Question

In: Biology

Cyanobacteria

Cyanobacteria

Solutions

Expert Solution

Blue-green algae, also called cyanobacteria, any of a large, heterogeneous group of prokaryotic, principally photosynthetic organisms. Cyanobacteria resemble the eukaryotic algae in many ways, including morphological characteristics and ecological niches, and were at one time treated as algae, hence the common name of blue-green algae. Algae have since been reclassified as protists, and the prokaryotic nature of the blue-green algae has caused them to be classified with bacteria in the prokaryotic kingdom Monera.

Like all other prokaryotes, cyanobacteria lack a membrane-bound nucleus, mitochondria, Golgi apparatus, chloroplasts, and endoplasmic reticulum. All of the functions carried out in eukaryotes by these membrane-bound organelles are carried out in prokaryotes by the bacterial cell membrane. Some cyanobacteria, especially planktonic forms, have gas vesicles that contribute to their buoyancy. Chemical, genetic, and physiological characteristics are used to further classify the group within the kingdom. Cyanobacteria may be unicellular or filamentous. Many have sheaths to bind other cells or filaments into colonies.

Cyanobacteria contain only one form of chlorophyll, chlorophyll a, a green pigment. In addition, they contain various yellowish carotenoids, the blue pigment phycobilin, and, in some species, the red pigment phycoerythrin. The combination of phycobilin and chlorophyll produces the characteristic blue-green colour from which these organisms derive their popular name. Because of the other pigments, however, many species are actually green, brown, yellow, black, or red.

Most cyanobacteria do not grow in the absence of light (i.e., they are obligate phototrophs); however, some can grow in the dark if there is a sufficient supply of glucose to act as a carbon and energy source.

In addition to being photosynthetic, many species of cyanobacteria can also “fix” atmospheric nitrogen—that is, they can transform the gaseous nitrogen of the air into compounds that can be used by living cells. Particularly efficient nitrogen fixers are found among the filamentous species that have specialized cells called heterocysts. The heterocysts are thick-walled cell inclusions that are impermeable to oxygen; they provide the anaerobic (oxygen-free) environment necessary for the operation of the nitrogen-fixing enzymes. In Southeast Asia, nitrogen-fixing cyanobacteria often are grown in rice paddies, thereby eliminating the need to apply nitrogen fertilizers.

Cyanobacteria range in size from 0.5 to 60 micrometres, which represents the largest prokaryotic organism. They are widely distributed and are extremely common in fresh water, where they occur as members of both the plankton and the benthos. They are also abundantly represented in such habitats as tide pools, coral reefs, and tidal spray zones; a few species also occur in the ocean plankton. On land, cyanobacteria are common in soil down to a depth of 1 m (39 inches) or more; they also grow on moist surfaces of rocks and trees, where they appear in the form of cushions or layers.

Cyanobacteria flourish in some of the most inhospitable environments known. They can be found in hot springs, in cold lakes underneath 5 m of ice pack, and on the lower surfaces of many rocks in deserts. Cyanobacteria are frequently among the first colonizers of bare rock and soil. Various types of associations take place between cyanobacteria and other organisms. Certain species, for example, grow in a mutualistic relationship with fungi, forming composite organisms known as lichens.

Cyanobacteria reproduce asexually, either by means of binary or multiple fission in unicellular and colonial forms or by fragmentation and spore formation in filamentous species. Under favourable conditions, cyanobacteria can reproduce at explosive rates, forming dense concentrations called blooms. Cyanobacteria blooms can colour a body of water. For example, many ponds take on an opaque shade of green as a result of overgrowths of cyanobacteria, and blooms of phycoerythrin-rich species cause the occasional red colour of the Red Sea. Cyanobacteria blooms are especially common in waters that have been polluted by nitrogen wastes; in such cases, the overgrowths of cyanobacteria can consume so much of the water’s dissolved oxygen that fish and other aquatic organisms perish.


Related Solutions

A) What is the natural habitat of Spirulina (cyanobacteria)? B) How does Spirulina (cyanobacteria) acquire nutrients...
A) What is the natural habitat of Spirulina (cyanobacteria)? B) How does Spirulina (cyanobacteria) acquire nutrients and transform energy? C) What is the type of movement of Spirulina (cyanobacteria)? D) What is the ecological role (niche) of Spirulina (cyanobacteria)? E) Name a unique structural feature of Spirulina (cyanobcateria).
what use is the nitrogen fixed by the cyanobacteria to mankind?
what use is the nitrogen fixed by the cyanobacteria to mankind?
Describe the unique qualities of cyanobacteria with respect to energy production.
Describe the unique qualities of cyanobacteria with respect to energy production.
Cyanobacteria and plants are photosynthetic organisms but their photosynthesis pathway are not identical. (a) You are...
Cyanobacteria and plants are photosynthetic organisms but their photosynthesis pathway are not identical. (a) You are required to summarize the major events (carbon fixation, electron transport chain) in cyanobacteria. The details of the summary should be concise and informative. The length of the summary should be less than 200 words.   (b)       Summarize how photosynthesis in bacteria is different from photosynthesis in plant. (c)        NAD and NADP are important molecules in plant cells. Describe in details the role of these molecules within a...
cyanobacteria = Describe how a patient with this disease is managed from a medical perspective, covering...
cyanobacteria = Describe how a patient with this disease is managed from a medical perspective, covering the following points: - Is there a specific treatment for this disease (eg. an antibiotic) and if so, how well does it work? If there is no treatment, how should the patient be managed? - What is the expected outcome after treatment (eg. would you expect the patient to be fully cured, or can there be long-term damage as a result of the disease,...
Determine True or False for the following statement   1. Archaea and cyanobacteria have DNA in their...
Determine True or False for the following statement   1. Archaea and cyanobacteria have DNA in their nuclei that directs protein synthesis. If you see a phylogenetic tree that illustrates adaptive radiation, it is reasonable to hypothesize that you might also see multiple lineages that went extinct just prior to the adaptive radiation event. Mature vessel and sieve tube cells in a plant's transport tissue have DNA in their nuclei that directs protein synthesis. The diverse, non-monophyletic group that we call...
Write notes on two of the following: 1. Cyanobacteria 2. Pseudomonas aeruginosa 3. The biochemistry of...
Write notes on two of the following: 1. Cyanobacteria 2. Pseudomonas aeruginosa 3. The biochemistry of acetic acid production 4. The purple sulphur bacteria
To explain the following concerning Cyanobacteria in general. 1) general characteristics 2) Type of reproduction and...
To explain the following concerning Cyanobacteria in general. 1) general characteristics 2) Type of reproduction and how 3) Why important evolutionarily, ecologically, and economically?
Some photosynthetic Cyanobacteria can fix N2 to NH4 + (using the enzyme Nitrogenase) when they are...
Some photosynthetic Cyanobacteria can fix N2 to NH4 + (using the enzyme Nitrogenase) when they are otherwise starved for nitrogen. They sense nitrogen starvation by sensing an excess of the amino acid Glutamate (Glu) within the cell. If there is adequate nitrogen, much of the Glutamate is converted to Glutamine (Gln), so that the [Glutamate] remains low. A. SKETCH the photosynthesis system in a typical aerobic Cyanobacterium. Be sure to show how O2 is involved, and how the three main...
what role(s) does iron play in controlling the abundance of cyanobacteria in temperate zone lakes.
what role(s) does iron play in controlling the abundance of cyanobacteria in temperate zone lakes.
ADVERTISEMENT
ADVERTISEMENT
ADVERTISEMENT