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Microbiology

Microbiology is the scientific study of microorganisms, those being of
unicellular, multicellular, or acellular. Microbiology encompasses numerous
sub-disciplines including virology, bacteriology, protistology, mycology,
immunology, and parasitology.

Study of microorganisms, or microbes, a diverse group of generally minute
simple life-forms that include bacteria, archaea, algae, fungi, protozoa, and
viruses. The field is concerned with the structure, function, and classification
of such organisms and with ways of both exploiting and controlling their
activities.

The 17th-century discovery of living forms existing invisible to the naked eye
was a significant milestone in the history of science, for from the 13th century
onward it had been postulated that "invisible" entities were responsible for
decay and disease. The word microbe was coined in the last quarter of the
19th century to describe these organisms, all of which were thought to be
related. As microbiology eventually developed into a specialized science, it
was found that microbes are a very large group of extremely diverse
organisms.

Daily life is interwoven inextricably with microorganisms. In addition to
populating both the inner and outer surfaces of the human body, microbes
abound in the soil, in the seas, and in the air. Abundant, although usually
unnoticed, microorganisms provide ample evidence of their presence
sometimes unfavourably, as when they cause decay of materials or spread
diseases, and sometimes favourably, as when they ferment sugar to wine and
beer, cause bread to rise, flavour cheeses, and produce valued products such
as antibiotics and insulin. Microorganisms are of incalculable value to Earth's
ecology, disintegrating animal and plant remains and converting them to
simpler substances that can be recycled in other organisms.

Importance of Microbiology in Everyday Life

1. Importance of Microbiology in Food Industry:
Microorganisms involved in food microbiology include bacteria molds and
yeasts.
Bacteria mainly cause food intoxication and food spoilage thereby causing
various human gut health diseases.
Several bacterial strains are used to produce a wide range of food and dairy
products.
These bacterial strains include Streptococcus thermophiles, Bifidobacterium
sp, and Lactobacillus bulgaricus.
Lactic acid bacteria help in producing yogurt cheese, hot sauce, pickles,
fermented sausages, and kimchi.
Molds are used to manufacture various food and food products. They help in
ripening several types of food. Molds also help in producing enzymes and
citric acid used in making bread and soft drinks respectively.
Yeasts are used in the food industry as they ferment sugar into ethanol and
carbon dioxide.
A yeast, Saccharomyces cerevisiae is used to make bread, brew beer, and
make wine.
Nisin is an antimicrobial agent derived from bacteria. It is used in cheese,
meats, and beverages to preserve them by inhibiting the growth of
detrimental microorganisms.

2. Importance of Microbiology in Medical Science.
Microorganisms can cause both benefit and harm to our human and animal
cells. These microorganisms include virus, bacteria, fungus, and parasites.
Medical Microbiology is important for several reasons.
Through the knowledge of medical microbiology, microbiologists can identify,
isolate, diagnose, prevent pathogenic microorganisms. They also can engineer
beneficial microorganisms to produce antimicrobial drugs.
The knowledge of microbiology helps microbiologists to innovate new
methods to combat diseases.
Fluorescent fusion is a good example of medical microbiology, that helps in
the rapid detection of pathogens in the tissue sample.

3. Importance of Microbiology in the pharmaceutical industry.
The discovery of antibiotics is one of the most important contributions of
microbiology in the pharmaceutical industry. Antibiotics are the metabolic
byproduct of microorganisms.
The vaccine is also another important discovery of microbiology. The vaccine
helps thousands of people by producing antibodies against the virus. Thus it
prevents viral infection. For example, the Polio vaccine helps eradicate polio
in many countries.
Phage therapy has also attracted great attention due to its killing potential
against
bacteria.
Steroids are also another pharmaceutical product produced by
microorganisms.
Prevention of microbial contamination of drugs, injectable, eye drops, nasal
solutions, and inhalation products are also another important discoveries of
microbiology.
One of the great examples of medical microbiology is the discovery of Insulin.
Insulin is used for the treatment of diabetic patients. Insulin was derived from
the ß cell of pancreases. But it was not sufficient to satisfy the massive-
demand for insulin.
Recombinant DNA technology uses E. coli to produce a higher amount of
insulin to control sugar concentration in diabetes patients.

4. Importance of Microbiology in nursing
The knowledge of microbiology in nursing is very important to control and
prevent infection in the hospital. The knowledge of microbiology for the
nurses and other health professionals in healthcare is very important because
it gives them much information about health and hygiene.
Through the knowledge of microbiology, the nurses and other health
professionals in healthcare can learn, how infections spread and how to
carefully cure or surgery an open wound without infecting it.
The knowledge of microbiology teaches them to keep the instruments aseptic
and contaminant-free. It helps them find and identify the symptoms of an
infection and type of infection at its early stage.
It also teaches them the nature of the organism and the factors affecting its
growth, the most susceptible means of disease transmission and the
composition of chemicals, drugs, aseptic solutions, etc.

5. Importance of Microbiology in Biotechnology
Microorganisms are used in various fields of biotechnology. In the
fermentation industry, microbes are used to produce ethanol, organic acids,
vinegar, and fermented foods by degrading complex organic matters.
Microbes (e. g. virus) are used as a source of molecular vectors such as a
plasmid, phagemid, and cosmid in molecular biology and recombinant DNA
technology.
Microbes are used in bioremediation that removes organic compounds and
hydrocarbon from sewage water by degrading these organic wastes.
By using microorganisms, microbiologists extract metals or heavy metals
from their ore through a process called bioleaching and biomining.
Microorganisms also produce enzymes, vitamins, organic acids, antibiotics,
amino acids, and polysaccharides as their metabolic products for industrial
purposes.

6. Importance of Microbiology in Chemical products
Several industrial chemical products are produced through the use of
microorganisms.
These products include acetaldehyde, acetic acid, acetoacetic acid, butanol,
ethanol, fructose, galactose, glycerol, lactic acid, mannitol, mannose, pyruvic
acid, sorbose, succinic acid.
The microorganism that produces these products include Acetic acid bacteria,
lactic acid bacteria, propionic acid bacteria, butyric acid bacteria, E. coli,
Aerobacter aerogenes.

7. Importance of Microbiology in fuel:
Biofuel can be obtained from extracted microalgae oil, biomethane by
anaerobic digestion of
Microalgae biomass, ethanol by fermentation of carbohydrate.
Biodiesel
Microalgae are a potential source of oil content for biodiesel production. They
also contain a higher amount of lipids that serve as raw material for biodiesel
production.

Butanol and ethanol
Microalgae contain a large amount of cellulose, starch, mannitol, agar and
laminarin that are fermented to alcohol (ethanol and butanol). This microalga
includes Chlorella, Chlamydomonas, Dunaliella, Scenedesmus, and Spirulina.

8. Importance of Microbiology in aquaculture/fisheries:
Heterotrophic microorganisms play an important role in decomposing organic
matter and cycling of nutrients in aquatic systems. In the aquatic system,
microbes are placed at the bottom of the food chain.
Microorganisms also play various important roles in aquaculture as they grow
naturally in the aquatic environment.
Microorganisms may
1. Protect fish and larvae from various microbial infections.
2. Improve the overall quality of water.
 3. Control the development of microbial and insect-infected diseases.
4. Suppress the growth of harmful bacteria and enhance larval survival,
minimizing the need to apply antibiotics.

9. Importance of Microbiology in Agriculture:
Microorganisms help in decomposing toxic compounds in agricultural soil
preventing toxic accumulation in the soil. Thus it helps in increasing the
fertility of the soil.
Microorganisms (e.g. Blue-green algae) play an important role in nitrogen
fixation.
Fungi like Mycorrhiza help the plant absorb minerals and water from the soil
and protect its roots from other fungi and nematodes.
Actinomycetes (Nocardia and Monospora) and Molds (Mucor and Aspergillus)
increase the fertility of the soil by decomposing its organic matter.
Other soil bacteria help in nitrification, nitrification, mineralization and sulfur
oxidation, etc.
Soil bacteria produce Humus that helps in retaining soil moisture and
enhances the formation of soil structure.
Soil bacteria support plant growth by producing several substances like
auxins, gibberellins, and antibiotics.
Soil bacteria also help in controlling pest and microbial disease. A best-known
soil bacterium Bacillus thuringienis have the ability to control caterpillar pests
of plants.

10. Importance of Microbiology in Environmental Science/ Sewage System:
Environmental Microbiology is the study of microorganisms that lives in air,
soil, water.
Microorganisms degrade toxic pollutants from the environment. For example,
Acinetobacter can degrade a wide range of aromatic compounds.
Bacteria help us clean water through sewage treatment. Bacteria degrade the
organic matter in sewage removing the pollution from water.
Nitrification and phosphorous removal are occurred by bacteria in the sewage
system.
In this system, Nitrosomonas spp oxidize ammonium to nitrite and
Nitrobacter spp oxidize nitrite to nitrate. Denitrifying bacteria (Pseudomonas)
reduce nitrate into nitrogen gas using the chemical energy in organic matter
to reduce.
Aerobic bacteria also ferment solid components of the sewage.

Historical background

Microbiology essentially began with the development of the microscope.
Although others may have seen microbes before him, it was Antonie van
Leeuwenhoek, a Dutch draper whose hobby was lens grinding and making
microscopes, who was the first to provide proper documentation of his
observations. His descriptions and drawings included protozoans from the
guts of animals and bacteria from teeth scrapings. His records were excellent
because he produced magnifying lenses of exceptional quality.
Leeuwenhoek conveyed his findings in a series of letters to the British Royal
Society during the mid-1670s. Although his observations stimulated much
interest, no one made a serious attempt either to repeat or to extend them.
Leeuwenhoek's
"animalcules," as he called them, thus remained mere oddities of nature to the
scientists of his day, and enthusiasm for the study of microbes grew slowly. It
was only later, during the 18th-century revival of a long-standing controversy
about whether life could develop out of nonliving material, that the
significance of microorganisms in the scheme of nature and in the health and
welfare of humans became evident.

Spontaneous generation versus biotic
generation of life

The early Greeks believed that living things could originate from nonliving
matter (abiogenesis) and that the goddess Gea could create life from stones.
Aristotle discarded this notion, but he still held that animals could arise
spontaneously from dissimilar organisms or from soil. His influence regarding
this concept of spontaneous generation was still felt as late as the 17th
century, but toward the end of that century a chain of observations,
experiments, and arguments began that eventually refuted the idea. This
advance in understanding was hard fought, involving series of events, with
forces of personality and individual will often obscuring the facts.
Although Francesco Redi, an Italian physician, disproved in 1668 that higher
forms of life could originate spontaneously, proponents of the concept claimed
that microbes were different and did indeed arise in this way. Such illustrious
names as John Needham and Lazzaro Spallanzani were adversaries in this
debate during the mid-1700s. In the early half of the 1800s, Franz Schulze and
Theodor Schwann were major figures in the attempt to disprove theories of
abiogenesis until Louis Pasteur finally announced the results of his conclusive
experiments in 1864. In a series of masterful experiments, Pasteur proved
that only preexisting microbes could give rise to other microbes (biogenesis).
Modern and accurate knowledge of the forms of bacteria can be attributed to
German botanist Ferdinand Cohn, whose chief results were published
between 1853 and 1892. Cohn's classification of bacteria, published in 1872
and extended in 1875, dominated the study of these organisms thereafter.

Microbes and disease

Girolamo Fracastoro, an Italian scholar, advanced the notion as early as the
mid-1500s that contagion is an infection that passes from one thing to
another. A description of precisely what is passed along eluded discovery until
the late 1800s, when the work of many scientists, Pasteur foremost among
them, determined the role of bacteria in fermentation and disease. Robert
Koch, a German physician, defined the procedure (Koch's postulates) for
proving that a specific organism causes a specific disease.
The foundation of microbiology was securely laid during the period from
about 1880 to
1900. Students of Pasteur, Koch, and others discovered in rapid succession a
host of bacteria capable of causing specific diseases (pathogens). They also
elaborated an extensive arsenal of techniques and laboratory procedures for
revealing the ubiquity, diversity, and abilities of microbes.

Progress in the 20th Century
All of these developments occurred in Europe. Not until the early 1900s did
microbiology become established in America. Many microbiologists who
worked in America at this time had studied either under Koch or at the
Pasteur Institute in Paris.
Once established in America, microbiology flourished, especially with regard
to such related disciplines as biochemistry and genetics. In 1923 American
bacteriologist David
onercan Bacerbgs Davd
Bergey established that science's primary reference, updated editions of
which continue to be used today.
Since the 1940s microbiology has experienced an extremely productive
period during which many disease-causing microbes have been identified and
methods to control them developed. Microorganisms have also been
effectively utilized in industry; their activities have been channeled to the
extent that valuable products are now both vital and commonplace.
The study of microorganisms has also advanced the knowledge of all living
things.
Microbes are easy to work with and thus provide a simple vehicle for studying
the complex processes of life; as such they have become a powerful tool for
studies in genetics and metabolism at the molecular level. This intensive
probing into the functions of microbes has resulted in numerous and often
unexpected dividends.
Knowledge of the basic metabolism and nutritional requirements of a
pathogen, for example, often leads to a means of controlling disease or
infection.

Types of microorganisms

The major groups of microorganisms-namely bacteria, archaea, fungi (yeasts
and molds), algae, protozoa, and viruses-are summarized below.
Bacteria (eubacteria and archaea)
Microbiology came into being largely through studies of bacteria. The
experiments of Louis Pasteur in France, Robert Koch in Germany, and others
in the late 1800s established the importance of microbes to humans. As stated
in the Historical background section, the research of these scientists provided
proof for the germ theory of disease and the germ theory of fermentation. It
was in their laboratories that techniques were devised for the microscopic
examination of
specimens, culturing (growing) microbes in the laboratory, isolating pure
cultures from mixed-culture populations, and many other laboratory
manipulations. These techniques, originally used for studying bacteria, have
been modified for the study of all microorganisms—hence the transition from
bacteriology to microbiology.
The organisms that constitute the microbial world are characterized as either
prokaryotes or eukaryotes; all bacteria are prokaryotic-that is, single-celled
organisms without a membrane-bound nucleus. Their DNA (the genetic
material of the cell), instead of being contained in the nucleus, exists as a long,
folded thread with no specific location within the cell.
Until the late 1970s it was generally accepted that all bacteria are closely
related in evolutionary development. This concept was challenged in 1977 by
Carl R. Woese and coinvestigators at the University of Illinois, whose research
on ribosomal RNA from a broad spectrum of living organisms established that
two groups of bacteria evolved by separate pathways from a common and
ancient ancestral form. This discovery resulted in the establishment of a new
terminology to identify the major distinct groups of microbes-namely, the
eubacteria (the traditional or "true" bacteria), the archaea (bacteria that
diverged from other bacteria at an early stage of evolution and are distinct
from the eubacteria), and the eukarya (the eukaryotes).
Today the eubacteria are known simply as the true bacteria (or the bacteria)
and form the domain Bacteria. The evolutionary relationships between
various members of these three groups, however, have become uncertain, as
comparisons between the DNA sequences of various microbes have revealed
many puzzling similarities. As a result, the precise ancestry of today's
microbes is very difficult to resolve. Even traits thought to be characteristic of
distinct taxonomic groups have unexpectedly been observed in other
microbes. For example, an anaerobic ammonia-oxidizer—the "missing link" in
the global nitrogen cycle was isolated for the first time in 1999. This
bacterium (an aberrant member of the order Planctomycetales) was found to
have internal structures similar to eukaryotes, a cell wall with archaean traits,
and a form of reproduction (budding) similar to that of yeast cells.

Bacterial Cell

Bacteria have a variety of shapes, including spheres, rods, and spirals.
Individual cells generally range in width from 0.5 to 5 micrometres (um;
millionths of a metre). Although unicellular, bacteria often appear in pairs,
chains, tetrads (groups of four), or clusters.
Some have flagella, external whiplike structures that propel the organism
through liquid media; some have capsule, an exteral coating of the cell; some
produce spores— reproductive bodies that function much as seeds do among
plants. One of the major characteristics of bacteria is their reaction to the
Gram stain. Depending upon the chemical and structural composition of the
cell wall, some bacteria are gram-positive, taking on the stain's purple colour,
whereas others are gram-negative.
Through a microscope the archaea look much like bacteria, but there are
important differences in their chemical composition, biochemical activities,
and environments. The cell walls of all true bacteria contain the chemical
substance peptidoglycan, whereas the cell walls of archaeans lack this
substance. Many archaeans are noted for their ability to survive unusually
harsh surroundings, such as high levels of salt or acid or high temperatures.
These microbes, called extremophiles, live in such places as salt flats, thermal
pools, and deep-sea vents. Some are capable of a unique chemical activity—
the production of methane gas from carbon dioxide and hydrogen. Methane-
producing archaea live only in environments with no oxygen, such as swamp
mud or the intestines of ruminants such as cattle and sheep. Collectively, this
group of microorganisms exhibits tremendous diversity in the chemical
changes that it brings to its environments.

Algae

The cells of eukaryotic microbes are similar to plant and animal cells in that
their DNA is enclosed within a nuclear membrane, forming the nucleus.
Eukaryotic microorganisms include algae, protozoa, and fungi. Collectively
algae, protozoa, and some lower fungi are frequently referred to as protists
(kingdom Protista, also called Protoctista); some are unicellular and others
are multicellular.

representative algae
Unlike bacteria, algae are eukaryotes and, like plants, contain the green
pigment chlorophyll, carry out photosynthesis, and have rigid cell walls. They
normally occur in moist soil and aquatic environments. These eukaryotes may
be unicellular and microscopic in size or multicellular and up to 120 metres
(nearly 400 feet) in length.
Algae as a group also exhibit a variety of shapes. Single-celled species may be
spherical, rod-shaped, club-shaped, or spindle-shaped. Some are motile. Algae
that are multicellular appear in a variety of forms and degrees of complexity.
Some are organized as filaments of cells attached end to end; in some species
these filaments intertwine into macroscopic, plantlike bodies. Algae also occur
in colonies, some of which are simple aggregations of single cells, while others
contain different cell types with special functions.

Fungi

Fungi are eukaryotic organisms that, like algae, have rigid cell walls and may
be either unicellular or multicellular. Some may be microscopic in size, while
others form much larger structures, such as mushrooms and bracket fungi
that grow in soil or on damp logs. Unlike algae, fungi do not contain
chlorophyll and thus cannot carry out photosynthesis. Fungi do not ingest
food but must absorb dissolved nutrients from the environment. Of the fungi
classified as microorganisms, those that are multicellular and produce
filamentous, microscopic structures are frequently called molds, whereas
yeasts are unicellular fungi.
In molds cells are cylindrical in shape and are attached end to end to form
threadlike filaments (hyphae) that may bear spores. Individually, hyphae are
microscopic in size.
However, when large numbers of hyphae accumulate for example, on a slice of
bread or fruit jelly-they form a fuzzy mass called a mycelium that is visible to
the naked eye.
The unicellular yeasts have many forms, from spherical to egg-shaped to
filamentous.
Yeasts are noted for their ability to ferment carbohydrates, producing alcohol
and carbon dioxide in products such as wine and bread.

Protozoa

representative protozoans
Protozoa, or protozoans, are single-celled, eukaryotic microorganisms. Some
protozoa are oval or spherical, others elongated. Still others have different
shapes at different stages of the life cycle. Cells can be as small as 1 um in
diameter and as large as 2,000 um, or 2 mm (visible without magnification).
Like animal cells, protozoa lack cell walls, are able to move at some stage of
their life cycle, and ingest particles of food; however, some phytoflagellate
protozoa are plantlike, obtaining their energy via photosynthesis.
Protozoan cells contain the typical internal structures of an animal cell. Some
can swim through water by the beating action of short, hairlike appendages
(cilia) or flagella. Their rapid, darting movement in a drop of pond water is
evident when viewed through a microscope.

amoeba

The amoebas (also amoebae) do not swim, but they can creep along surfaces
by extending a portion of themselves as a pseudopod and then allowing the
rest of the cell to flow into this extension. This form of locomotion is called
amoeboid movement. The sporozoans (phylum Apicomplexa) are so named
because they form dormant bodies called spores during one phase of their life
cycle. Protozoa occur widely in nature, particularly in aquatic environments.

Viruses

tobacco mosaic virus
Viruses, agents considered on the borderline of living organisms, are also
included in the science of microbiology, come in several shapes, and are
widely distributed in nature, infecting animal cells, plant cells, and
microorganisms. The field of study in which they are investigated is called
virology. All viruses are obligate parasites; that is, they lack metabolic
machinery of their own to generate energy or to synthesize proteins, so they
depend on host cells to carry out these vital functions. Once inside a cell,
viruses have genes for usurping the cell's energy-generating and protein-
synthesizing systems. In addition to their intracellular form, viruses have an
extracellular form that carries the viral nucleic acid from one host cell to
another. In this infectious form, viruses are simply a central core of nucleic
acid surrounded by a protein coat called a capsid.
The capsid protects the genes outside the host cell; it also serves as a vehicle
for entry into another host cell because it binds to receptors on cell surfaces.
The structurally mature, infectious viral particle is called a virion.
With the electron microscope it is possible to determine the morphological
characteristics of viruses. Virions generally range in size from 20 to 300
nanometres (nm; billionths of a metre). Since most viruses measure less than
150 mm, they are beyond the limit of resolution of the light microscope and
are visible only by electron microscopy. By using materials of known size for
comparison, microscopists can determine the size and structure of individual
virions.

Prions

Even smaller than viruses, prions (pronounced "pree-ons") are the simplest
infectious agents. Like viruses they are obligate parasites, but they possess no
genetic material.
Although prions are merely self-perpetuating proteins, they have been
implicated as the cause of various diseases, including bovine spongiform
encephalopathy (mad cow disease), and are suspected of playing a role in a
number of other disorders.

Lichens

crustose lichens
Lichens represent a form of symbiosis, namely, an association of two different
organisms wherein each benefits. A lichen consists of a photosynthetic
microbe (an alga or a cyanobacterium) growing in an intimate association
with a fungus. A simple lichen is made up of a top layer consisting of a tightly
woven fungal mycelium, a middle layer where the photosynthetic microbe
lives, and a bottom layer of mycelium. In this mutualistic association, the
photosynthetic microbes synthesize nutrients for the fungus, and in return the
fungus provides protective cover for the algae or cyanobacteria. Lichens play
an important role ecologically; among other activities they are capable of
transforming rock to soil.

Slime molds

The slime molds are a biological and taxonomic enigma because they are
neither typical fungi nor typical protozoa. During one of their growth stages,
they are protozoa-like because they lack cell walls, have amoeboid movement,
and ingest particulate nutrients. During their propagative stage they form
fruiting bodies and sporangia, which bear walled spores like typical fungi.
Traditionally, the slime molds have been classified with the fungi. There are
two groups of slime molds: the cellular slime molds and the acellular slime
molds.

The study of microorganisms

As is the case in many sciences, the study of microorganisms can be divided
into two generalized and sometimes overlapping categories. Whereas basic
microbiology addresses questions regarding the biology of microorganisms,
applied microbiology refers to the use of microorganisms to accomplish
specific objectives.

Basic microbiology

The study of the biology of microorganisms requires the use of many different
procedures as well as special equipment. The biological characteristics of
microorganisms can be summarized under the following categories:
morphology, nutrition, physiology, reproduction and growth, metabolism,
pathogenesis, antigenicity, and genetic properties.

Morphology

Morphology refers to the size, shape, and arrangement of cells. The
observation of microbial cells requires not only the use of microscopes but
also the preparation of the cells in a manner appropriate for the particular
kind of microscopy. During the first decades of the 20th century, the
compound light microscope was the instrument commonly used in
microbiology. Light microscopes have a usual magnification factor of 1000 x
and a maximum useful magnification of approximately 2000 x. Specimens can
be observed either after they have been stained by one of several techniques
to highlight some morphological characteristics or in living, unstained
preparations as a
"wet mount."
Light microscopy

Several modifications of light microscopy are available, such as:
bright field
The specimen is usually stained and observed while illuminated; useful
for observation of the gross morphological features of bacteria, fungi,
algae, and protozoa.
dark field
The specimen is suspended in a liquid on a special slide and can be
observed in a living condition; useful for determining motility of
microorganisms or some special morphological characteristic such as
spiral or coiled shapes.
fluorescence
The specimen is stained with a fluorescent dye and then illuminated;
objects that take up the fluorescent dye will "glow."
phase contrast
Special condenser lenses allow observation of living cells and
differentiation of cellular structures of varying density.

Electron microscopy

The development of the electron microscope and complimentary techniques
vastly increased the resolving power beyond that attainable with light
microscopy. This increase is possible because the wavelengths of the electron
beams are so much shorter than the wavelengths of light. Objects as small as
0.02 m are resolvable by electron microscopy, compared with 0.25 um-
allowing, for instance, the observation of virions and viral structures.
Specimens are observed by either transmission electron microscopy or
scanning electron microscopy. In TEM the electron beam passes through the
specimen and registers on a screen forming the image; in SEM the electron
beam moves back and forth over the surface of microorganisms coated with a
thin film of metal and registers a three-dimensional picture on the screen.
Advances in microscopes and microscopic techniques continue to be
introduced to study cells, molecules, and even atoms. Among these are
confocal microscopy, the atomic force microscope, the scanning tunneling
microscope, and immunoelectron microscopy. These are particularly
significant for studies of microorganisms at the molecular level.

Nutritional and physiological characteristics

Microorganisms as a group exhibit great diversity in their nutritional
requirements and in the environmental conditions that will support their
growth. No other group of living organisms comes close to matching the
versatility and diversity of microbes in this respect. Some species will grow in
a solution composed only of inorganic salts (one of the salts must be a
compound of nitrogen) and a source of carbon dioxide (COz); these are called
autotrophs. Many, but not all, of these microbes are autotrophic via
photosynthesis. Organisms requiring any other carbon source are called
heterotrophs.
These microbes commonly make use of carbohydrates, lipids, and proteins,
although many microbes can metabolize other organic compounds such as
hydrocarbons.
Others, particularly the fungi, are decomposers. Many species of bacteria also
require specific additional nutrients such as minerals, amino acids, and
vitamins. Various protozoans, fungi, and bacteria are parasites, either
exclusively (obligate parasites) or with the ability to live independently
(facultative parasites).
If the nutritional requirements of a microorganism are known, a chemically
defined medium containing only those chemicals can be prepared. More
complex media are also routinely used; these generally consist of peptone (a
partially digested protein), meat extract, and sometimes yeast extract. When a
solid medium is desired, agar is added to the above ingredients. Agar is a
complex polysaccharide extracted from marine algae. It has several properties
that make it an ideal solidifying substance for microbiological media,
particularly its resistance to microbial degradation.

Microorganisms vary widely in terms of the physical conditions required for
growth. For example, some are aerobes (require oxygen), some are anaerobes
(grow only in the absence of oxygen), and some are facultative (they grow in
either condition). Eukaryotic microbes are generally aerobic. Microorganisms
that grow at temperatures below 20 °C (68 °F) are called psychrophiles; those
that grow best at 20-40 °C (68-104 °F) are called mesophiles; a third group,
the thermophiles, require temperatures above 40 °C.
Those organisms which grow under optimally under one or more physical or
chemical extremes, such as temperature, pressure, pH, or salinity, are referred
to as extremophiles. Bacteria exhibit the widest range of temperature
requirements.
Whereas bacterial (and fungal) growth is commonly observed in food that has
been refrigerated for a long period, some isolated archaea (e.g., Pyrodictium
occultum and Pyrococcus woesel) grow at temperatures above 100 °C (212
°F).
Other physical conditions that affect the growth of microorganisms are acidity
or basicity (pH), osmotic pressure, and hydrostatic pressure. The optimal pH
for most bacteria associated with the human environment is in the neutral
range near pH 7, though other species grow under extremely basic or acidic
conditions. Most fungi are favoured by a slightly lower pH (5-6); protozoa
require a range of pH 6.7-7.7; algae are similar to bacteria in their
requirements except for the fact that they are photosynthetic.

Reproduction and growth

Bacteria reproduce primarily by binary fission, an asexual process whereby a
single cell divides into two. Under ideal conditions some bacterial species may
divide every 10-15 minutes-a doubling of the population at these time
intervals. Eukaryotic microorganisms reproduce by a variety of processes,
both asexual and sexual. Some require multiple hosts or carriers (vectors) to
complete their life cycles. Viruses, on the other hand, are produced by the host
cell that they infect but are not capable of self-reproduction.
The study of the growth and reproduction of microorganisms requires
techniques for cultivating them in pure culture in the laboratory. Data
collected on the microbial population over a period of time, under controlled
laboratory conditions, allow a characteristic growth curve to be constructed
for a species.
Metabolism

Collectively, microorganisms show remarkable diversity in their ability to
produce complex substances from simple chemicals and to decompose
complex materials to simple chemicals. An example of their synthetic ability is
nitrogen fixation-the production of amino acids, proteins, and other organic
nitrogen compounds from atmospheric nitrogen (N2). Certain bacteria and
blue-green algae (cyanobacteria) are the only organisms capable of this
ecologically vital process. An example of microbes' ability to decompose
complex materials is shown by the white and brown rot fungi that decompose
wood to simple compounds, including COz.
Laboratory procedures are available that make it possible to determine the
biochemical capability of a species qualitatively and quantitatively. Routine
techniques can identify which compounds or substances are degraded by a
specific microbe and which products are synthesized. Through more elaborate
experimentation it is possible to determine step-by-step how the microbe
performs these biochemical changes. Studies can be performed in a number of
ways using growing cultures, "resting cells" (suspensions of cells), cell-free
extracts, or enzyme preparations from cells.
Certain biochemical tests are routinely used to identify microbes-though more
in the case of bacteria than algae, fungi, or protozoa. The adoption of routine
sets of laboratory tests has allowed automated instrumentation to perform
the tests. For instance, technicians often simply inoculate individual units of a
"chamber" that is preloaded with a specific chemical substance (the substrate)
and then place the chamber into an apparatus that serves as an incubator and
analyzer. The apparatus automatically records the results and is frequently
capable of calculating the degree of accuracy of the identification.

Pathogenesis

Some microorganisms cause diseases of humans, other animals, and plants.
Such microbes are called pathogens. Pathogens are identified by the hosts
they infect and the symptoms they cause; it is also important to identify the
specific properties of the pathogen that contribute to its infectious capacity—
a characteristic known as virulence.
The more virulent a pathogen, the fewer the number needed to establish an
infection.

Antigenic characteristics

An antigen is a substance that, when introduced into an animal body,
stimulates the production of specific substances (antibodies) that react or
unite with the antigen.
Microbial cells and viruses contain a variety of antigenic substances. A
significant feature of antigen-antibody reactions is specificity; the antibodies
formed as a result of inoculating an animal with one microbe will not react
with the antibodies formed by inoculation with a different microbe.
Antibodies appear in the blood serum of animals, and laboratory tests of
antigen-antibody reactions are performed by using sera-hence the term
serological reactions. Thus, it is possible to characterize a microorganism by
its antigenic makeup as well as to identify microorganisms by using one of
many different serological tests. Antigens and antibodies are important
aspects of immunity, and immunology is included in the science of
microbiology.

Genetic characterization

Since the last quarter of the 20th century, researchers have accumulated a
vast amount of information elucidating in precise detail the chemical
composition, synthesis, and replication of the genetic material of cells. Much of
this research has been done by using microorganisms, and techniques have
been developed that permit experimentation at the molecular level. For
instance, experiments determining the degree of similarity between different
organisms' DNA and RNA have provided new insights for the classification of
microorganisms. Test kits are available for the identification of
microorganisms, particularly bacteria, by DNA probes.
Since the invention of recombinant DNA technology in 1973, techniques have
been developed whereby genes from one cell can be transferred to an entirely
different cell, as when a gene is transferred from an animal cell to a bacterium
or from a bacterium to a plant cell. Recombinant DNA technology opened the
door to many new medical and industrial applications of microbiology, and it
plays a central role in genetic engineering.

Applied microbiology

Genetic engineering is an example of how the fields of basic and applied
microbiology can overlap. Genetic engineering is primarily considered a field
of applied microbiology (that is, the exploitation of microorganisms for a
specific product or use). The methods used in genetic engineering were
developed in basic research of microbial genetics. Conversely, methods used
and perfected for applied microbiology can become tools for basic
microbiology. Applied microbiology can, however, be divided under the
following headings.

Soil microbiology

However "dead" soil may appear, it is in fact teeming with millions or billions
of microbial cells per gram, depending upon soil fertility and the environment.
Dead vegetation, human and animal wastes, and dead animals are deposited
in or on soil. In time they all decompose into substances that contribute to
soil, and microbes are largely responsible for these transformations.
Two great pioneer soil microbiologists were Martinus W. Beijerinck (1851-
1931), a Dutchman, and Sergey N. Winogradsky (1856-1953), a Russian.
These researchers isolated and identified new types of bacteria from soil,
particularly autotrophic bacteria, that use inorganic chemicals as nutrients
and as a source of energy. The relationship between legumes and bacteria in
the nodules of legume roots was discovered by other scientists in 1888. The
nodules contain large numbers of bacteria (Rhizobium) that are capable of
fixing atmospheric nitrogen into compounds that can be used by plants.

The ecology of fertile soil consists of plant roots, animals such as rodents,
insects, and worms, and a menagerie of microorganisms-viruses, bacteria,
algae, fungi, and protozoa. The role of this microbial flora can be conveniently
expressed in Earth's natural cycles. In the nitrogen cycle, for example,
microorganisms capture nitrogen gas from the atmosphere and convert it into
a combined form of nitrogen that plants can use as a nutrient; the plant
synthesizes organic nitrogen compounds that are consumed by humans and
animals; the consumed nitrogen compounds eventually reach the soil;
microorganisms complete the cycle by decomposing these compounds back to
atmospheric nitrogen and simple inorganic molecules that can be used by
plants. In similar cycles for other elements such as carbon, sulfur, and
phosphorus, microbes play a role; this makes them essential to maintaining
life on Earth.

Microbiology of water supplies, wastewater, and other aquatic environments

Long before the establishment of microbiology as a science, water was
suspected of being a carrier of disease-producing organisms. But it was not
until 1854, when an epidemic of cholera was proved to have had its origin in
polluted water, that contaminated water was considered more seriously as a
source of disease. Since that time there has been continuous research on the
microbiology of public water supplies, including the development of
laboratory procedures to determine whether the water is potable, or safe for
human consumption. At the same time, purification procedures for these
supplies have emerged.
A highly standardized and routine laboratory procedure to determine the
potability of water is based upon detecting the presence or absence of the
bacterium Escherichia coli. E. coli is a normal inhabitant of the intestinal tract
of humans; its presence in water indicates that the water is polluted with
intestinal wastes and may contain disease-producing organisms.
The principal operations employed in a municipal water-purification plant are
sedimentation, filtration, and chlorination. Each of these operations removes
or kills microorganisms, and the microbiological quality of the treated water is
monitored at frequent intervals.
The used water supply of a community, commonly referred to as sewage, is
microbiologically significant in two ways. First, sewage is a potential carrier of
pathogenic microorganisms, so measures such as chlorination must be
implemented to prevent these microbes from contaminating drinking-water
supplies. Second, sewage-treatment plants purify water by exploiting the
biochemical abilities of microbes to metabolize contaminants. Raw sewage is
processed through large tanks, first for anaerobic degradation of complex
substrates and later for aerobic oxidation of soluble products. This "activated
sludge" treatment is dependent upon incubation conditions that favour the
growth and metabolic activity of appropriate microorganisms.

Another aspect of the microbiology of water pertains to natural bodies of
water such as ponds, lakes, rivers, and oceans. Aquatic microbes perform a
host of biochemical transformations and are an essential component of the
food chain in these environments. For example, the microbial flora of the sea
comprises bacteria, algae, fungi, and protozoa. The microorganisms inhabiting
aquatic environments are collectively referred to as plankton; phytoplankton
refers to the photosynthetic microbes (primarily algae), whereas protozoa,
and other small animals, are zooplankton.
Phytoplankton is responsible for converting solar energy into chemical
energy-the components of plankton cells that serve as food for higher aquatic
life. The magnitude of this process can be appreciated by calculations
indicating that it takes 1,000 tons of phytoplankton to support the growth of
one ton of fish.
Large populations of archaea live in volcanic ridges 2,600 metres (8,500 feet)
below the ocean surface in areas immediately surrounding hydrothermal
vents (deep-sea hot springs). The vents spew superheated water (350 °C [662
°F]) that contains hydrogen sulfide (HS); the water surrounding the vents has
a temperature range of 10-20 °C
(50-68 °F). Many bacteria concentrate in this region because of the availability
of H2S, which they can use for energy. The abundance of animal life that also
inhabits this region is completely dependent on the microbes for food.
There is a growing interest in other ecological aspects of aquatic microbiology,
such as the role of microbes in global warming and oxygen production.
Experimental approaches are being developed to study the complex biology
and ecology of biofilms and microbial mats. These assemblages of microbes
and their products, while potentially useful in several ways, are complex. In
many instances the microbial flora involved must sometimes be studied in its
natural environment because the environment cannot be reproduced in the
laboratory.

Food microbiology

Microorganisms are of great significance to foods for the following reasons:
(1) microorganisms can cause spoilage of foods, (2) microorganisms are used
to manufacture a wide variety of food products, and (3) microbial diseases can
be transmitted by foods.

Food spoilage

Foods can be considered as a medium for microbial growth. Considering the
vast array of sources, substances, and methods with which food is produced,
practically every kind of microbe is a potential contaminant. Given a chance to
grow, microbes will produce changes in appearance, flavour, odour, and other
qualities of the food. The changes vary according to the type of food degraded
but can be summarized by examining the fates of the major nutrients found in
food: proteins, carbohydrates, and fats.
Protein-containing foods, particularly meats, are putrefied by organisms (e.g.,
Proteus, Pseudomonas, and Clostridium bacteria) that break down the long
peptide chains of proteins into amino acids and foul-smelling compounds such
as amines, ammonia, and hydrogen sulfide (HS).
Carbohydrates (sugars and starches) are fermented into acids (e.g., the acetic
acid in vinegar), alcohols, and gases, especially carbon dioxide. This process is
responsible for the bursting of spoiled chocolate cream candies by yeasts.
Fat-containing foods such as dairy products are spoiled by microbes that
break down lipids into fatty acids and glycerol. Rancid milk, which can be
caused by bacteria, yeast, or mold, is an example of this process.
Improperly canned foods are also subject to spoilage by bacteria, yeasts, and
molds.
Bacteria such as Bacillus and Clostridium are of particular significance in the
canning industry because of the high level of resistance that their spores
possess. One example of microbial spoilage of canned foods is "sulfide
spoilage" caused by C. nigrificans, in which contents are blackened and have
the odour of rotten eggs. Another example is called "flat sour," in which the
spoiled product has an abnormal odour, a cloudy appearance, and a sour taste
owing to its lowered pH. Putrefaction caused by C. sporogenes may cause a
can to swell and burst, releasing its partially digested contents and a putrid
odour.

Food preservation

All methods of food preservation are based upon one or more of the following
principles:
(1) prevention of contamination and removal of microorganisms, (2)
inhibition of microbial growth and metabolism, and (3) killing of
microorganisms. Prevention-or, more accurately, minimization-of
contamination is achieved by the sanitary handling of raw food products,
inhibition of growth by low temperatures (refrigeration or freezing),
dehydration by evaporation or by high concentrations of salt or sugar, and
killing of microbes by the application of high temperatures and, in some
instances, radiation.

Food products from microorganisms

Important food items produced in whole or in part by the biochemical
activities of microorganisms include pickles, sauerkraut, olives, soy sauce,
certain types of sausage, all unprocessed cheeses except cream cheese, and
many fermented milk products such as yogurt and acidophilus milk. In each
instance a raw food item, such as cucumbers in the case of pickles or milk
protein in the case of cheeses, is inoculated with microorganisms known to
produce the changes required for a desirable product.
The initial food item thus serves as a substrate that is acted upon by
microorganisms during the period of incubation. Frequently the manufacturer
uses a "starter culture"—a commercial population of microorganisms already
known to produce a good product.

Industrial microbiology and genetic engineering

Many substances of considerable economic value are products of microbial
metabolism.
From an industrial viewpoint the substrate may be regarded as a raw material
and the microorganism as the "chemical factory" for converting the raw
material into new products. If an organism can be shown to convert
inexpensive raw material into a useful product, it may be feasible to perform
this reaction on a large industrial scale if the following conditions can be met.
The organism.
The organism to be employed (a virus, bacterium, yeast, or mold) must
have the capacity to produce appreciable amounts of the product. It
should have relatively stable characteristics and the. ability to grow
rapidly and vigorously, and it should be nonpathogenic.
The medium.
The medium, including the substrate from which the organism produces
the new product, must be cheap and readily available in large quantities.
The product.
A feasible method of recovering and purifying the desired end product
must be developed. Industrial fermentations are performed in large
 tanks, some with capacities of 190,000 litres (50,000 gallons) or more.
The product formed by the metabolism of the microorganism must be
removed from a heterogeneous mixture that also includes a tremendous
crop of microbial cells and unused constituents of the medium, as well
as products of metabolism other than those being sought.
Traditional products of industrial microbiology are antibiotics, alcoholic
beverages, vaccines, vinegar, and miscellaneous chemicals such as
acetone and butyl alcohol.
The development of recombinant DNA technology, however, has made it
possible to conceive of virtually unlimited new products made by genetically
engineered microorganisms. One example of what can be achieved via
recombinant DNA technology is the production of human insulin by a
genetically altered strain of E. coli.
By inserting the human gene coding for insulin into the E. coli cell,
biotechnologists give this bacterium the ability to synthesize the hormone on
an industrial scale.
The scientific advances that have made genetic engineering a reality have
broad implications for the future. By introducing foreign genes into
microorganisms, it may be possible to develop strains of microbes that offer
new solutions to such diverse problems as pollution, food and energy
shortages, and the treatment and control of disease.