Introduction to Organisms: Difference between revisions
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Since, all three domains of life: archaea, bacteria and eukarya, inhabit the soil environment it is difficult to observe each microbe individually within the soil ecosystem.Only a few representative groups of each domain will be discussed to provide examples of the roles these organisms play in soil. This page attempts to outline the major microbial groups within the diverse soil environment.The interactions between soil microbes amongst the soil microbial diversity. The concept of survival of the fittest is seen in the soil food web, which allows only a selective few with the correct nutrients to thrive in a soil environment. The interactions of soil microbes is not only a part of nature but it also only selects those organisms that are fit for survival, growth and reproduction. The soil food web and symbiotic relationships are used to explain the dynamic interactions between soil organisms. | Since, all three domains of life: archaea, bacteria and eukarya, inhabit the soil environment it is difficult to observe each microbe individually within the soil ecosystem.Only a few representative groups of each domain will be discussed to provide examples of the roles these organisms play in soil. This page attempts to outline the major microbial groups within the diverse soil environment.The interactions between soil microbes amongst the soil microbial diversity. The concept of survival of the fittest is seen in the soil food web, which allows only a selective few with the correct nutrients to thrive in a soil environment. The interactions of soil microbes is not only a part of nature but it also only selects those organisms that are fit for survival, growth and reproduction. The soil food web and symbiotic relationships are used to explain the dynamic interactions between soil organisms. | ||
==Soil Food Web and Microbial Interactions== | |||
To survive in a soil environment, an organism must be able to adapt to changing environments and organism interactions. The interactions seen between organisms allows only the fittest to survive, thrive, grow and reproduce in the soil. The only type of interaction shown in (Figure 1.2) is predation. Other common interactions in the soil environment are: | |||
I. Commensalism: Organism (A) benefits from the presence of Organism (B) while (B) is unaffected by the presence of (A).[32] | |||
II. Mutualism: Organism (A) benefits from Organism (B) and Organism (B) benefits from Organism (A) and becomes a necessary association for each other’s survival. [32] [33] | |||
III. Synergism: Organism (A) benefits from Organism (B) and Organism (B) benefits from Organism (A) but the relationship is not necessary for survival.[33] | |||
IV. Competition: Depending on the organisms this interaction benefits organisms who can readily adapt to the environment and overcome any obstacles needed to survive, grow and reproduce.[33] | |||
V. Amensalism: An interaction in which Organisms (A) and (B) develop a partnership where (B) is unaffected by (A) but organism (A) is negatively affected by (B).[34] | |||
VI. Parasitism: Organism (A) benefits from Organism (B) but Organism (B) does not benefit positively from Organism (A). | |||
VII. Predation: “An interaction between organisms in which one benefits and one is harmed based on the ingestion of the smaller sized organism, the prey, by the larger organism, the predator.”[33] | |||
The soil food web consists of microbes which play an important role in maintaining the complexity of the soil environment. The interactions observed in the food web are not only based on predation, which directly affects the nutrient cycling and degradation of pollutants, but also the formation of aggregates.[35] The production of specific nutrients, such as ammonium created by microbial metabolic functions, helps to enrich the the soil for plant use.[35] Soil organism activity, along with the presence of soil organic matter, create stabilizing aggregates.[35] The hyphae within the soil environment and the microbes help form large, stable aggregates in the soil habitat.[35] The biodiversity in the soil plays a pivotal role in degrading pollutants, and also prevents pathogens from inhabiting the soil environment through competition.[35] The food web in the soil environment is necessary to maintain the soil nutrients, biological activity, and detoxifying pollutants. Thus, it directly maintains cultivation, productiveness and prosperity of the soil. | |||
In (Figure 1.1), all three domains, Archaea, Bacteria, and Eukarya, are represented in the soil food web. If one takes a closer look at the figure, the soil food web is not only dependent on small and large microbes but also dead organic matter and plant roots. Dead and living matter in the soil environment contribute to maintaining the food web. Plant residues also are apart of the soil food web. They contribute to the soil’s carbon source.[35] The plant residues either, release carbon dioxide to the environment, or contribute to the soil organic matter. Soil organic matter contributes to soil’s richness and helps to form aggregates.[35] The main focus in the image above is the diversity of organisms, both in domains and in size. The larger organisms are usually the predators. The smaller organisms eventually fall prey, due to their limited mobility, respiration, and size. The eukarya and small bacteria are apparent figures seen in the figure above, but archaea also contribute to the food cycle as they break down ammonia for plants to use. [35] | |||
The notable interactions of life that take place in the soil environment is evident both below-ground level, as seen in the figure 1.1, but also in the above-ground level.[36] Worms also impact the soil food web, acting as both drivers of the food web both belowground and aboveground.[36] |
Revision as of 22:10, 14 March 2016
Introduction
The soil ecosystem in an important environment that allows both plants and animals to survive, grow and reproduce. The significance of the soil as an ecosystem is at times overlooked despite its major contributions to the environment. The soil environment is a complex and varied microbial habitat.[1] The plants and organisms inhabiting the soil contribute to its thriving diversity. Soil life is diverse in morphology, metabolism, size, and many other characteristics. It is believed that “there is sufficient [microbial] DNA in 1 g of soil to extend 1,598km.” [30] Soil is a heterogeneous environment with various zones of rhizosphere, aggregates, organic matter and animal residues.[31] Given each zone is a small component of the larger soil ecosystem, rhizosphere accounts for only 5 to 7 percent of the soil environments but contains over “70 percent of the bacterial- and fungal-feeding nematodes.”[31]
Since, all three domains of life: archaea, bacteria and eukarya, inhabit the soil environment it is difficult to observe each microbe individually within the soil ecosystem.Only a few representative groups of each domain will be discussed to provide examples of the roles these organisms play in soil. This page attempts to outline the major microbial groups within the diverse soil environment.The interactions between soil microbes amongst the soil microbial diversity. The concept of survival of the fittest is seen in the soil food web, which allows only a selective few with the correct nutrients to thrive in a soil environment. The interactions of soil microbes is not only a part of nature but it also only selects those organisms that are fit for survival, growth and reproduction. The soil food web and symbiotic relationships are used to explain the dynamic interactions between soil organisms.
Soil Food Web and Microbial Interactions
To survive in a soil environment, an organism must be able to adapt to changing environments and organism interactions. The interactions seen between organisms allows only the fittest to survive, thrive, grow and reproduce in the soil. The only type of interaction shown in (Figure 1.2) is predation. Other common interactions in the soil environment are:
I. Commensalism: Organism (A) benefits from the presence of Organism (B) while (B) is unaffected by the presence of (A).[32]
II. Mutualism: Organism (A) benefits from Organism (B) and Organism (B) benefits from Organism (A) and becomes a necessary association for each other’s survival. [32] [33]
III. Synergism: Organism (A) benefits from Organism (B) and Organism (B) benefits from Organism (A) but the relationship is not necessary for survival.[33]
IV. Competition: Depending on the organisms this interaction benefits organisms who can readily adapt to the environment and overcome any obstacles needed to survive, grow and reproduce.[33]
V. Amensalism: An interaction in which Organisms (A) and (B) develop a partnership where (B) is unaffected by (A) but organism (A) is negatively affected by (B).[34]
VI. Parasitism: Organism (A) benefits from Organism (B) but Organism (B) does not benefit positively from Organism (A).
VII. Predation: “An interaction between organisms in which one benefits and one is harmed based on the ingestion of the smaller sized organism, the prey, by the larger organism, the predator.”[33]
The soil food web consists of microbes which play an important role in maintaining the complexity of the soil environment. The interactions observed in the food web are not only based on predation, which directly affects the nutrient cycling and degradation of pollutants, but also the formation of aggregates.[35] The production of specific nutrients, such as ammonium created by microbial metabolic functions, helps to enrich the the soil for plant use.[35] Soil organism activity, along with the presence of soil organic matter, create stabilizing aggregates.[35] The hyphae within the soil environment and the microbes help form large, stable aggregates in the soil habitat.[35] The biodiversity in the soil plays a pivotal role in degrading pollutants, and also prevents pathogens from inhabiting the soil environment through competition.[35] The food web in the soil environment is necessary to maintain the soil nutrients, biological activity, and detoxifying pollutants. Thus, it directly maintains cultivation, productiveness and prosperity of the soil.
In (Figure 1.1), all three domains, Archaea, Bacteria, and Eukarya, are represented in the soil food web. If one takes a closer look at the figure, the soil food web is not only dependent on small and large microbes but also dead organic matter and plant roots. Dead and living matter in the soil environment contribute to maintaining the food web. Plant residues also are apart of the soil food web. They contribute to the soil’s carbon source.[35] The plant residues either, release carbon dioxide to the environment, or contribute to the soil organic matter. Soil organic matter contributes to soil’s richness and helps to form aggregates.[35] The main focus in the image above is the diversity of organisms, both in domains and in size. The larger organisms are usually the predators. The smaller organisms eventually fall prey, due to their limited mobility, respiration, and size. The eukarya and small bacteria are apparent figures seen in the figure above, but archaea also contribute to the food cycle as they break down ammonia for plants to use. [35]
The notable interactions of life that take place in the soil environment is evident both below-ground level, as seen in the figure 1.1, but also in the above-ground level.[36] Worms also impact the soil food web, acting as both drivers of the food web both belowground and aboveground.[36]