Prescott's Microbiology
10th Edition
ISBN: 9781259281594
Author: Joanne Willey, Linda Sherwood Adjunt Professor Lecturer, Christopher J. Woolverton Professor
Publisher: McGraw-Hill Education
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Chapter 30, Problem 1CHI
The unicellular cyanobacterium Prochlorococcus sp. is the most abundant photosynthetic microbe in tropical and subtropical oceans. At least two ecotypes exist: one is adapted to high light and the other to lower light intensities. How does the presence of these two ecotypes contribute to their physiological success and their numerical success? How would you determine the amount of fixed carbon they contribute to these open-ocean ecosystems?
Expert Solution
Summary Introduction
To determine: The way in which presence of two ecotypes (one adapted to high light and other to lower light) contribute to the physiological and numerical success of cyanobacterium Prochlorococcus sp.
Introduction: Prochlorococcus are green, small, and unicellular bacteria having chlorophyll a and chlorophyll b pigments. The species of this bacterium exist in two ecotypes: one which is adapted to the high intensity of light while the other adapted to low light intensity.
Explanation of Solution
The existence of cyanobacterium Prochlorococcus sp. in two different ecotypes, help them in their survival in different conditions. Because of this adaptation, these bacteria are the most abundant microbe in the oceans of tropical and subtropical those are capable of carrying out photosynthesis.
The presence of two ecotypes in this bacterial species, have given them an advantage over oxygenic phototrophic microbes. By having access to high as well as low light intensities, these bacteria are able to establish two different types of niche for themselves. The strains adapted to high light intensity can inhabit shallow water while those adapted to low light intensity can inhabit deep waters. In such a way, they both would not compete for similar resources with the same bacterial species.
Expert Solution
Summary Introduction
To determine: The way in which the amount of fixed carbon contributed by cyanobacterium Prochlorococcus to an open-ocean ecosystem can be determined.
Introduction: Prochlorococcus are green, small, and unicellular bacteria having chlorophyll a and chlorophyll b pigments. The species of this bacterium exist in two ecotypes: one which is adapted to the high intensity of light while the other adapted to low light intensity.
Explanation of Solution
The development of micro-ecosystem in the laboratory would be required to determine the amount of fixed carbon contributed by cyanobacterium Prochlorococcus to the open-ocean ecosystem. By setting up micro-ecosystem similar to the open-ocean ecosystem, would help in manipulating the amount of carbon fixed by the bacterium. The addition, as well as the removal of these microbes from the micro-ecosystem, will help in measuring the amount of fixed carbon by using various electrodes to test the level of carbon dioxide in the system.
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Chapter 30 Solutions
Prescott's Microbiology
Ch. 30.1 - Figure 30.1 The Carbonate Equilibrium System....Ch. 30.1 - What factors influence oxygen solubility? How is...Ch. 30.1 - Describe the buffering system that regulates the...Ch. 30.1 - Prob. 3RIACh. 30.1 - What features of a thermocline make it similar to...Ch. 30.2 - How is sulfur cycled between the anoxygenic...Ch. 30.2 - How do heterotrophic microbes contribute to the...Ch. 30.2 - Prob. 3MICh. 30.2 - Prob. 1.1RIACh. 30.2 - Prob. 1.2RIA
Ch. 30.2 - Describe the ecosystem that develops within a...Ch. 30.2 - What is marine snow? Why is it important in CO2...Ch. 30.2 - Prob. 2.2RIACh. 30.2 - Why do you think that, despite their great...Ch. 30.2 - List some metabolic strategies that have evolved...Ch. 30.2 - Describe the role of marine viruses in the...Ch. 30.2 - Explain what is meant by upside-down microbial...Ch. 30.2 - Prob. 2.7RIACh. 30.3 - Figure 30.15 Nutrient Cycling in Antarctic Lakes...Ch. 30.3 - How does the contribution of benthic autotrophs...Ch. 30.3 - Why does water turbulence play only a minor role...Ch. 30.3 - Why is mixotrophy suited for survival in Antarctic...Ch. 30.3 - What is an oxygen sag curve? What changes in a...Ch. 30.3 - What are point and nonpoint source pollution? Can...Ch. 30.3 - Prob. 2.1RIACh. 30.3 - Prob. 2.2RIACh. 30.3 - Why do cyanobacteria often dominate waters that...Ch. 30 - The unicellular cyanobacterium Prochlorococcus sp....Ch. 30 - How might it be possible to cleanse an aging...Ch. 30 - It is well known that bacterivory (the consumption...Ch. 30 - Prob. 4CHI
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