Microbiology: Difference between revisions

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==Benefits of microbiology==
==Benefits of microbiology==
While microbes are often viewed negatively due to their association with many human illnesses, microbes are also responsible for many beneficial processes such as [[industrial fermentation]] (e.g. the production of [[alcohol]], [[vitamins]] and [[dairy products]]), [[antibiotic]] production and as standard laboratory tools for genetic manipulation of higher organisms such as plants. Scientists have also exploited their knowledge of microbes to produce biotechnologically important enzymes such as [[Taq polymerase]], [[reporter gene]]s for use in other genetic systems and novel molecular biology techniques such as the [[two-hybrid screening|yeast two-hybrid system]].
While microbes are often viewed negatively due to their association with many human illnesses, microbes are also responsible for many beneficial processes such as [[industrial fermentation]] (e.g. the production of [[alcohol]], [[vitamins]] and [[dairy products]]), [[antibiotic]] production and as standard laboratory tools for genetic manipulation of higher organisms such as plants. Scientists have exploited their knowledge of microbes to produce biotechnologically important enzymes such as [[Taq polymerase]], [[reporter gene]]s for use in other genetic systems and novel molecular biology techniques such as the [[two-hybrid screening|yeast two-hybrid system]].
<!--These traits allowed Joshua and Esther Lederberg to devise an elegant experiment in [[1951]] demonstrating that adaptive mutations arise from [[preadaptation]] rather than directed mutation. For this purpose, they invented [[replica plating]], which allowed them to transfer numerous [[colony (biology)|bacterial colonies]] from their specific locations on one agar-filled petri dish to analogous locations on several other petri dishes. After replicating a plate of ''E. coli'', they exposed each of the new plates to a [[bacteriophage]] (also called phage). They observed that phage-resistant colonies were present at analogous locations on each of the plates, allowing them to conclude that the phage resistance trait had existed in the original colony, which had never been exposed to phage, instead of arising after the bacteria had been exposed to the virus.  !-- This was on the page before I modified it to read more like a general description of the field of microbiology, but it just didn't seem to make sense with the rest of the page the way I wrote it. I didn't want to just throw it out, but I don't know what to do with it now! Any suggestions?  transfer to [[genetics]]-->
<!--These traits allowed Joshua and Esther Lederberg to devise an elegant experiment in [[1951]] demonstrating that adaptive mutations arise from [[preadaptation]] rather than directed mutation. For this purpose, they invented [[replica plating]], which allowed them to transfer numerous [[colony (biology)|bacterial colonies]] from their specific locations on one agar-filled petri dish to analogous locations on several other petri dishes. After replicating a plate of ''E. coli'', they exposed each of the new plates to a [[bacteriophage]] (also called phage). They observed that phage-resistant colonies were present at analogous locations on each of the plates, allowing them to conclude that the phage resistance trait had existed in the original colony, which had never been exposed to phage, instead of arising after the bacteria had been exposed to the virus.  !-- This was on the page before I modified it to read more like a general description of the field of microbiology, but it just didn't seem to make sense with the rest of the page the way I wrote it. I didn't want to just throw it out, but I don't know what to do with it now! Any suggestions?  transfer to [[genetics]]-->



Revision as of 05:16, 20 November 2006

An agar plate streaked with microorganisms

Microbiology is the study of microorganisms, which are unicellular or cell-cluster microscopic organisms. This includes eukaryotes (with a nucleus) such as fungi and protists, and prokaryotes (without a nucleus) such as bacteria and viruses (though viruses are not strictly classed as living organisms).

Although much is now known in the field of microbiology, advances are being made regularly. The most common estimates suggest that we have studied only about 1% of all of the microbes in any given environment. Thus, despite the fact that over three hundred years have passed since the discovery of microbes, the field of microbiology is clearly in its infancy relative to other biological disciplines such as zoology, botany or even entomology.

History

Bacteria were first observed by Anton van Leeuwenhoek in 1676 using a single-lens microscope of his own design. The name "bacterium" was introduced much later, by Ehrenberg in 1828, derived from the Greek word βακτηριον meaning "small stick". While Antony van Leeuwenhoek is often cited as the first microbiologist, the first recorded microbiological observation, that of the fruiting bodies of molds, was made earlier in 1665 by Robert Hooke.

The field of bacteriology (later a subdiscipline of microbiology) is generally considered to have been founded by Ferdinand Cohn (1828-1898), a botanist whose studies on algae and photosynthetic bacteria led him to describe several bacteria including Bacillus and Beggiatoa. Ferdinand Cohn was also the first to formulate a scheme for the taxonomic classification of bacteria.

Louis Pasteur (1822-1895) and Robert Koch (1843-1910) were contemporaries of Cohn’s and are often considered to be the founders of medical microbiology. Pasteur is most famous for his series of experiments designed to disprove the then widely held theory of spontaneous generation, thereby solidifying microbiology’s identity as a biological science. Pasteur also designed methods for food preservation (pasteurization) and vaccines against several diseases such as anthrax, fowl cholera and rabies. Robert Koch is best known for his contributions to the germ theory of disease, proving that specific diseases were caused by specific pathogenic microorganisms. He developed a series of criteria that have become known as the Koch's postulates. Koch was one of the first scientists to focus on the isolation of bacteria in pure culture resulting in his description of several novel bacteria including Mycobacterium tuberculosis, the causative agent of tuberculosis.

While Louis Pasteur and Robert Koch are often considered the founders of microbiology, their work did not accurately reflect the true diversity of the microbial world because of their exclusive focus on microorganisms having medical relevance. It was not until the work of Martinus Beijerinck (1851-1931) and Sergei Winogradsky (1856-1953), the founders of general microbiology (an older term encompassing aspects of microbial physiology, diversity and ecology), that the true breadth of microbiology was revealed. Martinus Beijerinck made two major contributions to microbiology: the discovery of viruses and the development of enrichment culture techniques. While his work on the Tobacco Mosaic Virus established the basic principles of virology, it was his development of enrichment culturing that had the most immediate impact on microbiology by allowing for the cultivation of a wide range of microbes with wildly different physiologies. Sergei Winogradsky was the first to develop the concept of chemolithotrophy and to thereby reveal the essential role played by microorganisms in geochemical processes. He was responsible for the first isolation and description of both nitrifying and nitrogen-fixing bacteria.

Types of microbiology

The field of microbiology can be generally divided into several subdisciplines:

  • Microbial physiology: The study of how the microbial cell functions biochemically. Includes the study of microbial growth, microbial metabolism and microbial cell structure.
  • Microbial genetics: The study of how genes are organised and regulated in microbes in relation to their cellular functions. Closely related to the field of molecular biology.
  • Medical microbiology: The study of the role of microbes in human illness. Includes the study of microbial pathogenesis and epidemiology and is related to the study of disease pathology and immunology.
  • Veterinary microbiology: The study of the role in microbes in veterinary medicine.
  • Environmental microbiology: The study of the function and diversity of microbes in their natural environments. Includes the study of microbial ecology, microbially-mediated nutrient cycling, geomicrobiology, microbial diversity and bioremediation. Characterisation of key bacterial habitats such as the rhizosphere and phyllosphere.
  • Evolutionary microbiology: The study of the evolution of microbes. Includes the study of bacterial systematics and taxonomy.
  • Industrial microbiology: The exploitation of microbes for use in industrial processes. Examples include industrial fermentation and wastewater treatment. Closely linked to the biotechnology industry. This field also includes brewing, an important application of microbiology.
  • Aeromicrobiology: The study of Airborne Microorganisms.
  • Food Microbiology: The study of Microorganisms causing Food Spoilage.
Fermenting tanks with yeast being used to brew beer

Benefits of microbiology

While microbes are often viewed negatively due to their association with many human illnesses, microbes are also responsible for many beneficial processes such as industrial fermentation (e.g. the production of alcohol, vitamins and dairy products), antibiotic production and as standard laboratory tools for genetic manipulation of higher organisms such as plants. Scientists have exploited their knowledge of microbes to produce biotechnologically important enzymes such as Taq polymerase, reporter genes for use in other genetic systems and novel molecular biology techniques such as the yeast two-hybrid system.

References

  • Madigan, Michael; Martinko, John (editors) (2005). Brock Biology of Microorganisms, 11th ed.. Prentice Hall. ISBN 0-13-144329-1. 
  • Ryan KJ; Ray CG (editors) (2004). Sherris Medical Microbiology, 4th ed.. McGraw Hill. ISBN 0-8385-8529-9. 
  • Schaechter, Moselio; Ingraham, John L.; Neidhardt (2006). Microbe, 1st ed.. ASM Press. ISBN 1-55581-320-8. 

See also

External links

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