only green plants and cyanobacteria can photosynthesize, while fungi, including bacteria and fungi, cannot photosynthesize without chlorophyll or other substances that can help with photosynthesis.
1. Which structure of the plant can be photosynthesized?
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You can take the lights like in the greenhouse.
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