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hand book
KEY NOTES TERMS
DEFINITIONS FLOW CHARTS

Biology
Highly Useful for Class XI & XII Students,
Medical Entrances and Other Competitions

Sanjay Sharma
Supported by
Kavita Agarwal
Navraj Bharadwaj

ARIHANT PRAKASHAN, (SERIES) MEERUT
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Arihant Prakashan (Series), Meerut
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PREFACE
Handbook means reference book listing brief facts on a subject.
So, to facilitate the students in this we have released this
Handbook of Biology. This book has been prepared to serve
the special purpose of the students, to rectify any query or any
concern point of a particular subject.
This book will be of highly use whether students are looking
for a quick revision before the board exams or just before other
Medical Entrances.
This handbook can even be used for revision of a subject in the
time between two shift of the exams, even this handbook can
be used while travelling to Examination Centre or whenever
you have time, less sufficient or more.
The format of this handbook has been developed particularly so
that it can be carried around by the students conveniently.

The objectives of publishing this handbook are :
— To support students in their revision of a subject just before
an examination.
— To provide a focus to students to clear up their doubts about
particular concepts which were not clear to them earlier.
— To give confidence to the students just before they attempt
important examinations.
However, we have put our best efforts in preparing this book,
but if any error or what so ever has been skipped out, we will
by heart welcome your suggestions. Apart from all those who
helped in the compilation of this book, a special note of thanks
goes to Miss Akansha Tomar of Arihant Publications.

Authors
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CONTENTS
1. The Living World 1-6
— Characteristics of Living Beings — Taxonomy
— Biodiversity — Taxonomical Aids
— Systematics

2. Biological Classification 7-23
— Biology : Nature and Scope — Kingdom–Fungi
— Classification of Living Organisms — Kingdom–Plantae
— Kingdom–Monera — Kingdom–Animalia
— Kingdom–Protista — Viruses and Viroids

3. Plant Kingdom 24-42
— Plants : Producers of Ecosystem — Gymnospermae
— Algae — Angiospermae
— Bryophyta — Alternation of generations
— Pteridophyta

4. Animal Kingdom 43-73
— Basis of Classification — Phylum–Arthropoda
— Phylum–Porifera — Phylum–Mollusca
— Phylum–Coelenterata (Cnidaria) — Phylum–Echinodermata
— Phylum–Platyhelminthes — Phylum–Hemichordata
— Phylum–Aschelminthes — Phylum–Chordata
— Phylum–Annelida

5. Morphology of Flowering Plants 74-103
— Plant Morphology : An Overview — Flower
— Stem — Fruit
— Leaf — Seed
— Inflorescence

6. Anatomy of Flowering Plants 104-121
— The tissues — Anatomy of Dicot and Monocot
— Plant Tissue System Plants
— Secondary Growth in Plants
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7. Structural Organisation in Animals 122-151
— Tissue — Neural Tissue
— Epithelial Tissue(By Ruysch) — Earthworm
— Connective Tissue — Cockroach
— Muscular Tissue — Frog

8. Cell : The Unit of Life 152-166
— Cell — Structure and Components of
— Cell Theory Eukaryotic Cell
— Components of a Cell

9. Biomolecules 167-188
— How to Analyse Chemical — Nucleic Acids
Composition? — DNA
— Biomolecules — RNA
— Carbohydrates(Saccharides) — Enzymes
— Proteins — Metabolites
— Lipids

10. Cell Cycle and Cell Division 189-194
— Cell Cycle — Amitosis
— Dividing or M-phase — Significance of Cell Cycle

11. Transport in Plants 195-206
— Process Involved in Passive — Upward Water Movement in a
Transport Plant
— Plant-Water Relation — Uptake and Transport of Mineral
— Long Distance Transport of Water Nutrients
— Absorption of Water by Plants — Translocation and Storage of Food
in Plants (Phloem Transport)

12. Mineral Nutrition in Plants 207-214
— Classification of Mineral Nutrients — Hydroponics
— Deficiency Symptoms of Essential — Metabolism of Nitrogen
Mineral Nutrients

13. Photosynthesis in Higher Plants 215-227
— Chemistry and Thermodynamics — Photorespiration
of Photosynthesis — Factors Affecting Photosynthesis
— Chloroplast : Photosynthetic
Organ of Cell
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14. Respiration in Plants 228-238
— Cellular Respiration — Anaerobic Cellular Respiration
— Aerobic Respiration — Factors Affecting Respiration
— Pentose Phosphate Pathway (PPP)

15. Plant Growth and Development 239-248
— Growth — Seed Dormancy
— Development — Photoperiodism
— Plant Hormones/Phytohormones/ — Abscission of Plant Parts
Plant Growth Regulators (PGRs)

16. Digestion and Absorption 249-264
— Human Digestive System — Digestive Enzymes
— Alimentary Canal — Digestive Hormones
— Digestive Glands — Disorder of Digestive System
— Physiology of Digestion

17. Breathing and Exchange of Gases 265-275
— Respiration — Transport of Gases
— Human Respiratory System — Regulation of Respiration
— Lungs — Disorders of Respiratory System
— Exchange of Gases

18. Body Fluids and Circulation 276-296
— Body Fluids — Human Circulatory System
— Blood — Blood Vascular System
— Lymph — Portal System
— Circulatory System

19. Excretory Products and Their Elimination 297-306
— Excretion — Regulation of Kidney Function
— Excretory Products — Micturition
— Human Excretory System — Role of Other Organs in Excretion
— Mechanism of Filtrate
Concentration

20. Locomotion and Movement 307-329
— Locomotion — Skeletal System
— Movement — Joints
— Muscle — Disorders of Muscular and
— Specialised Muscle Phenomena Skeletal System
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21. Neural Control and Coordination 330-359
— Human Neural System — Nerve Impulse
— Central Nervous System — Synapse
— Brain — Sense Organs
— Brain Ventricles — The Visual Sense-The Eye
— Spinal Cord — Human Ear-Organ of Hearing and
— Reflex Action Balance
— Reflex Arc

22. Chemical Coordination and Integration 360-370
— Glands — Regulation of Hormone Action
— Hormones — Major Hormones of Human
— Human Endocrine System Endocrine System
— Mechanism of Hormone Action

23. Reproduction in Organisms 371-375
— Reproduction in Plants — Events in Sexual Reproduction of
— Reproduction in Animals Both Plants and Animals

24. Sexual Reproduction in Flowering Plants 376-390
— Flowers — Fertilisation
— Pre-fertilisation : Structures and — Post-fertilisation Events
Events — Development of
— Pollination Embryo/Embryogenesis

25. Human Reproduction 391-414
— Male Reproductive System — Fertilisation
— Female Reproductive System — Implantation
— Gametogenesis — Embryonic Development
— Spermatogenesis — Foetal Development
— Structure of Sperm — Placenta
— The Menstrual Cycle — Lactation

26. Reproductive Health 415-425
— Problems Related to Reproductive — Acquired Immuno Deficiency
Health Syndrome
— Population Explosion — Infertility
— Strategies to Improve — Assisted Reproductive Technology
Reproductive Health — Detection of Foetal Disorders
— Medical Termination of Pregnancy during Early Pregnancy
— Sexually Transmitted Diseases
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27. Principles of Inheritance @neetquestionpaper
and Variation 426-449
— Heredity — Sex-Determination
— Variations — Linkage
— Gregor Johann Mendel — Mutation
— Mendel's Laws of Inheritance — Pedigree Analysis
— Chromosomal Theory of
Inheritance

28. Molecular Basis of Inheritance 450-468
— DNA as Genetic Material — Wobble Hypothesis
— DNA — Regulation of Gene Expression
— RNA — Human Genome Project
— Gene Expression — DNA Fingerprinting
— Genetic Code

29. Evolution 469-499
— Origin of Universe — Mutation Theory
— Origin of Life — Mechanism of Evolution
— Evidences of Evolution — Evolution of Human
— Theories of Evolution — Human and Other Primates
— Darwinism

30. Human Health and Diseases 500-521
— Human Health — Acquired Immuno Deficiency
— Common Diseases in Humans Syndrome
— Immunity and Immune System — Cancer
— Complement System — Drugs
— Vaccination and Immunisation — Addiction
— Allergies — De-addiction
— Autoimmunity — Adolescence

31. Strategies for Enhancement in Food Production 522-537
— Animal Husbandry — Apiculture/Bee-Farming
— Improvement of Animals through — Sericulture
Breeding — Lac Culture
— Pisciculture/ Fish Farming/ Culture — Plant Breeding
Fishery — Single Cell Protein

32. Microbes in Human Welfare 538-547
— Microbes in Household Products — Bioherbicides
— Microbes in Industrial Products — Bioinsecticides
— Biopesticides — Microbes in Sewage Treatment
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33. Biotechnology : Principles and Processes 548-561
— Principle of Biotechnology — Gel Electrophoresis
— Genetic Engineering/Recombinant — Bioreactors
DNA Technology — Downstream Processing
— Tools of rDNA Technology

34. Biotechnology and Its Applications 562-574
— Types of Biotechnology — Applications of Biotechnology in
— Applications of Biotechnology in Industry and Environment
Plant Tissue Culture
— Applications of Biotechnology in
Medicine

35. Organisms and Population 575-585
— Organism and its Environment — Population and Community
— Responses to Abiotic Factors — Characteristics of Population
— Adaptations

36. Ecosystem 586-603
— Ecosystem — Features of Ecosystem
— Components of Ecosystem — Food Chain
— Ecosystem: Structure and — Food Web
Characteristics — Ecosystem Services

37. Biodiversity and Conservation 604-617
— Levels of Biodiversity — Loss of Biodiversity
— Patterns of Biodiversity — IUCN and Red List Categories
— Importance of Biodiversity — Biodiversity Conservation

38. Environmental Issues 618-639
— Pollution — Ozone Layer Depletion
— Greenhouse Effect — Degradation by Improper
— Global Warming Resource Utilisation and
— Acid Rain Maintenance

Appendix 640-644
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1
The Living World
Life is a characteristic quality that differentiates inanimate (non-living)
objects from the animate (living) forms.

Characteristics of Living Beings
Catabolism
Process of breakdown
of complex substances
into simpler ones, Growth
e.g., respiration. Living organisms
Short-term Adaptations Anabolism grow with increase
Temporary changes to Process of formation in mass and number
respond to changing of complex substances of individuals/cells.
environment, from simpler ones,
e.g., hibernation and e.g., photosynthesis. Heat Stroke
aestivation. Increase in body
temperature above the
Long-term Adaptations A series of chemical normal level.
Permanent changes in processes catalysed
by enzymes, occurring
Hypothermia
response to changing
Decrease in body
environment, within the body
temperature below the
e.g., humming birds. of living beings.
normal level.
Metabolism
Adaptation Thermoregulation
Genetic mechanism of Process that allows
an organism to survive, Characteristics
your body to maintains
thrive and reproduce by of its core internal
constantly enhancing Living Beings temperature
itself.
Conciousness Cellular Organisation
Reproduction
Composition and
Ability of an Process of producing arrangement of
organism to young ones by ·cells in body.
sense its living things.
environment.
Multicellular Organisms
Asexual Reproduction Organisms with multiple
Irritability Does not involve the cells of various type,
Ability of an organism to fusion of gametes or e.g., Hydra.
react against external stimuli, sex cells, e.g., Amoeba. Unicellular Organisms
e.g., movement of an Organisms having a
Sexual Reproduction
organism towards the light single cell,
Involves the fusion of
source. e.g., Amoeba.
gametes, e.g., humans.
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2 Handbook of Biology

Biodiversity
It is the degree of variability among living organisms. It includes all
the varieties of plants and animals. It encompasses all the ecological
complexes (in which the diversity occurs), ecosystem, community
diversity, species diversity and genetic diversity. It comprises all the
millions of species and the genetic differences between them.

Systematics
It is the study of the biodiversity. It attempts to classify the diversity of
organisms on the basis of following four fields viz, identification,
classification, nomenclature.
1. Identification
It aims to identify the correct name and position of an organism in the
already established classification system. It is done with the help of
keys. Key is a list of alternate characters found in organisms. An
organism can be identified easily by selecting and eliminating the
characters present in the key.
2. Classification
It involves the scientific grouping of identified organisms into
convenient categories or taxa based on some easily observable
and fundamental characters. The various categories which show
hierarchical arrangement in decreasing order are
Kingdom → Phylum → Class → Order → Family → Genus → Species
3. Nomenclature
After classification, organisms are subjected to a format of two-word
naming system called binomial nomenclature. It consists of two
components, i.e., generic name and specific epithet. For example, in
Mangifera indica, ‘Mangifera’ is the generic name and ‘indica’ is the
specific name of mango. This system was proposed by C Linnaeus
(a Swedish Botanist) in (1753) in his book Species Plantarum.
Polynomial system of nomenclature is a type of naming system
containing more than two words. Trinomial system is a component of
polynomial system and contains three words. Third word represents
the sub-species and first two-words remain the same as in binomial
system.
Codes of Biological Nomenclature
There are five codes of nomenclature which help to avoid errors,
duplication and ambiguity in scientific names.
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The Living World 3
These codes are as follows
ICBN International Code of Botanical Nomenclature
ICZN International Code of Zoological Nomenclature
ICVN International Code of Viral Nomenclature
ICNB International Code for Nomenclature of Bacteria
ICNCP International Code for Nomenclature for Cultivated Plants
Types of Specification in Nomenclature
The ICBN recognises following several types are given below
Syntype
Holotype
Any of the two or more
Prototype specimen from specimens cited by an
which description of a new author when there is
species is established. no holotype.

Specification
Isotype in Paratype
It is the same as Nomenclature Specimens described
holotype. along with the holotype.

Neotype Lectotype
New nomenclature type Specimen selected from
when the holotype is original material when
not available. there is no holotype.

Taxonomy
It deals with the principles and procedures of identification,
nomenclature and classification of organisms. It reflects the natural
and phylogenetic relationships among organisms. It also provides the
details of external and internal structures, cellular structure and
ecological information of organisms. The term taxonomy was coined by
AP de Candolle, 1813.
Various Branches of Taxonomy
Taxonomic Field Basis
Alpha (α) Taxonomy Morphological traits
Artificial Taxonomy Habit and habitat of organisms
Natural Taxonomy Natural similarities among organisms
Chemotaxonomy Presence or absence of chemicals in cells or tissues
Cytotaxonomy Cytological studies
Numerical or Phenetic Taxonomy Number of shared characters of various organisms
Phylogenetic or Omega (ω) Taxonomy Based on phylogenetic relationships
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4 Handbook of Biology

Classical Taxonomy
It is also known as old taxonomy. In classical taxonomy, species is the
basic unit and it can be described on the basis of one or few preserved
specimens. Organisms are classified on the basis of some limited features.
Modern Taxonomy/New Systematics
The concept of modern taxonomy was given by Julian Huxley (1940).
According to it, species are dynamic and ever-changing entity. Studies
of organisms are done on a huge number of variations. It includes
cytotaxonomy, numerical taxonomy, chemotaxonomy, etc.

Taxonomic Categories
Classification is not a single step process. It involves hierarchy of steps
in which each step represents a rank or category. Since, the category is
a part of overall taxonomic arrangement, it is called the taxonomic
category.
The taxonomic categories, which are always used in hierarchical
classification of organisms are called obligate categories.
The sub-categories like sub-species, sub-class, sub-family, etc., which
facilitate more sound and scientific placement of various taxa are
called intermediate categories.
Arrangement of taxonomic categories in a descending order during the
classification of an organism is called taxonomic hierarchy. It was
first introduced by Linnaeus (1751) and hence, it is also known as
Linnaean Hierarchy.
Taxonomic Categories

For Plants For Animals
Kingdom Kingdom

Division Phylum

Class Class

Order Order

Family Family

Genus Genus

Species Species
Taxonomic categories showing hierarchical
arrangement in ascending order
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The Living World 5
Taxon represents the rank of each category and referred to as a unit
of classification. The term ‘Taxon’ was first introduced by ICBN during
1956. According to Mayr (1964), taxon is a group of any rank that is
sufficiently distinct to be worthy of being assigned a definite category.
In simple words, taxon refers to a group of similar, genetically related
individuals having certain characters distinct from those of other
groups.
(i) Kingdom It is the highest category in taxonomy. A kingdom
includes all the organisms which share a set of distinguished
characters.
(ii) Phylum or Division (Cuvier, Eichler) It is a taxonomic
category higher than class and lower in rank to kingdom. The
term ‘Phylum’ is used for animals, while ‘Division’ is commonly
employed for plants. It consists of more than one classes having
some similar correlated characters.
(iii) Class (Linnaeus) It is a major category, which includes related
orders.
(iv) Order (Linnaeus) It is a group of one or more related families
that possess some similar correlated characters, which are
lesser in number as compared to a family or genera.
(v) Family (John Ray) It is a group of related genera with less
number of similarities as compared to genus and species. All the
genera of a family have some common or correlated features.
They are separable from genera of a related family by
important differences in both vegetative and reproductive
features.
(vi) Genus (Term given by John Ray) It comprises a group of related
species, which has more characters common in comparison to
species of other genera. In other words, genera are the
aggregates of closely related species.
(vii) Species Taxonomic studies consider a group of individual
organisms with fundamental similarities as a species
(John Ray). It is the lowest or basic taxonomic category, which
consists of one or more individuals of a population.
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6 Handbook of Biology

Taxonomical Aids
They include techniques, procedures and stored information that are
useful in identification and classification of organisms.
Some of the taxonomical aids are as follows
Herbarium Manuals and Catalogues
Storehouse of collected Provide information for
plant specimens that are identification of names
dried, pressed and of species found in an area.
preserved on sheets.

Museums Taxonomical Aids Monographs
Place for the collection Contain information
of preserved plants and on any one taxon.
animal specimens.

Keys Botanical and Zoological Parks
Used for identification of Contain the living collection of
plants and animals based plants and animals in the
on their similarities and conditions similar to their
dissimilarities. natural habitat.

Importance of Taxonomical Aids
l These aids help to store and preserve the information as well as
the specimens. The collection of actual specimens of plant and
animal species is essential and is the prime source of taxonomic
studies.
l These are also essential for training in systematics which is used for
the classification of an organism. Hence, taxonomic aids facilitate
identification, naming and classification of organisms using actual
specimens collected from the fields and preserved as referrals in the
form of herbaria, museums, etc.
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2
Biological
Classification
Biology : Nature and Scope
Biology (L. bios – life; logos – knowledge) is the branch of science,
which deals with the study of living organisms and their life processes.
Aristotle is called the Father of Biology, but the term ‘Biology’ was
first coined by Lamarck and Treviranus in 1802. It has two main
branches, i.e., Botany (study of plants) and Zoology (study of animals).
l
Father of Botany Theophrastus
l
Father of Zoology Aristotle

Classification of Living Organisms
Classification is an arrangement of living organisms according to their
common characteristics and placing the group within taxonomic
hierarchy.
The branch of science which deals with description, nomenclature,
identification and classification of organisms is called taxonomy.
Some major branches of taxonomy are
(i) Numerical taxonomy It is based on all observable
characteristics. Number and codes are assigned to characters
and data is processed through computers.
(ii) Cytotaxonomy In this taxonomy, the detailed cytological
information is used to categorise organisms.
(iii) Chemotaxonomy The chemical constituents are taken as
the basis for classification of organisms.
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8 Handbook of Biology

On the basis of reference criteria, the classification of living organisms can be
of three types
Classification of Living Organisms

Artificial Natural Phylogenetic
or or or
Prior Classification Phenetic Classification Cladistic Classification

1. Artificial or Prior Classification
In this system of classification one or very few characters are
considered as the key feature of classification. This classification
system never throws light on affinities or relationships between the
organisms.

2. Natural or Phenetic Classification
The classification system in which organisms are classified on the basis
of their permanent vegetative characters. In this classification system,
the grouping of heterogenous groups (unrelated) of organisms is
avoided.

3. Cladistic or Phylogenetic Classification
This classification may be monophyletic (i. e. , one ancestry),
polyphyletic (i. e. the organism derived from two ancestors) and
paraphyletic (i. e. , the organism does not include all the descendents of
common ancestor).
Cladistics is a method of classification of organisms based upon their
genetic and ancestral relationships, which are more scientific and
natural.
The most accepted, five kingdom system of classification of living
organisms was proposed by RH Whittaker. These five kingdoms are
Monera, Protista, Fungi, Animalia and Plantae.

Other Classification Systems
l
Two kingdom system–Carolus Linnaeus (Animalia and Plantae).
Merits Photosynthetic organisms were included into plant kingdom
and non-photosynthetic organisms were included into animal
kingdom.
Demerits Some organisms do not fall naturally either into plant or
animal kingdom or share characteristics of both.
l
Three kingdom system–Ernst Haeckel (Protista, Animalia and
Plantae).
Merits Created a third kingdom which includes unicellular
eukaryotic microorganisms and some multicellular organisms.
Demerits Monerans were not placed correctly.
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Biological Classification 9
l Four kingdom system–Copeland (Monera, Protista, Animalia and
Plantae).
Merits Monerans were placed separately along with other kingdoms.
Demerits Monerans were not subdivided in Archaebacteria and
Eubacteria.
l Six kingdom system–Carl Woese (Archaebacteria, Eubacteria,
Protista, Fungi, Animalia and Plantae).
Merits Archaebacteria and Eubacteria were separately placed.

A. Kingdom–Monera (Prokaryotic, Unicellular Organisms)
It includes all prokaryotes such as bacteria, archaebacteria,
mycoplasma, actinomycetes, cyanobacteria and rickettsia.
1. Bacteria
These unicellular, prokaryotic organisms contain cell wall (feature of
plant cells only). These are approximately 4000 species of bacteria,
with cosmopolitan occurrence. Bacteria can be regarded both friends
and foes on the basis of interaction with human beings.
An average weight human (~ 70 kg) has about 2.5 kg of bacteria in the
form of gut microflora to supplement the proper digestion and other
metabolic functions.
Details to bacteria can be visualised in a nutshell as
Bacteria

Archaebacteria Eubacteria
(primitive bacteria) (true bacteria)

Methanogens Halophiles Thermoacidophiles
(methane producing (salty/marine (present in acidic
bacteria) bacteria) sulphur springs)

On the basis On the basis On the basis
of staining behaviour of structure of nutrition

Gram-Positive Gram-Negative Autotrophic
Bacteria Bacteria Photosynthetic
bacteria
Purple-sulphur
Cocci Bacilli Spirillum Vibrio bacteria
(rounded) (capsule) (spiral) (comma-like) Heterotrophic
Saprophytic
Symbiotic
Parasitic
Non-motile Motile
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10 Handbook of Biology

(i) Archaebacteria
These are the group of most primitive prokaryotes. They have a cell
wall, made up of protein and non-cellulosic polysaccharides. The
presence of 16 srRNA, makes them unique and helps in placing in a
separate domain called archaea between bacteria and eukarya.
Archaebacteria can live under extreme hostile conditions like salt
pans, salt marshes and hot sulphur springs. They are also known as
living fossils, because they represent the earliest form of life on earth.
Archaebacteria can be used for
(a) Experimentation for absorption of solar radiation.
(b) Production of gobar gas from dung and sewage.
(c) Fermentation of cellulose in ruminants.
(ii) Eubacteria
Eubacteria are ‘true bacteria’ which lack nucleus and membrane bound
organalles like mitochondria, chloroplasts, etc. Eubacteria are usually
divided into five phylums– Spirochetes, Chlamydias, Gram- positive
bacteria, Cyanobacteria and Proteobacteria.
The structural detail of a typical eubacterial cell is given as follows
Inclusions Capsule
These are reserve food It is made up of gelatinous polysaccharide
deposits found in prokaryotic and polypeptide. It protects the bacteria,
and eukaryotic cells. These from pathogens and desiccation. It helps
may be of glycogen, starch, in adherance to any surface.
lipid and sulphur granules. Cytoplasm
It contains 80% water, protein,
carbohydrate, lipid, organic ions, etc.
Ribosomes
70 S type of ribosomes, consists
of r RNA and proteins.
Plasma Membrane
Its structure and functions Cell Wall
are similar to eukaryotic It is rigid due to the presence of
plasma membrane. murein. Cell wall contains Mg2+
It is also the site of some ions which bind to teichoic acid.
respiratory enzymes. This binding protects the bacteria
Mesosome from thermal injuries.
Complex localised infolding
of membrane which serves
as respiratory organ, Nuclear Area (Nucleoid)
i.e., centre of respiration. It is amorphous lobular mass of
fibrillar chromatin type material
which occupies 10-20% area of
Fimbriae
cell.
These are short, filamentous structures
composed of protein, pilin. These are Plasmid
evenly distributed and used for Small, circular, self-replicating
attachment rather than motility. extrachromosomal DNA, having
Flagellum few genes.
Long, filamentous appendage consisting of
filament, hook and basal body. It is rotatory
in function and contains flagellin protein.
Detailed structure of a bacterium
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Biological Classification 11
Nutrition in Bacteria
The process of acquiring energy and nutrients., is called nutrition.
On the basis of mode of nutrition, bacteria are of two types–
autotrophic and heterotrophic. About 1% bacteria show autotrophic
mode of nutrition and the rest are of heterotrophic habit.
Chemosynthetic bacteria oxidise various inorganic substances such as
nitrates, nitrites and ammonia and use the released energy for their
ATP production.
Autotrophic (i.e., photosynthetic) bacteria and heterotrophic
bacteria with their related details are mentioned in following tables.
Some Photosynthetic Bacteria
Group Main Habitats Cell Wall Representatives

Prochlorobacteria Live in tissues of marine Gram-negative Prochloron
invertebrates.
Purple or green Generally anaerobic and Gram-negative Rhodospirillum
bacteria reside on sediments of and Chlorobium
lakes and ponds.

Some Heterotrophic Bacteria
Group Main Habitats Cell Wall Representatives

Spirochetes Aquatic habitats, Gram-negative Spirochaeta and
parasites of animals Treponema.
Aerobic rods and Soil, aquatic habitats, Gram-negative Pseudomonas,
cocci parasites of animals Neisseria,
and plants Nitrobacter,
Azotobacter and
Agrobacterium
Facultative Soil, plants, animal gut Gram-negative Salmonella,
anaerobic rods Shigella, Proteus,
(enterobacteria) Escherichia and
Photobacterium
Sulphur and Anaerobic muds, Gram-negative Desulfovibrio
sulphate reducing sediments
bacteria (as in bogs, marshes)
Myxobacteria Decaying plant and Gram-negative Myxococcus and
animal matter, bark of Chondromyces
living trees
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12 Handbook of Biology

Group Main Habitats Cell Wall Representatives

Mycoplasmas Parasites of plants Cell wall absent Mycoplasma
and animals
Gram-positive Soil, skin and mucous Gram-positive Staphylococcus
cocci membranes of animals and
Streptococcus
Endospore-forming Soil; animal gut Gram-positive Bacillus and
rods and cocci Clostridium
Non-sporulating Fermenting plant and Gram-positive Lactobacillus and
rods animal material, Listeria
human oral cavity, gut,
vaginal tract
Chemoautotrophes Soil, aquatic habitat Gram-negative Halothiobacillus
and
Acidothiobacillus

Respiration in Bacteria
Respiration occurs in the plasma membrane of bacteria. Glucose is
broken down into carbon dioxide and water using oxygen in aerobic
cellular respiration and other molecules such as nitrate (NO3 ) in
anaerobic cellular respiration.

Reproduction in Bacteria
Bacteria reproduce asexually and sexually both.
Asexual Methods
Asexually, bacteria reproduce by following methods
l
Fission Bacteria divide both laterally and longitudinally.
l
Budding Vegetative outgrowths result into new organisms after
maturity.
l
Spore formation Non-motile spores like conidia, oidia and
endospores are formed.
Sexual Methods
Although sexes are not differentiated in bacteria, following methods of
genetic recombination are categorised under sexual reproduction in
bacteria.
l
Transformation F Griffith (1928), Genetic material of one
bacteria is transferred to other through conjugation tube.
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Biological Classification 13
l Conjugation Lederberg and Tatum (1946), Transfer of genetic
material occurs through sex pili.
l Transduction Zinder and Lederberg (1952), Transfer of genetic
material occurs by bacteriophage.

Economic Importance of Bacteria
Economically, some bacteria are useful in producing various useful
substances like curd, cheese, antibiotics and vinegar, etc. While other
bacteria cause several chronic diseases in humans, plants and other
animals, etc.

Other Monerans
These are as follows
1. Mycoplasma
l It was discovered by Nocard and Roux in 1898. These are cell wall
less, aerobic and non-motile organisms. Due to the absence of cell wall
and pleomorphic nature, they are commonly called as jokers of living
world.
l
The mycoplasmas are also known as Pleuro Pneumonia Like
Organisms (PPLO). These are the smallest living cells, yet
discovered, can survive without oxygen and are typically about
0.1 µm in diameter.
Lipoprotein membrane
(3 layers)

Ribosomes

DNA

Soluble RNA

Structure of Mycoplasma

2. Actinomycetes
l
The members of a heterogeneous group of Gram-positive, are
generally anaerobic bacteria noted for a filamentous and branching
growth pattern. It results in most forms in an extensive colony or
mycelium.
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14 Handbook of Biology

l Morphologically, they resemble fungi because of their elongated cells
that branch into filaments or hyphae. During the process of
composting, mainly thermophilic and thermotolerent Actinomyces
are responsible for the decomposition of the organic matter at
elevated temperature.
l Generally, Actinomycetes grow on fresh substrates more slowly than
other bacteria and fungi. During the composting process, the
Actinomycetes degrade natural substances such as chitin or
cellulose.
l Natural habitats of thermophilic Actinomycetes are silos, corn mills,
air conditioning systems and closed stables. Some Actinomycetes are
found responsible for allergic symptoms in the respiratory tract,
e.g., Extrinsic Allergic Alveolitis (EAA).
3. Cyanobacteria/Blue-Green Algae (BGA)
l They are Gram-negative photosynthetic prokaryotes which perform
oxygenic photosynthesis. These can live in both freshwater and
marine habitats and are responsible for ‘blooms’ in polluted water
(eutrophication).
l
They have photosynthetic pigments, chlorophyll-a, carotenoids
and phycobilins and food is stored in the form of cyanophycean
starch, lipid globule and protein granules.
l
Cyanobacteria have cell wall formed of peptidoglycan, naked DNA,
70S ribosomes and the absence of membrane bound organelles like
endoplasmic reticulum, mitochondria, Golgi bodies, etc.
l
The red sea is named after the colouration provided by red coloured
cyanobacteria i.e., Trichodesmium erythraeum.
l
Cyanobacteria can fix atmospheric nitrogen through a specific
structure called heterocyst. These are modified cells in which
photosystem-II is absent hence, non-cyclic photophosphorylation
does not take place. Nitrogen-fixation is performed through enzyme
nitrogenase, present in it.
4. Rickettsia
l
These are small, aerobic and Gram-negative bacteria. They belong to
phylum–Proteobacteria, which are capable of growing in low level of
nutrients and have long generation time relative to other
Gram-negative bacteria.
l
Rocky Mountain Spotted Fever (RMSF) is a tick borne human
disease caused by Rickettsia rickettsii, an obligate, intracellular
bacteria.
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Biological Classification 15
B. Kingdom–Protista (Eukaryotic, Unicellular Organisms)
It includes three broad groups, explained in the following flow chart
Kingdom–Protista

Plant-like Protists Fungi-like Protists Animal-like Protists
(photosynthetic (slime moulds) (protozoans)
protists) Subphyla
Subphyla
Amoeboid Sporozoans
Protozoans Flagellated Ciliated
Pyrophyta Chrysophyta Euglenophyta Protozoans Protozoans
(dinoflagellates) (diatoms) (euglenoids flagellates)
Subphyla

Myxomycota Acrasiomycota
(acellular slime (cellular slime
moulds) moulds)

In the view of evolution, the kingdom–Protista acts as a connecting
link between the prokaryotic kingdom–Monera and multicellular
kingdoms like Fungi, Plantae and Animalia. The term ‘Protista’ was
given by German biologist, Ernst Haeckel in 1866.
The group Protista shows following characteristics in common
(i) These are mostly aquatic.
(ii) Eukaryotic cell of protists possess well-defined nucleus.
(iii) Membrane bound organelles present.
(iv) Protists reproduce both asexually and sexually by a process
involving cell fusion and zygote formation.
(v) They may be autotrophic and heterotrophic (i.e., parasitic).
The detailed descriptions of protistan groups are as follows

Plant-like Protists (Photosynthetic)
These can be
1. Dinoflagellates
The group of 1000 species of photosynthetic protists, belongs to the
division–Pyrophyta and class–Dinophyceae. They are unicellular,
motile and biflagellate, golden-brown coloured protists. They form the
important components of phytoplanktons.
Their macronuclei possess condensed chromosomes, even in
interphase, called as mesokaryon (Dodge; 1966). Sometimes they
exhibit the phenomenon of bioluminescence.
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16 Handbook of Biology

2. Chrysophytes
These include diatoms and desmids. Diatoms are mostly aquatic
and sometimes present in moist terrestrial habitat. They are very
good pollution indicator.
The diatoms do not decay easily as their body is covered by siliceous
shell. They pile up at the bottom of water body and form diatomite or
diatomaceous earth (can be used as fuel after mining).
3. Euglenoids
These are Euglena like unicellular flagellates found mostly in stagnant
freshwater. Instead of a cell wall, they have a protein rich layer called
pellicle, which makes their body flexible.
They have two types of flagella
(i) Long Whiplash
(ii) Short Tinsel
The food is stored in proteinaceous granules called pyrenoids.
Photosynthetic euglenoids, behave like heterotrophs in dark, this mode
of nutrition is called mixotrophic.
The chief member of this group, i.e., Euglena is regarded as connecting
link between animals and plants.

Fungi-Like Protists (Slime Moulds)
They possess the characters of both animals and fungi therefore,
combinedly called as fungus-animals. They show saprophytic food
habit and consume organic matter. Under suitable conditions, they
form Plasmodium. On the basis of occurrence of Plasmodium, these are
of two types
(i) Acellular/Plasmodial slime moulds, e.g., Physarum, Fuligo
septica, etc.
(ii) Cellular slime moulds, e.g., Dictyostelium, Polysphondylium, etc.

Animal-Like Protists (Protozoans)
The most primitive relatives of animals, protozoans are heterotrophic
(predator or parasitic) organisms, divided into four major groups
(i) Amoeboid protozoans They live in freshwater, moist soil
and salt water as parasite. They move with the help of
pseudopodia as in Amoeba.
Other members of this group are
Entamoeba histolytica and E. gingivalis cause various digestive
and oral diseases when engulfed through polluted water.
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Biological Classification 17
(ii) Flagellated protozoans They are either free-living or
parasitic in nature. Chief members are
(a) Trypanosoma sp.–carried by tse-tse fly and causes African
sleeping sickness.
(b) Leishmania sp. carried by sand fly and causes kala-azar or
dum-dum fever.
(c) Giardia sp. causes giardiasis.
(d) Trichomonas vaginalis causes leucorrhoea.
(iii) Ciliated protozoans They are aquatic and move actively due
to the presence of cilia. They show nuclear dimorphism (macro
and micronucleus), e.g., Paramecium, etc.
(a) Macronucleus/Vegetative nucleus Controls metabolic
activities and growth.
(b) Micronucleus/ReproductivenucleusControls reproduction.
(iv) Sporozoans They have an infectious, spore-like stage in their
life cycle. All are endoparasites. Locomotory organs are cilia,
flagella and pseudopodia, e.g., Plasmodium, Monocystis, etc.

C. Kingdom–Fungi (Eukaryotic, Heterotrophic Organisms)
Fungi are a group of eukaryotic, achlorophyllous, non-photosynthetic
and heterotrophic organisms.
The basic features of fungi include
(i) Fungi lack chlorophyll, hence they are heterotrophic.
(ii) They cannot ingest solid food, but absorb it after digestion.
The digestive enzymes are secreted on food, then they (fungi)
absorb it.
(iii) On the basis of food sources, they may be saprophyte or
parasites. Cell wall in fungi is made up of nitrogen containing
polysaccharides, chitin. Reserved food material is glycogen or
oil. Along with certain bacteria, saprotrophic fungi function as
the main decomposers of organic remains.
With the exception of yeasts (unicellular, fungi and filamentous), fungi
bodies consist of long, slender, thread-like structures called hyphae.
Mycelium is the network of hyphae. Some are called coenocytic hyphae
(continuous tubes filled with multinucleated cytoplasm) and others
have cross walls (septae) in their hyphae. Cell walls of fungi are
composed of chitin and polysaccharides.
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18 Handbook of Biology

Classification of Fungi (Martin; 1961)
Fungi

Myxomycetes Eumycetes
(body as amoeboid (unicellular, multicellular,
naked protoplast) filamentous)

Phycomycetes Ascomycetes Deuteromycetes Basidiomycetes
(mycelium aseptate and (mycelium septate) (mycelium septate) (septate)
multinucleate) l Known as sac fungi, l Known as imperfect l Grow in soil, on logs
l Members are found mostly multicellular fungi. and in living plant
in aquatic habitats; (Penicillium) or rarely l Deuteromycetes bodies.
decaying wood in unicellular (yeast). reproduce only by l Reproduce
damp places. l Asexual spores are asexual spores, vegetatively by
l Reproduce asexually conidia produced on conidia. fragmentation, sex
by zoospores or conidiophores. e.g., Synchytrium, organs are absent.
aplanospores. l Sexual spores are Aspergillus, etc. e.g.,Agaricus, etc
e.g., Allomyces and ascospores
Puccinia, etc. produced on asci.
e.g., Albugo, etc.

Reproduction in Fungi
Three types of reproduction occur in fungi
Reproduction

Vegetative Asexual Sexual
When a vegetative structure During asexual reproduction, In sexual reproduction, the
after separation produces several mononucleate and fusion of compatible nuclei
new individual, it is called binucleate spores are takes place. It involves three
vegetative reproduction. produced which later steps, plasmogamy,
It occurs by following germinate into new individuals. karyogamy and meiosis.
processes It occurs by following methods It occurs by following methods

Fragmentation Zoospore Planogametic copulation
Budding Sporangiospore (Phycomycetes) Gametangial contact
Fission Chlamydospore Gametangial copulation
Sclerotia Oidia Spermatogamy
Rhizomorphs Conidia Somatogamy
Ascospore (Ascomycetes)
Basidiospore (Basidiomycetes)
Binucleate spore
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Biological Classification 19
Life Cycles of Some Fungi
These can be described as follows
(i) Life Cycle of Rhizopus
The structural representation (sexual and asexual) of life cycle of
Rhizopus is as follows

Fragmentation
Vegetative
Reproduction

Sporangium

Chlamydospore

Oidia

Asexual
Reproduction

Rhizopus
mycelia

Sexual Progametangium(–)
Germ spores Reproduction
(+ or –) Progametangium
(+)
Gametangium (–)
Germ sporangium
Gametangium
Haplophase (n) (+)
Coenogamete (–)
Promycelium
Coenogamete

+
Azygospore
Meiosis Fertilisation
Diplophase (2n)

Zygospore

Life cycle of Rhizopus
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20 Handbook of Biology

(ii) Life Cycle of Yeast
The diagrammatic representation of sexual cycle of Saccharomyces
cerevisiae is as follows

Dwarf strain
yeast cells B
Budding +
C +
A
Gametangia

–
Germinate
–
Plasmogamy

L Ascospore
D
Karyogamy
n) ase

Ascospores
h
op

Mature
pl

e
(2 has
(
Ha

ascus Zygote
op
n)
pl

E
Di

K
Young Germination
ascus
Large strain
yeast cell

Ascus mother F
J
cell
Meiosis Bud

G Budding
I
H

Life cycle of Saccharomyces cerevisiae

Heterothallism
The phenomenon of having two genetically different and compatible
sexual strains in two different thalli is called heterothallism. It was
discovered by Blakeslee in Mucor.
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Biological Classification 21
Mushroom and Fairy Rings
Agaricus compestris is an edible mushroom. It is also called white
button mushroom. The fruiting body of Agaricus, arises in concentric
rings (called fairy rings or fungal flowers) from the mycelium present
in the soil.
Lichens
They have composite structure and consist of two dissimilar organisms
forming a symbiotic relationship between them.
Lichens are formed by
l Algal Part — Phycobiont — Provide food to fungi
l Fungal part — Mycobiont — Provide shelter to algae
Lichens are of three types on the basis of their structure
(i) Crustose lichens These are point-like, flat lichens, e.g., Caloplaca.
(ii) Foliose lichens These lichens have leafy structure,
e.g., Hypogymnia physodes.
(iii) Fruticose lichens These are branched lichen, form filamentous
branching, e.g., Cladonia evansii, Usnea australis, etc.
Various forms of lichens are given below
Fungal fructification

Parmella
Graphis Cora
(foliose)
(crustose) (foliose)
Attaching disc
Pendent
branches

Podetia
Early
foliose
part Cladonia
Fungal (fruticose)
Usnea fructification
(fruticose)
Forms of lichens

Mycorrhiza
It is a symbiotic association between a fungus and a plant. Plants
prepare organic food and supply them to fungus and in return, fungus
supplies water and mineral nutrients to plants.
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22 Handbook of Biology

D. Kingdom–Plantae (Eukaryotic, Chlorophyllous Organisms)
These are chlorophyllous and embryo forming organisms. Mostly
non-motile and function as the producers in ecosystem as they can fix
solar energy into chemical energy through the process of
photosynthesis. The cell wall in plants is cellulosic and stored food
material is in the form of starch.
A detailed account of plant kingdom is given in chapter 6.

E. Kingdom–Animalia (Multicellular, Eukaryotic Organisms)
The heterotrophic, eukaryotic organisms which are multicellular and
lack cell wall, present in this kingdom. Animals have advanced level of
tissue organisation, in which the division of labour is highly specific.
The two main groups among animals are Non-chordata and Chordata,
divided on the basis of the presence of notochord in them.
A detailed account of animal kingdom is given in chapter 7.
Viruses and Viroids
1. Viruses
The term ‘Virus’ means poisonous fluid. The word was coined by
Louis Pasteur. Viruses are very small (0.05-0.2 µm), infective,
nucleoprotein particles, which can be called as living because of the
presence of nucleic acid as genetic material and ability to produce their
own copy-viruses. They show only some properties of living beings,
otherwise they behave like non-livings. Hence, these are referred to as
the connecting link between living and non-living.
On the basis of nature of genetic material, the viruses are of two types
(i) Adenovirus DNA containing, e.g., HIV, etc.
(ii) Retrovirus RNA containing, e.g., Rous sarcoma virus, etc.
On the basis of their host, the viruses can be categorised as
(i) Animal virus (Zoophagineae), e.g., HIV, sarcoma, etc.
(ii) Plant virus (Phytophagineae), e.g., TMV, etc.
(iii) Bacterial viruses (Phagineae), e.g., T4 phage, etc.
Characteristics of Viruses
Characteristics of viruses are as follows
Living
l
They can replicate.
l
In host body, they can synthesise protein.
l
They cause diseases like other living organisms.
l
Similar gene mutation as living organism.
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Biological Classification 23
Non-living
l Do not have protoplasm, and do not perform metabolism.
l These can be crystallised.
l They do not respire.
l In vitro culture is not possible.

Structure of Viruses
(i) Viruses are non-cellular and ultramicroscopic.
(ii) Virus has two components
(a) A core of nucleic acid called nucleoid.
(b) A protein coat called capsid.

Envelope, only in Capsomeres, together form
some larger viruses. capsid, a protein coat
usually highly symmetrical.
Genetic material, Core region
DNA or RNA inside capsid
Structure of a virus (generalised)

2. Viroids (RNA without a Capsid)
TO Diener (1917) introduced the term as ‘Subviral pathogens’. Viroids
are 100 times smaller than smallest virus. They are known to be
infectious for plants only (no animal), e.g., potato spindle tuber caused
by viroids.
Virion
An intact, inert, complete virus particle capable of infecting the host
lying outside the host cell in cell free environment is called virion.
Virusoids
These are like viroids, but located inside the protein coat of a true
virus. Virusoid RNA can be circular or linear. These are non-infectious
as they are replicated only in their host.
Prions/Slow Virus
The prions are smallest, proteinaceous infectious particles, i.e., disease
causing agents that can be transmitted from one animal to another.
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3
Plant Kingdom
Plants : Producers of the Ecosystem
Plants are multicellular, photoautotrophic and embryo forming
(excluding algae) organisms placed in kingdom–Plantae. They have
cell wall, which is made up of cellulose and reserve food material in the
form of starch (sometimes fat as in seeds).
Plants are referred to as producers, because they have unique ability to
fix solar energy in the form of chemical energy, through the process of
photosynthesis. They supply the energy in ecosystem to other living
organisms, hence they are referred to as producers.
The plant kingdom is classified as
Plant Kingdom

Cryptogamae (non-flowering) Phanerogamae (flowering)

Thallophyta
(plant body is not divided Gymnosperms Angiosperms
into root, stem and leaves) (naked seeded plants) (covered seed)

Algae Bryophyta Pteridophyta
(non-embryophytes, (these are (these are embryo Monocotyledons Dicotyledons
lack seeds and embryophytes bearing plants which
vascular tissue.) without vascular form seed and contain
tissues.) vascular tissue as well.)

Ferns
Liverworts Hornworts Mosses

Algae (L. Alga–sea weeds)
These are eukaryotic, autotrophic (holophytic), chlorophyll containing,
non-vascular thallophytes. These are characterised by the absence of
embryonic stage and presence of non-jacketed gametangia. Mostly,
they are of aquatic habitat (both freshwater and marine).
The branch of Botany which deals with the study of algae is termed as
‘Algology or Phycology’. FE Fritsch is known as ‘Father of Algology’.
(Prof. MOP Iyengar is regarded as Father of Indian Algology).
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Plant Kingdom 25
Classification of Algae (FE Fritsch; 1935)
Algal Class Colour Reserve Food Examples
Chlorophyceae Grass green Starch Chlamydomonas and
Spirogyra.
Xanthophyceae Yellow-green Fat Microspora and Botrydium.
Chrysophyceae Yellow-green and Carbohydrate and Amphipleura and
golden-brown leucosin Chrysosphaera.
Bacillariophyceae Brown and green Fat and volutin Pinnularia and Melosira.
Cryptophyceae Red and Carbohydrate and Cryptomonas.
green-blue starch
Dinophyceae Dark yellow, Starch and oil Peridinium and
brown-red Glenodinium.
Chloromonadineae Bright green Fatty compounds Vaucheria and Trentonia.
Euglenophyceae Grass green Paramylum Euglena and Phacus.
Phaeophyceae Brown coloured Laminarin and Laminaria and Fucus.
mannitol
Rhodophyceae Red coloured Floridean starch Polysiphonia and
Batrachospermum.
Myxophyceae Blue-green Protein granules Nostoc and Anabaena.

Characteristics of Algae
Important characteristics of algae are given below
Structure
Algae may be unicellular and multicellular.
1. Unicellular
It is of two types
(i) Motile, e.g., Chlamydomonas, etc.
(ii) Non-motile, e.g., Chlorella, etc.
2. Multicellular
It is of following types
(i) Colonial, e.g., Volvox, Hydrodictyon, etc.
(ii) Aggregation, e.g., Tetraspora, Prasinocladus, etc.
(iii) Filamentous, e.g., Ulothrix, Cladophora, etc.
(iv) Pseudoparenchymatous, e.g., Nemalion, etc.
(v) Siphonous, e.g., Vaucheria, etc.
(vi) Parenchymatous, e.g., Ulva, Fritschiella, etc.
(vii) Well-developed thallus, e.g., Chara, Sargassum, etc.
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26 Handbook of Biology

Nutrition
Mostly algae are autotrophic, due to the presence of chlorophyll. Some
are parasitic, e.g., Cephaleuros that causes rust of tea.

Reproduction
Algae reproduce by
(i) Vegetative methods
(ii) Asexual methods
(iii) Sexual methods
Vegetative Reproduction
Algae reproduce vegetatively by two methods
(i) Fragmentation, e.g., Fucus, Chara, etc.
(ii) By hormogones, e.g., Oscillatoria, Nostoc, etc.
Asexual Reproduction
In this process, some cells form motile or non-motile spores. After
release, these spores give rise to new plants. Following spores are
involved
(i) By zoospore, e.g., Ulothrix, Oedogonium, etc.
(ii) By aplanospore, e.g., Chlorella, etc.
(iii) By hypnospore, e.g., Vaucheria, etc.
(iv) By palmella stage, e.g., Chlamydomonas, Ulothrix, etc.
(v) By endospore, e.g., Anabaena, Nostoc, etc.
(vi) By akinete, e.g., Chara, Oedogonium, etc.
Sexual Reproduction
On the basis of shape, size, morphology and behaviour of gametes,
the sexual reproduction is of following types
Sexual Reproduction

Isogamous Anisogamous Oogamous
(similar gametes, (gametes are dissimilar (gametes are different
morphologically), morphologically), both morphologically and
e.g., Spirogyra. e.g., Chlamydomonas sp. physiologically),
e.g.,Volvox.
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Plant Kingdom 27
Life Cycle of Algae
Various algae show different types of life cycles. Life cycles of
Spirogyra and Ulothrix are discussed here.
Life cycle of Spirogyra It is a green alga of filamentous shape.
The detailed life cycle is given below.
Aplanospore
Azygospore
Akinete
Asexual reproduction

Chloroplast
Cytoplasm
s
id Nucleus
11 e no
r
10 Py all
ll w 1
Ce
Vegetative cell
Vegetative
filament
Three degenerating nuclei
2
9 Functional Sexual reproduction
nucleus
Haploid phase (n)
Four haploid nuclei

8
Conjugation
Male tube
Diploid gamete
phase (2n) (n ) Female 3
7 gamete
at m

(n)
ug o r
n
io
nj rif
co cala
S
)
o sis
ei

Zygote (2n)
(M

6
5
Zygospore (2n) 4

Life cycle of Spirogyra
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28 Handbook of Biology

Life cycle of Ulothrix The diagrammatic representation of life cycle
of Ulothrix is given below.
Palmella stage
Akinete
Hypnospore
Macrozoospores
Microzoospore
Aplanospore
Asexual reproduction

15

Chloroplast
14
Hold Nucleus
fast
1
Vacuole
Vegetative cell
Zoospores
13 Gametangium
2

12 Reduction division
Isogametes
Resting Vegetative
Zygospore (2n) filament 3
Phase (2n)
11 Sexual reproduction

Quariflagellate
10 zygospore Haploid phase (n)
+ 4
my
9 Synga
–
Vesicle

8
5

Liberations of 7 6
gametes

Life cycle of Ulothrix
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Plant Kingdom 29
Economic Importance
Algae can be both useful and harmful. Several useful algal species with
their uses are mentioned here
As Food As Medicine
Ulva, Sargassum, Laminaria, Chlorella gives chlorellin
Porphyra, Nostoc and Laurencia. (antibiotic), Nitella is used
as mosquito repellent.

In Industries Algae Source of Minerals
Diatoms, Chondrus, Laminaria, Polysiphonia and
Polysiphonia, Gracilaria Ascophyllum are used in
are used in paints, cosmetics, etc. extraction of minerals.

In Agriculture In Biological Research
Nostoc, Anabaena, help in Chlorella,Scenedesmus and
nitrogen-fixation, hence Acetabularia are used as tools
used as biofertilisers. for biological research.
Ecological Significance
Algae like planktons are used as
food by others and stabilise
the ecosystem.
Useful applications of algae

Algin, Carrageenan and Agar
l
Algin, used as artificial fibre to control blood flow in surgery and
in production of non-inflammable films, is extracted from marine
brown algae.
l
Carrageenan, extracted from seaweeds is used in cosmetics, boot
polish, ice cream, paints, etc.
l
Agar, extracted from Gelidium and Gracilaria is used in culture
medium, biscuits for diabetic patients, etc.
– Sargassum is used as food and fodder.
– Laminaria, Fucus are used in extraction of iodine, bromine and
potash.
Harmful Algae
Group of algae like Microcystis, Oscillatoria and Anabaena cause water
blooms (eutrophication) and death and reduction of aquatic organisms.

Bryophyta (L. Bryon–leaf-like; phyton–plant body)
It is the simplest and primitive group of land plants. They are also
known as amphibians of plant kingdom because of their habitat
adaptability in both aquatic and terrestrial environment. They are the
connecting link between algae and pteridophytes. Bryophytes
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30 Handbook of Biology

are autotrophic, non-seeded, cryptogamic plants. The plant body is
gametophytic and may be differentiated into stem, leaves and rhizoids.
l Bryophytes do not have true vascular tissue (xylem and phloem),
but some of them have hydroids (similar to xylem) and leptoids
(similar to phloem) which help in the conduction of water and food,
respectively.
l The sex organs in bryophytes are multicellular, male sex organ is
called antheridium and female sex organ is called archegonium.
Sexual reproduction in bryophytes is mainly oogamous type.

Classification of Bryophyta
Bryophyta (sub-division)
Classes

Hepaticopsida Anthocerotopsida Bryopsida
(Liverworts) (Hornworts) (Mosses)
l Plant body is thalloid l Plant body is thalloid l Primary gametophyte
or foliose. and dorsiventrally consists of prostate
l Cells have chloroplast flattened. or thalloid
without pyrenoids. l Sex organs protonema.
l Sporophyte simple or embedded in the l Adult gametophyte
differentiated into thallus tissue. consists of stem,
foot, seta and l Cells bear large spirally arranged
capsule. chloroplast with a leaves.
conspicuous l Sex organs develop
pyrenoid. from superficial cells.
Order
Orders
Anthocerotales
e.g., Anthoceros
Orders Bryales Sphagnales
e.g., Funaria and e.g.,Sphagnum.
Sphaerocarpales Jungermaniales Polytrichum.
e.g.,Sphaerocarpus. e.g., Porella

Marchantiales Calobryales
e.g., Marchantia and e.g., Calobryum.
Riccia.

Reproduction in Bryophytes
Bryophytes reproduce by both vegetative and sexual methods of
reproduction.
Vegetative Reproduction
Following methods of vegetative reproduction are reported in bryophytes
(i) By fragmentation The two fragments resulted by progressive
death and decay of thallus, produce new thallus, e.g., Riccia.
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Plant Kingdom 31
(ii) By adventitious branches Special adventitious branches
arise from the mid-ventral surface of the thallus, e.g., Riccia
fluitans.
(iii) By tubers Some species form perennating tubers at the apices
of thallus, e.g., Riccia, Marchantia, etc.
(iv) By persistent apices The underground part of thallus in soil
remains living and grows into plant, e.g., Riccia, Pellia, etc.
Sexual Reproduction
The sex organs are highly differentiated and well-developed in
bryophytes. The antherozoids or sperms (minute, slender, curved
body, having two whiplash flagella) are released from antheridium and
reach to archegonium through neck canal cells. The antherozoid fuses
with egg cell to produce sporophytic generation.

Life Cycle of Bryophytes
A typical bryophyte shows following type of life cycle

Vegetative
reproduction
(n)

Bryophyte
(n)
Protonema (n)
Male (n)
Female
Spores (n) Sexual (n)
Reproduction Antheridium (n)
Meiosis (R/D) Archegonium
(n)
Ga
me
Sp t op
Spore hyt Antherozoid (n)
mother cell (2n) oro e(
ph n) Egg (n)
yte
(2n
)
Sporogonium (2n) Fertilisation
(syngamy)

Embryo (2n)

Zygote (2n)

Graphic representation of the life cycle of bryophyte
(R/D refers to reductional division)
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32 Handbook of Biology

Economic Importance
Bryophytes have limited economic importance, they can be used in
following ways
(i) They help in soil formation (pedogenesis) and act as agent
for biological succession.
(ii) Peat from Sphagnum can be used as fuel and in preparation of
ethyl alcohol.
(iii) They help in protecting soil from erosion.
(iv) Some bryophytes are used as fodder for cattle.
(v) Due to high water retention capacity, Sphagnum can be
used in preserving living materials and used in grafting of
plants.

Pteridophyta ( L. pteron–feather; phyton–plant)
Pteridophytes are seedless, vascular cryptogams. They reproduce by
means of spores and can reach to the tree-like heights (30-40 feets).

General Characteristics
(i) The plant body is differentiated into root, stem and leaves.
(ii) The stem may be aerial or underground and is generally
herbaceous, rarely solid and stout.
(iii) Vascular tissues consist of xylem (without vessels) and phloem
(without companion cells).
(iv) Alternation of generations is found here, gametophyte is
autotrophic and independent.
(v) Sporangia containing leaves are called sporophylls.
(vi) Antherozoids (flagellated male gametes) are formed in
antheridia.
(vii) Reproduction is of both vegetative and sexual types.
(viii) On the basis of development of sporangia, they are of two
types
(a) Eusporangiate From a group of superficial initial cells.
(b) Leptosporangiate From a single superficial initial cell.
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Plant Kingdom 33
Stelar System in Pteridophytes
Stele is central vascular tissue surrounded by cortex. It is of two types

Protostele Siphonostele
Pericycle
Endodermis Xylem Phloem
Phloem
Endodermis
Xylem

Leaf trace
Leaf trace Pith
Xylem in centre is surrounded Xylem surrounds the central pith.
by phlem e.g., Selaginella. Phloem is outside to xylem, e.g., Pteridium.
Endodermis Leaf trace
Endodermis
Pericycle Pericycle
Phloem Phloem Pith
Xylem
Xylem
Leaf gap
Haplostele Ectophloic Solenostele
Central xylem core Xylem is like hollow cylinder surrounded
surrounded by phloem by phloem e.g., Equisetum
e.g., Rhynia

Outer endodermis
Endodermis Outer pericycle
Pericycle Outer phloem
Phloem Leaf trace
Xylem
Xylem Inner pericycle Leaf gap
Inner endodermis
Actinostele
Central xylem core is star-shaped Amphiphloic Solenostele
phloem is patchy outer Hollow xylem cylinder has phloem on both
to xylem, e.g., Lycopodium. outer and inner side of xylem, e.g., Marsilea

Classification of Pteridophyta
(Smith; 1955, Bold; 1955-57, Benson; 1957)
Division–Pteridophyta
Sub-division

Psilophyta Lycophyta or Sphenophyta or Filicophyta or
(rootless Lepidophyta Arthrophyta Pterophyta
sporophytes). (differentiated (foliage leaves (sporophyll
sporophytes are borne in contains sori
contain strobili). transverse e.g., ferns).
whorls, e.g., horse
tails).
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34 Handbook of Biology

Reproduction
Pteridophytes reproduce by vegetative, asexual and sexual methods.
Vegetative Reproduction
It takes place by two methods
(i) Death and decay of older tissues lead to separation of new
branches, which can grow into new plants.
(ii) Adventitious buds develop from petiole and later on rooting
takes place and get separated.
Asexual Reproduction
It occurs by meiospores
When pteridophytic plants get mature, the special spore bearing
structures develop under the surface of pinnules.
These structures are
(i) Sporangium These are differentiated into capsule and the
stalk. Capsule has a single layer of thick wall, which consists of
specialised cell along with the normal wall cells.
(ii) Spores These are minute, bilateral bodies of brown
colour. The spore coat is two layered, i.e., thick exine and thin
intine.
Sexual Reproduction
It is of advanced type, in which the multicellular sex organs
(i.e., antheridia and archegonia) are borne on the underside of
prothallus. The mucilaginous substance oozes out from archegonia,
which contains malic acid. After diffusing into water, it attracts
antherozoids through chemotaxis. The male nucleus fuses with the
egg nucleus and forms zygote.
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Plant Kingdom 35
Life Cycle of Pteridophytes
Most pteridophytic plants show similar type of life cycle.
Which is diagrammatically represented below.
Mesophyll
Upper epidermis
Circinate
Lower epidermis
leaf
Sporangia
(stalked)
Placenta Covering by
Sori Strobilus indusium
Stalk
Part of sporophyll
Leaflet Rhizome with with sori
mesarch xylem
Stomium
Sporophytic Roots with diarch
plant condition of xylem Spores
Sporangium
First leaf
Prothallus with
autotrophic
Rhizoids
nutrition
Apicol Notch
Sporophytic
Rhizoids phase
ytic
Germinating
2n ph Cushion
to spore
n me e
a
G has Apical notch
p
Antheridia Archegonium
Antheridia
Antherozoids
Cilia
Rhizoids

Prothallus with
Egg archegonia and
A single Neck antheridia
antherozoids Archegonium

Life cycle of Dryopteris

Heterospory in Pteridophytes
In heterosporous