Microorganisms: Introduction to Bacteria PDF

Summary

This document provides an introduction to bacteria, outlining their key characteristics, structure, reproduction, and metabolism. It also discusses the roles of bacteria in ecosystems, biotechnology, and disease. The document also touches on archaea.

Full Transcript

COURSE TITLE: FUNDAMENTALS OF MICROBIOLOGY
Unit 1: Microorganisms and their significance

Introduction to Bacteria:

Bacteria are fascinating and diverse microorganisms that play a crucial role in
the biosphere. They are single-celled prokaryotic organisms, which means they
lack a true nucleus and other membrane-bound organelles. Despite their
simplicity, bacteria are incredibly resilient and adaptable, existing in almost
every environment on Earth, from the deepest oceans to the highest mountains
and even inside the human body.

Key Characteristics:

 Prokaryotic Cells: Bacteria are among the simplest forms of life and lack a
membrane-bound nucleus. Instead, their genetic material, typically a circular
DNA molecule, is found in the nucleoid region.
 Cell Structure: Bacterial cells are surrounded by a rigid cell wall made up of
peptidoglycan, a unique molecule not found in eukaryotic cells. Some
bacteria also possess an outer capsule that provides protection and aids in
adhesion.
 Shape and Arrangement: Bacteria can have various shapes, such as cocci
(spherical), bacilli (rod-shaped), and spirilli (spiral-shaped). They can occur
as single cells, pairs (diplo), chains (strepto), or clusters (staphylo).
 Reproduction: Bacteria reproduce asexually through binary fission, where a
single cell divides into two identical daughter cells. This process is highly
efficient and can lead to rapid population growth.
 Metabolism: Bacteria exhibit diverse metabolic pathways. Some are
autotrophs, capable of synthesizing their own food from inorganic
substances, while others are heterotrophs, relying on organic compounds for
sustenance. Some bacteria can also thrive in extreme conditions, known as
extremophiles.

Figure 11: Animated representation of structure of a typical bacterial cell

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Figure 12: Metabolic diversities in bacteria

Roles and Importance of Bacteria:

 Decomposers: Bacteria play a vital role in the ecosystem by breaking down
dead organic matter and recycling nutrients. They help convert complex
organic compounds into simpler forms that can be absorbed by plants and
other organisms.
 Nitrogen Fixation: Certain bacteria are capable of converting atmospheric
nitrogen into a form usable by plants (ammonia), thus contributing to the
nitrogen cycle and providing essential nutrients for the growth of living
organisms.
 Symbiotic Relationships: Bacteria form symbiotic relationships with various
organisms. For instance, some bacteria live in the guts of animals, aiding in
digestion and providing mutual benefits.
 Biotechnology and Industry: Bacteria are used in various biotechnological
applications, such as producing enzymes, antibiotics, and other valuable
compounds. They are also involved in food fermentation processes.
 Disease and Pathogens: While most bacteria are harmless or even beneficial,
some can cause diseases in humans, animals, and plants. These disease-
causing bacteria are known as pathogens and can be responsible for various
illnesses.

In conclusion, bacteria are a diverse group of microorganisms that have a
significant impact on our planet. Their ability to adapt, their ecological roles, and
their importance in various fields of science make them a subject of great
interest and importance in the study of biology and microbiology. Understanding
bacteria is crucial for advancing our knowledge of life processes and for
developing strategies to address both the beneficial and harmful aspects of
bacterial interactions with the world around us.

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Introduction to Archaea:

The term ‘Archaea’ is derived from a Greek word, ‘archaios’ which means
primitive or ancient, indicating the primitive structure of these organisms.
Archaea, are a fascinating group of microorganisms that form one of the three
domains of life, alongside Bacteria and Eukarya. Archaea were first discovered in
the 1970s by American microbiologist Carl Woese, who recognized their
uniqueness and distinct evolutionary history.

Key Characteristics:

 Ancient lineage: Archaea are some of the oldest known life forms on Earth,
with their origins dating back over 3.5 billion years. They thrived in extreme
environments long before more complex life forms appeared.
 Cellular structure: Archaea are single-celled microorganisms. Their cellular
structure is prokaryotic, meaning they lack a true nucleus and other
membrane-bound organelles found in eukaryotic cells.
 Genetic differences: Archaea have genetic differences from both Bacteria and
Eukarya. They possess a unique RNA polymerase enzyme that distinguishes
them from bacteria and shares some similarities with eukaryotes.
 Extremophiles: Some of the most fascinating members of the Archaea
domain are extremophiles. These microorganisms can survive and thrive in
extreme environmental conditions that are hostile to most other life forms.
Examples include thermophiles (heat-loving), halophiles (salt-loving),
acidophiles (acid-loving), and methanogens (organisms that produce
methane in anaerobic environments).
 Importance in biogeochemical cycles: Archaea play critical roles in various
biogeochemical cycles, such as the nitrogen cycle and carbon cycle.
Methanogenic archaea, for instance, are involved in the production of
methane, a potent greenhouse gas, and are significant contributors to global
warming.
 Ubiquitous distribution: Archaea are found in diverse habitats, including
terrestrial and marine environments, hot springs, hydrothermal vents, salt
flats, acidic lakes, and even the human gut.
 Symbiotic relationships: Some archaea form symbiotic relationships with
other organisms. For example, some methanogenic archaea live in the
intestines of certain animals, aiding in the digestion process.
 Taxonomy and classification: Archaea are classified into several phyla, but
our understanding of their diversity is still evolving due to ongoing research
and discoveries.
 Archaea's unique properties and evolutionary significance have led scientists
to study them extensively to gain insights into the origins of life and
understand their biological adaptations to extreme environments. As
research continues, archaea's importance in various ecological and
biochemical processes becomes increasingly apparent, further expanding
our understanding of life on Earth.

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Introduction to Fungi:

Fungi are a diverse group of eukaryotic organisms that play critical roles in
ecosystems and have significant impacts on human life. They belong to their own
kingdom, separate from plants, animals, and bacteria. Fungi exhibit a wide range
of forms and functions, and they can be found in almost every environment on
Earth.

Key Characteristics:

 Eukaryotic cells: Unlike bacteria and archaea, fungi are composed of
eukaryotic cells. This means they have a true nucleus and other membrane-
bound organelles within their cells.
 Heterotrophs: Fungi are heterotrophic organisms, which means they cannot
produce their own food through photosynthesis like plants. Instead, they
acquire nutrients by absorbing organic matter from their environment. They
are primarily decomposers, breaking down dead organic material and
recycling nutrients back into the ecosystem.
 Chitin cell walls: The cell walls of fungi are made of chitin, a tough, complex
carbohydrate that provides structural support and protection for the fungal
cells. This sets them apart from the cell walls of plants, which are composed
of cellulose.

Yeasts and molds are two distinct groups of fungi, each with unique
characteristics and roles in various environments. While they are both types of
fungi, they differ in their morphology, lifestyles, and applications.

Yeasts:

Yeasts are single-celled fungi that belong to the class Ascomycota. They are
widely distributed in nature, and some species have been used by humans for
thousands of years for various purposes. Key features of yeasts include:
 Morphology: Yeasts are unicellular organisms that typically appear as small,
rounded cells under a microscope.
 Reproduction: Yeasts reproduce asexually through a process called budding.
During budding, a small daughter cell forms as an outgrowth from the parent
cell and eventually separates to become a new yeast cell.
 Fermentation: One of the most well-known characteristics of yeasts is their
ability to ferment sugars. This process converts sugars into alcohol and
carbon dioxide, a property utilized in the production of bread, beer, wine,
and other fermented foods.
 Applications: Yeasts have significant applications in the food and beverage
industry, biotechnology, and research. They are used to leaven bread, brew
beer, ferment wine, and produce biofuels, enzymes, and pharmaceuticals.

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Molds:

Molds are filamentous fungi that belong to various groups, including Ascomycota
and Zygomycota. Unlike yeasts, molds are composed of multiple cells and form a
network of thread-like structures called hyphae. Key features of molds include:
 Morphology: Molds have a filamentous and multicellular structure,
consisting of a mass of hyphae called mycelium. The mycelium allows molds
to spread and grow over large areas.
 Reproduction: Molds can reproduce both sexually and asexually. They
produce spores, which are tiny reproductive structures that can be dispersed
through the air to start new colonies in suitable environments.
 Colonization and Decomposition: Molds are known for their ability to
colonize various organic materials. Some molds can cause decay and
decomposition, while others are involved in breaking down dead plant and
animal matter, playing a vital role in nutrient recycling in ecosystems.
 Applications: While some molds can be harmful to human health and cause
food spoilage, others are utilized in the production of various food items,
such as cheese, soy sauce, and certain types of fermented foods.

Both yeasts and molds are essential in various industries and ecological
processes. Yeasts' ability to ferment sugars and produce alcohol has been
exploited by humans for millennia in food and beverage production. On the other
hand, molds play significant roles in decomposition and nutrient cycling in
ecosystems, as well as in the creation of many culturally important food products.
Their diversity and biological significance continue to be areas of active research
and exploration.

Protists

Protists are a diverse group of eukaryotic microorganisms that do not fit into the
classification of plants, animals, or fungi. They belong to the kingdom Protista
and are typically unicellular, although some species can be multicellular. Protists
are known for their remarkable diversity in terms of size, shape, and lifestyle.
They can be found in various aquatic and terrestrial environments, including
freshwater, marine, and soil habitats.

Due to their vast diversity, protists can be broadly categorized into several
groups:

Protozoa: These are unicellular protists that primarily feed on organic matter,
bacteria, and other small particles. They can move using structures like cilia,
flagella, or pseudopodia (temporary extensions of the cell).

Algae: Algae are photosynthetic protists that can be either unicellular or
multicellular. They play a significant role in aquatic ecosystems by producing
oxygen and serving as a primary food source for various aquatic organisms.

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Slime Molds: Slime molds are unique protists that undergo fascinating
transformations during their life cycle. They can be either plasmodial (forming a
multinucleate mass) or cellular (consisting of individual cells).

Water Molds: Water molds are filamentous protists that often live in water and
can be parasitic or saprophytic, meaning they feed on decaying organic matter.

Protists have historically been studied as a single group, but advancements in
molecular biology have revealed their diverse evolutionary relationships.
Consequently, the kingdom Protista is no longer considered a valid taxonomic
group in modern classification systems like the five-kingdom system. Protists are
now distributed across multiple kingdoms, depending on their phylogenetic
relationships and characteristics.

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Algae

Algae are a diverse group of photosynthetic organisms that can range from
single-celled microorganisms to large, multicellular seaweeds. They belong to
the kingdom Protista in the old classification system, while in more modern
classifications, they are distributed among several groups, including the
Chromista, Archaeplastida, and others.

Characteristics of Algae
Specific general characteristics of algae are common to plants as well as animals.
Algal cells are eukaryotic. For instance, algae can photosynthesize like plants,
and they possess specialized structures and cell-organelles, like centrioles and
flagella, found only in animals. The algal cell walls consist of mannans, cellulose
and Galatians. Listed below are some of the general characteristics of algae.

 Algae are photosynthetic organisms
 Algae can be either unicellular or multicellular organisms
 Algae lack a well-defined body, so, structures like roots, stems or leaves are
absent
 Algaes are found where there is adequate moisture.
 Reproduction in algae occurs in both asexual and sexual forms. Asexual
reproduction occurs by spore formation.
 Algae are free-living, although some can form a symbiotic relationship with
other organisms.

Figure 13: Classification of Algae

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Key characteristics of algae include:

Photosynthesis: Like plants, algae use sunlight to synthesize their own food
through photosynthesis. They contain chlorophyll and other pigments that
absorb light energy for this process.
Habitat: Algae can be found in various aquatic environments, such as freshwater,
saltwater, and even damp terrestrial habitats like rocks and tree bark.

Diversity: Algae come in a wide range of shapes, sizes, and colors. Some are
unicellular, like Chlorella and diatoms, while others are multicellular, forming
complex structures like kelp and seaweed.

Importance: Algae play a crucial role in aquatic ecosystems and the planet's
overall ecology. They are primary producers, meaning they form the foundation
of the food chain by providing food and oxygen to other organisms. Additionally,
they are vital in carbon dioxide sequestration, helping regulate the Earth's
atmosphere.

Human Uses: Algae have practical applications as well. For example, they are
used in food products like sushi wraps (nori) and as dietary supplements. Some
species of algae are also cultivated for biofuel production, as they can generate
large amounts of biomass and oils.
Harmful Algal Blooms (HABs): Under certain conditions, some types of algae can
undergo rapid and excessive growth, leading to harmful algal blooms. These
blooms can produce toxins that are harmful to aquatic life, humans, and animals.

Overall, algae are essential components of various ecosystems and have
significant ecological, economic, and industrial importance. They are a
fascinating group of organisms with immense potential for various applications
and research endeavors.

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Protozoa

Protozoa are a group of unicellular, eukaryotic microorganisms belonging to the
kingdom Protista. As the name suggests, the term "protozoa" translates to "first
animals" in Greek, as they were historically among the first unicellular organisms
observed under a microscope.

Protozoa are the simplest animals, usually measuring only a few microns in size.
The most primitive group of animal organisms is the protozoa. They are
unicellular cells with no cell wall, motile organisms and form a very large, highly
diverse group originating from several phylogenetic lines. Currently, there are
roughly more than 50,000 different protozoa species. Some protozoa live as
unwanted guests or parasites inside the bodies of other animals, causing serious
diseases in their hosts such as malaria, kala-azar, sleeping sickness, dysentery,
and so on. Read more about the definition of protozoa, classification,
reproduction, importance and diseases caused by protozoa.

These microorganisms are typically found in various aquatic environments, such
as freshwater, marine habitats, and moist soil. Some protozoa are free-living,
meaning they can survive independently, while others may be parasitic, relying
on a host organism for their nutrition and survival.

What are Protozoa?
Single-celled organisms are known as protozoa. They range in size and shape
from an amoeba, which can change shape, to Paramecium, which has a fixed
shape and sophisticated structure. They can be found in a range of damp
conditions, such as freshwater, marine environments, and soil. The body of
acellular protozoa is not separated into cells, and organelles are parts of
protoplasm set aside for performing certain activities. Most protozoa are aerobic,
mesophilic organisms that thrive at temperatures ranging from 16 to 25 degrees
Celsius. Entamoeba, for example, is anaerobic.

Figure 14: Euglena, Amoeba, Paramecium

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Classification of Protozoa

Figure 15: Classification of Protozoa

Characteristics of Protozoa
Habitat - Protozoans exhibit mainly two forms of life; free-living (aquatic,
freshwater, seawater) and parasitic (ectoparasites or endoparasites). They are
also commensal in habitat.

Size and Shape – They’re microscopic and can only be seen under a microscope.
They are the most basic and rudimentary of all organisms. The body is made up
of only one cell (without tissue and organs). Spherical, oval, elongated, or
flattened body form variables are present. Body symmetry is either none or
bilateral or radial or spherical. The body form is usually constant, varied in some,
while changing with environment or age in many. The body is usually naked or
bounded by a pellicle, but it can be covered in shells and has an internal skeleton
in other species.

Cellular Structure –

 Body organisation is simple, that is, with a protoplasmic grade of
organisation. They have one or more nuclei that are monomorphic or
dimorphic. They are solitary (existing alone/single) or colonial (individuals
are alike and independent).

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 The protozoal cells are not enclosed by a cell wall; rather, their protoplasts
are protected by a special thin and pliable layer which is commonly known
as a pellicle or periplast.

 The cytoplasm of many protozoal cells is separated into two layers: an
outside layer called ectoplasm and an interior layer called endoplasm.

 The consistency of the ectoplasm is often denser than that of the endoplasm.
The protoplast consists of the ingredients typically present in eukaryotic
cells, like the membrane-bound nucleus, Golgi bodies endoplasmic reticulum,
ribosomes and mitochondria.

 The single-cell body performs all the essential and vital activities, which
characterise the animal body; hence only the subcellular physiological
division of labour.

 Another distinguishing trait of some protozoa, such as ciliates, is that they
have two different types of nuclei: a polyploid macronucleus and a diploid
micronucleus.

Locomotory organs are fingers like pseudopodia, whip-like flagella, hair-like
cilia or none. Membrane-bound proteins play a role in how the body reacts to
various environmental stimuli.

Nutrition may be holozoic (animal-like), holophytic (plant-like), saprozoic or
parasitic. Euglena, for example, has chromatophores and does photosynthesis.
These photosynthetic protozoa are commonly referred to as algae. The majority
of protozoa are, however, heterotrophic or holozoic, i.e. they live by phagocytosis
of other organisms.

Digestion takes place inside the food vacuoles, which is an intracellular process.
Solid food particles collected by the protozoa are stored and digested in the food
vacuoles. Enzymes are found in secretory vacuoles.

Respiration occurs by diffusion via the general body surface.

Excretion occurs primarily through the surface, although it can also occur
through a brief opening in the ectoplasm or a permanent pore termed the
cytopyge. In freshwater species, contractile vacuoles regulate osmoregulation
and assist in the removal of excretory products.

Reproduction- Asexual and sexual reproduction are both possible for protozoa.
However, sexual reproduction is less common and only happens in select taxa.

A. Asexual (binary or multiple fission, budding, sporulation)

B. Sexual (conjugation (hologamy), gamete formation (syngamy)

a) Syngamy: A motile microgamete unites with a non-motile macrogamete
(anisogamy) to generate a diploid zygote in Sporozoa (Apicomplexa)
similar to Plasmodium (malarial parasite).

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b) Conjugation is another way of sexual reproduction found in ciliate
protozoa such as Tetrahymena and Paramecium.

c) Autogamy: The male and female gametes give rise to the same
unicellular fusion to form a diploid zygote. Thus, in autogamy, both
gametes are produced by the same parent. It occurs in some ciliated
protozoa like Paramecium.

The life cycle is often complicated with alternation of asexual and sexual phases
(alternation of generation). Most protozoa have a life cycle that alternates
between a latent cyst stage and a proliferating vegetative stage, such as
trophozoites. Without water or nutrition, the cyst stage can survive in extreme
environments. It can stay outside the host for prolonged periods of time before
being transmitted. The trophozoite stage is contagious, and it is during this stage
that they feed and multiply.

Encystment commonly occurs to resist unfavourable conditions of food,
temperature, and moisture and also helps in dispersal.

Examples: Euglena, Amoeba, Plasmodium, Paramecium, Podophyra, etc.

Importance of Protozoans

1. Protozoans have a critical function in soil fertility. They manage bacterial
populations and keep them in a state of physiological youth, or active growth
phase, by feeding on soil bacteria. This accelerates the decomposition of
dead organic substances by microbes.

2. Protozoans also excrete nitrogen and phosphorus as products of their
metabolism, in the form of ammonium and orthophosphate, and studies
have shown that the presence of protozoans in soils promotes plant growth.

3. In both activated sludge or slow percolating filter plants, protozoans play a
significant role in wastewater treatment.

4. Protozoans provide shelter, carbon, and vital phytonutrients in exchange.

5. Protozoan grazing can have a significant impact on phytoplankton. These
planktonic protozoans, like soil protozoans, expel a lot of nitrogen and
phosphate.

6. Protozoans play a critical role in the phytoplankton’s recycling of key
nutrients (nitrogen and phosphorus).

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Protozoan Disease

Diseases Etiological Agents

Malaria Plasmodium falciparum, P. vivax

African Trypanosomiasis Trypanosoma brucei

Chagas Disease Trypanosoma cruzi

Leishmaniasis Leishmania donovani, L. major

Summary

Single-celled organisms are known as protozoa. They range in size and shape
from an amoeba, which can change shape, to Paramecium, which has a fixed
shape and sophisticated structure. They can be found in a range of damp
conditions, such as freshwater, marine environments, and soil. Protozoa are
known for their ability to move on their own, which is a trait shared by the
majority of species. They cannot frequently photosynthesise, even though the
Euglena genus is known for both motility and photosynthesis (and is therefore
considered both an alga and a protozoan).

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Slime Moulds
Slime moulds (or slime molds) are earlier grouped under fungi, however, later
they are kept in the kingdom Protista with other unicellular and small
multicellular eukaryotic organisms.

They are saprophytic and feed on dead and decaying organic matter.

The name ‘slime’ comes from the gelatinous appearance of macroscopic slime
moulds. Under unfavourable conditions, they form aggregates, this is common in
plasmodial or acellular slime moulds. Their size varies from a few centimetres to
several square metres.

They can live as a single-celled organism when there is abundant food, mainly
cellular slime moulds.

There are approximately 900 species of slime moulds present worldwide.

General Characteristics of Slime Moulds

 Slime moulds are found creeping on debris, decaying leaves or twigs, in
soil, on the forest floor, on tree canopies and moist, dark and cool
conditions
 The protoplast is not surrounded by a cell wall in the vegetative phase
 They are saprophytic and lack chlorophyll. They feed on microorganisms
such as bacteria, fungi and yeasts and decompose dead organic matter
 Some of the slime moulds are parasitic and found in the roots of cabbage
and other plants of Brassicaceae family
 The plasmodial stage resembles protozoa and fruiting bodies form spores
resembling fungi
 Spores have a cell wall made up of cellulose and are resistant to adverse
conditions. They can survive for many years

Slime Moulds Classification
Slime moulds are classified under kingdom Protista. They resemble fungi as well
as protozoa. In modern taxonomy, the true slime moulds come under Mycetozoa.
They are further classified in different classes. The main classes of slime moulds
are the following:

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Myxomycetes- True slime moulds or acellular slime moulds. They are
characterised by syncytial (multinucleated), plasmodial stage

Myxomycetes
(plasmodial stage)

Figure 20: Myxomycetes

Dictyostelia- Cellular slime moulds. They do not form huge coenocytes

Figure 21: Dictyostelium discoideum

Protostelia- Simple, minute, amoeboid slime moulds

Figure 22: Life cycle of Plasmodial Slime moulds

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Acrasia- Cellular slime moulds similar to dictyostelids but have eruptive
pseudopodia

Figure 23: Acrasia (sorocarpic amoebae). Light micrographs. Acrasiaceae.
1–3. Acrasis spp. 1. Sorocarp. Scale bar = 100 μm. 2. Spore; note the
prominent hila on the spore. 3. Limax-type amoebae. Scale bar = 10 μm.
Copromyxaceae. 4–6. Copromyxa protea. 4. Sorocarp. Scale bar = 100 μm. 5.
Sorocyst (spore). 6. Limax-type monopodial amoeba. Fonticulaceae. 7–9.
Fonticula alba. 7. Sorocarp. Scale bar = 100 μm. 8, 9. Amoebae of F. alba
with filose pseudopodia near a fungal hypha. Guttulinopsidaceae. 10–12.
Guttulinopsis vulgaris. 10. Two sorocarps fruiting near one another. Scale
bar = 100 μm. 11. Spore. 12. Flabellate-type amoebae. – Scales for Figs. 2, 5,
6, 8, 9, 11, 12 as for Fig. 3. Images M. Brown.

Plasmodiophomycetes- Parasitic slime moulds. They are found as an internal
parasite in cabbage roots. They cause various diseases in plants such as clubroot
disease of cabbage

Club root disease

Figure 24: Plasmodiophomycetes: Parasitic slime moulds

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Labyrinthulae- Net slime moulds. Form a network of tubes in which amoeba
without pseudopodia can swim freely

Figure 25: Labyrinthula sp.

Fonticula- Form volcano-shaped fruiting bodies

Figure 26: Fonticula on agar medium

Slime moulds are mainly of two types: Acellular and Cellular slime moulds.
Acellular slime moulds are also known as Plasmodial slime moulds

Acellular Slime Moulds (Plasmodial)

 The feeding stage is a multinucleate mass of protoplasm, i.e. plasmodium
 They can grow up to 1 ft in diameter
 They are found creeping as a slimy mass over leaf litter, moist and
decaying logs. It feeds on dead and decaying organic matter and
microorganisms
 When the food is scarce and moisture is less, they reproduce asexually
 Examples: Physarum, Cribaria, Lycogala, Fuligo, Tubifera

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Cellular Slime Moulds

 The feeding stage is a single-celled amoeboid, which lives as a solitary
organism
 They have a close resemblance to amoebas
 Individual cells feed on microorganisms and other food matter while
creeping on decaying log or freely swimming in freshwater
 Just like an amoeba, each cell has a haploid nucleus and divides
mitotically
 When the food is less they form aggregate but retain their individuality
due to the presence of a thin plasma membrane and reproduce asexually
by spore formation
 When the food or moisture is depleted, they send out a cAMP-mediated
chemical signal
 The chemical diffuses out and binds to the receptors present on the
surface of nearby cells resulting in the movement of cells towards cAMP
(cyclic adenosine monophosphate)
 Examples: Dictyostelium, Acytostelium, Polysphondylium

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Water molds

Water molds, also known as oomycetes, occupy a distinct position in the living
world. They are classified as protists, which is a diverse group of eukaryotic
microorganisms that do not fit neatly into other major categories such as animals,
plants, or fungi. Here are some characteristics of water molds and their position
in the living world:

 Kingdom Classification: Water molds belong to the kingdom
Stramenopila (chromista). This kingdom includes a variety of organisms,
some of which have both photosynthetic and non-photosynthetic members.
Diatoms and brown algae are also part of the Stramenopila group.
 Eukaryotic: Water molds, like all protists, are eukaryotic. This means their
cells have a defined nucleus and other membrane-bound organelles.
 Habitats: Water molds are predominantly aquatic microorganisms and are
commonly found in freshwater and marine environments. They thrive in
moist conditions and are often associated with decaying organic matter.

Figure 27: Water mould on organic matter and on dead gold fish

 Filamentous Growth: Water molds exhibit a filamentous growth pattern,
much like fungi. They consist of branching structures called hyphae, which
collectively make up a mycelium.
 Cell Wall Composition: The cell walls of water molds are composed of
cellulose, a carbohydrate polymer. This sets them apart from true fungi,
whose cell walls are made of chitin.
 Heterotrophic Nutrition: Water molds are heterotrophic, meaning they
obtain their nutrition by absorbing organic matter from their environment.
They secrete enzymes into their surroundings to break down organic
materials, which are then absorbed as nutrients.

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 Reproduction: Water molds have both sexual and asexual modes of
reproduction. Sexual reproduction involves the production of specialized
structures like oospores, which are formed when two different mating
types come together. Asexual reproduction involves the production of
zoospores, which are motile spores with flagella that enable them to move
through water.
 Pathogenicity: Some water molds are notorious plant pathogens, causing
diseases in crops and other plants. Phytophthora infestans, responsible for
the Irish Potato Famine, is a well-known example. Water molds can also be
parasitic to aquatic animals, leading to diseases in fish and other aquatic
organisms.
 Ecological Role: Water molds play a role in decomposing organic matter
in aquatic ecosystems. They help recycle nutrients and contribute to the
breakdown of dead plant and animal material.

In summary, water molds are a diverse group of protists with filamentous
growth patterns, cellulose cell walls, and a mix of saprophytic and parasitic
lifestyles. They are ecologically important for nutrient cycling but can also have
negative impacts as pathogens. Water molds occupy a unique position in the
living world due to their characteristics and ecological roles.

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Viruses

Viruses are small infectious agents that are not considered living organisms in
the traditional sense. They are composed of genetic material (either DNA or RNA)
surrounded by a protein coat called a capsid. Some viruses also have an outer
lipid envelope derived from the host cell membrane.

Viruses are unique in that they cannot carry out essential life processes on their
own, such as metabolism or reproduction. Instead, they rely on infecting and
hijacking the cellular machinery of living organisms to replicate and produce
new viral particles. This process often involves the virus attaching to a host cell,
injecting its genetic material into the cell, and then using the host cell's resources
to replicate itself.

Once new viral particles are produced within the host cell, they are released
either by causing the host cell to burst (lytic cycle) or by budding off from the cell
membrane (lysogenic cycle). This process can damage or destroy the host cell,
leading to the symptoms of infection that are often observed in the host
organism.

Viruses can infect a wide variety of hosts, including animals, plants, bacteria
(bacteriophages), and even other viruses (virophages). Here are some examples
of different types of viruses and their respective hosts:

 Animal Viruses: These viruses infect animals, including humans. Examples
include: Influenza virus: Infects birds and mammals, including humans.
Human immunodeficiency virus (HIV): Infects humans and attacks the
immune system, causing AIDS. Herpes simplex virus: Causes oral and genital
herpes in humans. Rabies virus: Infects mammals, including humans, and
affects the nervous system.
 Plant Viruses: These viruses infect various types of plants and can lead to
crop damage. Examples include: Tobacco mosaic virus: Infects tobacco plants
and many other plant species. Potato virus Y: Infects potato and other
Solanaceae family plants. Citrus tristeza virus: Affects citrus trees.
 Bacteriophages (Phages): These viruses infect and replicate within
bacterial cells. They are important for bacterial control and play a role in the
regulation of bacterial populations. Examples include: T4 bacteriophage:
Infects Escherichia coli bacteria. Lambda phage: Can establish both lytic and
lysogenic cycles in E. coli.
 Archaeal Viruses: These viruses infect archaea, which are single-celled
microorganisms distinct from bacteria and eukaryotes. Examples include:
Sulfolobus turreted icosahedral virus (STIV): Infects certain species of
archaea from the genus Sulfolobus.

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 Virophages: These viruses are parasites of other viruses and can infect the
hosts of those viruses. Examples include: Sputnik virophage: Infects
mimivirus, a giant virus that infects amoebae.

Figure 28: Different types of Viruses

Because of their unique characteristics and their ability to cause disease, viruses
are the focus of extensive scientific research in fields such as virology,
immunology, and public health, with the aim of understanding their behavior,
preventing their spread, and developing treatments and vaccines to combat viral
infections. It's important to note that viruses are highly specific in terms of their
hosts. Each virus tends to infect a particular species or a narrow range of species.
This specificity is determined by the interactions between viral surface proteins
and host cell receptors. Understanding these interactions is crucial for
developing strategies to prevent and treat viral infections.

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Unit 1: Microorganisms and their significance

Viroids

Viroids are small, infectious, circular RNA molecules that can cause disease in
plants. They are unique in that they lack a protein coat, which is a characteristic
feature of viruses. Despite their simplicity, viroids are able to replicate and
spread within plant cells, leading to various symptoms of disease.

Structure of Viroids

Viroids differ from virus in structure and form. These consists of solely short
strands of circular, and single-stranded RNA without the protein coats.

The plants that are infected by viroids are responsible for the crop failures and
also cause the loss of millions of dollars in agricultural revenue every year. Some
of the plants that are affected by these pathogens are potatoes, tomatoes,
cucumbers, chrysanthemums, coconut palms, avocados, etc.

Viroids were first discovered by T.O. Diener in the year 1971. It was first
examined in the potato spindle tuber viroid caused a huge loss to the potato
industry.

Viroids are the plant parasites like transcriptional machinery of the cell
organelles such as the nucleus or the chloroplast since they are known to be non-
coding. These replicate by the process of RNA–RNA transcription. They mainly
infect the epidermis of the hosts after causing mechanical damage to the cell wall
of the plant.

Characteristic Features of Viroids

 Viroids contain only RNA.
 These are known to be smaller in size and infect only the plants.
 These are among the smallest known agents causing infectious disease.
 Viroids are species of nucleic acid with relatively low molecular weight and a
unique structure.
 They reproduce within the host cell which they affect and cause variations in
them causing death.
 Viroids are mainly classified into two families namely Pospiviroidae- nuclear
viroids and Avsunviroidae- chloroplastic viroids.
 Viroids are said to move in an intracellular manner, cell to cell through the
plasmodesmata, and long distance through the phloem.

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Viroid Diseases

Some of the diseases that are caused by the infection of viroids in plants are
citrus exocortis, cucumber pale fruit, and chrysanthemum stunt. These infectious
diseases are spread by the propagation of seeds in plants by cutting, tubers, etc
and also by mishandling the contaminated implements. Hepatitis- D is caused in
humans by viroid-like particles.

The symptoms that are caused by the infection of viroid in plants include
stunting of growth, stem necrosis, deformation of the leaves and fruits, and at
last causing the death of the plant.

Most of the viroids are said to infect the plants, including coconut and apple trees.
The (PSTV) potato spindle tuber viroid causes significant crop damage to the
potato yields causing the tubers to elongate and then crack. The other common
type of viroid infection symptoms includes stunting and leaf epinasty.

It's important to note that viroids only infect plants and do not pose a direct
threat to animals or humans.

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Unit 1: Microorganisms and their significance

Satellites

Satellites are similar to viroids in that they also consist only of a nucleic acid
(either DNA or RNA). Satellites are infectious agents that depend on the presence
of a helper virus for their replication and transmission. They are much smaller
than viruses and lack the ability to replicate on their own. Instead, they require
the machinery and resources of a host cell that has been infected by a helper
virus.

They differ from viroids in that they may encode one or more gene products and
need ahelper virus to replicate and infect host cells. There is no homology
between the genome of the satellite and its helper virus.

Satellites are further divided into three types: Satellite viruses, Satellite RNAs,
and Satellite DNAs. Satellite viruses encode their own capsid proteins, whereas
satellite RNAs and DNAs do not. Most satellites use plant viruses as their helper
viruses.

There are three main types of satellite nucleic acids:

Satellite Viruses: These are small infectious agents that have their own nucleic
acid genome but are only able to replicate and propagate within cells that are co-
infected with a compatible helper virus. Satellite viruses are often dependent on
the helper virus for essential functions such as replication, encapsidation, and
movement within the host plant or animal.

Satellite RNAs: Similar to satellite viruses, satellite RNAs are small RNA
molecules that also require a helper virus for replication and transmission. They
rely on the helper virus to provide the necessary proteins and enzymes for their
replication. Satellite RNAs can either enhance or interfere with the replication
and symptoms caused by the helper virus, depending on the specific interactions
between the satellite RNA, helper virus, and host.

Satellites can have various effects on their host organisms. Some satellite
infections can lead to more severe symptoms in the host, while others might
attenuate the symptoms caused by the helper virus. The relationship between
satellites and their helper viruses can be quite complex and can vary depending
on the specific interactions between the two.

Satellites have been primarily studied in the context of plant viruses, where they
can impact agricultural productivity by affecting the severity of viral diseases.
Understanding the interactions between satellites, helper viruses, and host
organisms can provide insights into the mechanisms of viral replication and
pathogenesis and can also have implications for disease management strategies.

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Unit 1: Microorganisms and their significance

Prions

Prions are unique and fascinating infectious agents that are composed of
misfolded proteins. They are associated with a group of neurodegenerative
diseases known as transmissible spongiform encephalopathies (TSEs), which
affect the nervous system of humans and animals. The term "prion" itself stands
for "proteinaceous infectious particle."

Prions are proteins encoded by the PRNP gene that are composed of 253 amino
acids. These proteins are found in two forms including the benign cellular form
(PrPC) and the abnormal misfolded form (PrPSc).

Prions were first discovered in the 1980s during laboratory research on
neurodegenerative diseases. Scientists noticed how prion proteins were highly
expressed in nerve cells and that the abnormal PrPSc form acted as an infectious
pathogen with the capacity to degenerate the central nervous system.

What makes prions remarkable is that they lack a traditional genetic material
like DNA or RNA, which is typically responsible for encoding and transmitting
information for biological processes. Instead, prions are misfolded versions of a
normal cellular protein, usually a protein called PrP (prion protein). When a
prion comes into contact with its properly folded counterpart, it can cause the
normal protein to undergo a conformational change and adopt the misfolded,
infectious form.

This misfolding and accumulation of prions in the brain leads to the destruction
of nerve cells and the formation of microscopic holes, giving the affected brain
tissue a spongy appearance, hence the name "spongiform encephalopathies."

Some well-known prion diseases in animals include:

Bovine Spongiform Encephalopathy (BSE) or "mad cow disease" in cattle.
Scrapie in sheep and goats.
Chronic Wasting Disease (CWD) in deer, elk, and moose.

In humans, prion diseases include:

 Creutzfeldt-Jakob Disease (CJD), which has several variants including
sporadic, familial, and acquired forms.
 Variant Creutzfeldt-Jakob Disease (vCJD), linked to consumption of meat
from cattle affected by BSE.

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Unit 1: Microorganisms and their significance

Prion diseases are often fatal and are challenging to treat or manage due to their
unusual mode of transmission and lack of genetic material. The infectious nature
of prions, their resistance to standard sterilization procedures, and the fact that
they can arise spontaneously through protein misfolding make them a subject of
significant scientific interest and concern.

Furthermore, scientists are working to discover therapeutic strategies to treat
prion diseases. The majority of which aim to reduce the level of abnormal
PrPSc present to limit nerve damage.

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