Animal diversity and classification

Biodiversity
The word Biodiversity is formed from the Greek word Bios meaning life and diversity. Biodiversity is the variety of living organisms. The difference or variety seen in all organisms living in a particular environment at a particular time is called biodiversity. In 1986 scientist Walter G. Rosen first used the term Biodiversity. There are three types of biodiversity. Dr. Siddiq Publications
1. Genetics diversity: The genetic differences or variations seen in different plants or animals belonging to the same species are called genetic biodiversity or genetic diversity. It is also called intraspecific variation. Inbreeding occurs between members of these species. Species with greater genetic diversity also have greater adaptive capacity. If a gene is susceptible to a disease, it is passed down from generation to generation. Although humans are of the same species (Homo sapien), there are many differences in size, shape, skin color, hair color etc. due to genetic reasons. Genetic variation occurs due to allelic variation of genes in species. New alleles of genes can be created due to mutation. Siddique Publications
Importance of genetic diversity
(i) Greater variation occurs when a species has more genetic variation. As a result, it helps the organism to survive in the changing environment.
(ii) Genetic variation leads to variety of physical characteristics in organisms. So survival and adaptability in nature increases.Dr. Siddiq Publications
(iii) Genetic diversity reduces the re-emergence of hereditary unwanted traits.
(iv) Organisms with low genetic diversity are always under threat.
(v) Genetic diversity helps in resistance to parasites, pests and diseases.
(vi) Genetic diversity protects species from extinction. Because it has survival properties. Dr. Siddiq Publications
2. Species diversity: The difference between two or more species of plants or animals is called species diversity. It is also called interspecific diversity. The main components of species diversity are two. (species richness) and species evenness. The role that species play in the ecosystem is called ecological niche. Areas where species diversity is high are considered biodiversity hotspots. Species diversity is higher in regions where nutrients and climate are favorable. For example, tropical regions.
Measurement of species diversity
Animal species diversity is measured by species diversity index. The most commonly used index to measure species diversity is Simpson’s Diversity Index. It is expressed by D = ∑(n/N)2. n is the number of a particular animal species, N is the sum of all animal species and D is the value of animal diversity. The value of D ranges from 0-1. The higher the value of D at a site, the greater the animal diversity. In 1990, scientist Norman Myer (1990) called the world’s biodiversity hot spot. Dr. Siddiq Publications
Importance of species diversity
(i) Species diversity drives energy capture and storage, biomass production and decomposition, and water and nutrient cycling in ecosystems.
(ii) Species diversity increases the productivity of ecosystems.
(iii) Species diversity prevents soil erosion and pest control.
(iv) Species diversity controls the amount of gaseous substances in the atmosphere.
3. Ecosystem diversity: The environmental or ecological differences or differences between different types of organisms are called ecological diversity or ecosystem diversity. Ecological diversity arises when the physical, biological and chemical components of the natural environment change. For example, desert biome, forest biome, grassland biome, tundra biome etc.
Importance of species diversity
(i) Ecological diversity leads to decomposition of waste materials and increases soil fertility.Dr. Siddiq Publications
(ii) Ecological diversity controls plant pollination and predators.
(iii) Ecological diversity regulates productivity and stress tolerance. Siddiq Publications
(iv) Ecological diversity provides essential raw materials for the ecosystem.

Data deficient
Species for which there is no scientific data are called data deficient species. For example – Guilya Tangra – Mystus gulio

Hot spots
Areas rich in biodiversity are called hotspots. For example, the Indo-Burma hotspot. Bangladesh’s Sylhet, Chittagong and Hill Chittagong belong to the Indo-Burma hotspot.

Species
A group of organisms that are physically most similar and capable of producing fertile offspring through sexual intercourse among themselves, but unable to produce fertile offspring through sexual intercourse with other groups, is called a species. John Ray first used the term species in 1686.
Characteristics of species
1. Each species has unique characteristics.
2. A species is the darkness of a gene pool.
3. Always trying to adapt to the environment.
4. They exchange genes with each other.
5. They have the ability to create new species.
6. Members of the same species have the most characteristics

Methods of species identification
1. Common Descent: All members of a species naturally descend from a common ancestor. Dr. Siddiq Publications
2. Specific and Smallest Group of Organisms: Species is the smallest and specific group of organisms in the light of morphological and chromosomal characteristics.
3. Mode of Reproduction: Species are capable of producing fertile offspring by sexual intercourse among themselves. Dr. Siddiq Publications
4. Ecological niche: Each species has a specific ecological niche.
5. Genetic unit: A species is the darkness of a gene pool.
Base of Animal Classification
The characteristics on the basis of which organisms are classified are called taxonomic bases. The Greek philosopher Aristotle divided red-blooded animals into two groups called Enaima and non-red-blooded animals. Enaima is divided into two parts. Ovaries and uterus. The main basis of classification is-
1. Number of Cells
(i) Unicellular Animal: They are protocellular and their body is made up of only one cell. Protozoa are unicellular organisms. Such as Amoeba (Amoeba proteus), Malaria parasite (Plasmodium vivax), Entamoeba histolytica etc.
(ii) Multicellular Animal: They are true cells and their body is made up of multiple cells. Animals of the order Metazoa, Porifera and Chordata are multicellular. Such as Hydra- (Hydra vulgaris), Ilisha (Tenualosa ilisha), Doel (Copsychus saularis) etc.
2. Body Shape
(i) Micro animal: Those animals which are very small and microscopic are called Micro animals. For example, malaria bacteria (Plasmodium vivax), dysentery bacteria (Entamoeba histolytica) etc.
(ii) Macro animal: Those animals which are large in size and can be seen with the naked eye are called macro animals. For example, guinea pig (Cavia porcellus), Indian elephant (Elephas indicus), blue whale (Balaenoptera musculus) etc.
3. Levels of organization
(i) Cell level structure: The body structure in which some cells combine to perform specific functions is called cellular level structure. Cells perform reproductive functions, nutrient collection, metabolism etc. For example, Porifera animals.
(ii) Cell-planar structure: The structure in which some similar cells are arranged in a specific layer to form a tissue is called cell-planar structure. E.g. Cnidaria animals. Dr. Siddiq Publications
(iii) Organ-level structure: The body structure in which multiple tissues combine to form organs is called organ-level structure. E.g. Platyhelminthes.
(iv) Structure of organ-tantra level: The body structure in which more than one organ forms a system is called structure of organ-tantra level. Such structures first appeared in Nemertean sea creatures. Such as Nematoda, Annelida, Mollusca, Arthropoda, Echinodermata and Chordata.
4. Way of living
(i) Free living: Animals that move freely. For example – pigeon, cow
(ii) Parasite: Those organisms which live in the body of another organism and take food from it are called parasites. For example, worms, lice etc. (iii) Symbiont: When two different species live together and benefit both, it is called symbiont. For example – Chlorohydra viridissima and Zoochlorella.
(iv) Commensal: Two different species of organisms living together are called symbionts, neither benefiting nor being harmed by the other. For example, the sucking fish called Remora shows symbiosis by attaching to the body of Shark or any other fish.
5. Embryo layer
After fertilization the zygote divides by cleavage process to form blastomere. Blastomere cells are arranged to form a distinct morula. Later the cells of the morula dasa give rise to the hollow blastula. Blastula cells develop into bilayer or trilayer gastrula. Scientist Heinz Christian Pander discovered the embryonic layer. Multicellular organisms are divided into two groups based on the embryonic stage.
(i) Diploblastic animal: Those animals which have two layers in the embryo are called diploblastic animals. Their embryos have two layers called ectoderm and endoderm. Between the ectoderm and endoderm is an acellular layer called mesogia. Animals in the order Cnidaria are bivalves. Such as Hydra (Hydra vulgaris), Jellyfish (Aurelia aurita), Obelia (Obelia geniculata) etc.
(ii) Triploblastic animals: Animals which have three layers in their embryo are called triploblastic animals. The outer layer is the ectoderm, the middle layer is the mesoderm and the inner layer is the endoderm. The order Platyhelminthes, Nematoda, Mollusca, Annelida, Arthropoda, Echinodermata and Chordata are phyla.
6. Notochord
(i) None chordata: Those animals which do not have notochord are called non-chordata. Protozoa, Metazoa, Porifera, Cnidaria, Platyhelminthes, Nematoda, Mollusca, Annelida, Arthropoda I Echinodermata are non-chordata. Such as Hydra (Hydra vulgaris), cockroach (Periplaneta americana), tapeworm (Taenia solium), snail (Pila globosa), sea star (Asterias rubens) etc.
(ii) Chordata: All animals which have notochord in their body are called Chordata. All animals in the order Chordata have notochords. Animals in the order Chordata are divided into three suborders.
• Urochordata: Urochordata only have a notochord in the tail region in the larval stage. E.g. Ascidia.
• Cephalochordata: In Cephalochordata the notochord extends from the apex of the head to the caudal region. Their notochord remains for life. For example, Branchiostoma.
• Vertebrata: In vertebrates the notochord is replaced by the spinal cord. E.g. Ascidia.

7. Vertebral column
(i) Invertebrate: Those animals which do not have backbone are called invertebrates. Protozoa, Metazoa, Porifera, Cnidaria, Platyhelminthes, Nematoda, Mollusca, Annelida, Arthropoda I Echinodermata are invertebrates. For example – snail (Pila globosa), fly (Musca domestica), earthworm (Metaphire posthuma) etc.
(ii) Vertebrate: All the animals which have backbone in their body are called vertebrates. Animals in the order Chordata are vertebrates. For example, lion (Panthera leo), tiger (Panthera tigris), cow (Naja naja), cow (Bos indicus) etc.
8. Symmetry
Balanced distribution of different parts of the body is called symmetry.
(i) Asymmetry: If the body of an animal is not divided into two equal parts along the center or axis, it is called asymmetric. For example – Snail (Pila globosa), Amoeba (Amoeba proteus), Spongilla (Spongilla proliferens), Sponge (Cliona celata) etc.
(ii) Bilaterally symmetrical: When the body of an animal is divided along the center into two equal parts, it is called bilaterally symmetrical. Their taxonomic level is Bilateria. Animals of the order Platyhelminthes, Arthropoda I Chordata are bilaterally symmetrical. For example, humans (Homo sapiens), cockroaches (Periplaneta americana), frogs (Duttaphrynus melanostictus), butterflies (Pieris brassicae), Inlish (Tenualosa ilisha), pigeons (Columba livia), liver worms (Fasciola hepatica) etc.
(iii) Biradial symmetrical: If the body of an animal is divided longitudinally along the axis to get two equal parts, it is called biradial symmetrical. In this case four equal parts are obtained as the cutting planes are at right angles. Such symmetry is called Tetramerous symmetry. Such as Anthozoa, Ctenophora, Ceoloplana etc.
(iv) Radial symmetrical: If the body of an animal is divided along the center to get more than two equal parts, it is called radial symmetry. Their taxonomic level is radiata. Such as Hydra (Hydra vulgaris), Jelly fish (Aurelia aurita), Sea anemone (Metridium dianthus), Sea snake (Astropecten auranciacus).
(v) Spherical symmetry: If the body of an animal is divided repeatedly along the center and two equal parts are obtained each time, it is called spherical symmetry. Like Volvox globactor, Radiolaria (Acrosphaera trepanata), Haliozoa (Gymnosphaera albida) etc.
9. (Segmentation/Metamerism)
When the body of an organism is made up of similar parts, it is called fragmentation or metamerism. Each segment is called a metamere or somite.
(i) Asegment: Those animals which have no segmentation in their body are called non-segmented animals. Chordata are unsegmented animals. For example, humans (Homo sapiens), starfish (Asterias ruben) etc.
(ii) Homonomous metamere: Animals whose body is made up of similar segments are called homosegmented animals. Annelida is a group of animals. For example, earthworm (Metaphire posthuma), cockroach (Hirudinaria medicinalis) etc.
(iii) Heteronomous metamere: Those animals whose body is made up of unequal or different types of segments are called heteronomous animals. Animals of the order Arthropoda are unclassified. For example – cockroach (Periplaneta americana), Prajaprati (Pieris brassicae and Palilio krishna) etc.
10. Coelom
In animals, the body cavity between the alimentary canal and the body wall is covered by a membrane called peritoneum and filled with chyloemic juice. It arises from embryonic mesoderm. According to the nature of Siloam, animals can be divided into 4 categories.
(i) Acoelomate: Animals that do not have a coelom are called acoelomates. Their spaces are filled by spongy parenchyma cells. Animals of the order Porifera, Platyhelminthes, Cnidaria and Ctenophora are asilomates. For example – Tapeworm (Taenia solium), Hydra (Hydra viridis), Liverworm (Fasciola hepatica) etc.
(ii) Pseudocoelomate: The body cavity between alimentary canal and body wall is not covered by peritoneum in animals called pseudocoelomate. Animals of the order Nematoda, Rotifera, Acanthocephola, Ectoprocta and Kinorhyncha are pseudocylomates. Such as round worm (Ascaris lumbricoides), eye worm (Loa loa), hook worm (Ancylostoma duodenale) etc.
(iii) Coelomate: The body cavity between alimentary canal and body wall is covered by peritoneum in animals called coelomate. Animals belonging to the order Annelida, Arthropoda, Echinodermata, Mollusca, Hemichordata and Chordata are coelomates. Such as earthworm (Metaphire posthuma), human (Homo sapiens), mosquito (Culex pipiens), sea star (Asterias vulgare), hilsa (Tenualosa ilisha), oyster (Unio marginalis) etc.
Silom is divided into two parts based on embryonic development.
(i) Psyzocilous chyloem: The chyloem that arises from embryonic mesodermal tissue is called zygosylous chyloem. For example Annelida, Arthropoda and Mollusca.
(ii) Enterocillus chyloem: The chyloem arising from the embryonic mesodermal sac is called enterocylus chyloem. For example, Echinodermata and Chordata.
Importance of coelom
(i) Cells help in independent growth and movement of various organs.
(ii) It protects the various parts of the animal body from friction.
(iii) Siloam helps transport waste materials, nutrients and gaseous materials.
(iv) It acts as a hydrostatic skeleton during locomotion of the animal.
11. Alimentary canal
Animals are divided into two groups based on alimentary canal.
(i) Parazoa: All the animals which do not have alimentary canal are called Parazoa. Animals of the order Porifera are Parazoa. For example, Cycon (Scypha gelatinosum), Spongilla (Spongilla lacustris), Cliona (Cliona celata) etc.
(ii) Enterozoa: All organisms having alimentary canal are called Enterozoa. Enterozoa are animals of the order Annelida, Arthropoda, Nematoda, Platyhelminthes, Echinodermata, Cnidaria, Mollusca and Chordata. Asexual reproducers and sexual reproducers.
12. Reproductive characteristics
Animals are divided into 2 groups based on reproductive characteristics.
(i) Asexual reproducer: Those animals which do not have any specific reproductive organs and reproduce without the help of opposite sex are called asexual reproducers. Asexual reproduction is of three types. These are-
* Binary fission: The process in which an organism divides to produce two offspring is called bisegmentation. Such as Euglena (Euglena viridis), Hydra (Hydra vulgaris) etc.
* Multiple division: The process in which a single-celled organism divides repeatedly to produce numerous offspring is called multiple division. For example – Entamoeba histolytica, Paramecia (Paramecium caudatum) etc.
* Budding: The process by which new organisms are created by budding from the mother body is called budding. Such as Hydra (Hydray viridis).
(ii) Sexual reproducer: The process of reproduction through the union of sperm and egg of two animals of opposite sex of the same species is called sexual reproduction.
* Oviparous: The animals that lay fertilized or unfertilized eggs and the eggs hatch outside the mother’s body to develop into young animals are called oviparous. For example – fish, birds, snakes, poultry, turtles, frogs etc.
* Endo-viviparous: The animals that lay eggs and after fertilization the eggs develop in the mother’s womb and become babies are called endo-viviparous. For example, sharks, some amphibians etc.
* Viviparous: Those animals whose eggs are fertilized inside the mother’s body and the embryo receives nutrients from the mother’s body through immortality and develops into a full-fledged baby animal are called in utero. For example, mammals.
13. Tagmatization
The process by which the animal body is divided into larger segments or tagmas is called regionalization or tagmatization. Each region is called a tagma. The evolutionary process by which regionalization is accomplished is called tagmosis. The bodies of animals of the class Insecta of the order Arthropoda are divided into three tagmas. Head, thorax and abdomen. For example – grasshopper (Poekilocerux pictus).
14. Polarity
The polarization of the animal body based on the position of the head and mouth is called marginality. There are five types of limitations in the animal body.
(i) Anterior end: The end of the animal where the head is is called the anterior end. This is called the oral edge.
(ii) Posterior end: The end opposite to the head of the animal is called the posterior end. called the paraoral edge.
(iii) Dorsal end: The upper surface of the animal’s body is called the dorsal end.
(iv) Ventral end: The bottom of the animal’s body is called the ventral end.
(v) Lateral end: The bottom of both sides of the animal body is called lateral end.
15. Planes
The region along which the animal body can be divided into right and left or longitudinally and transversely or anteriorly and posteriorly is called floor. There are generally three types of floor in the animal body.
(i) Sagittal plane: The plane by which the body can be divided into right and left is called midline plane.
(ii) Frontal plane: The plane by which the animal body can be divided into digital and dorsal parts is called frontal plane.
(iii) Transverse plane: The plane by which the animal body can be divided into anterior and posterior parts is called transverse plane.
16. Cleavage and development
The process by which the zygote divides repeatedly to form a multicellular embryo is called cleavage. If the cleavage is complete it is called holoblastic and if it is partial it is called meroblastic. At the time of cleavage, the end of the egg containing the yolk is called the vegetative pole and the end containing the nucleus is called the animal pole.
Cleavage is of two types on the basis of swelling. These are-
(i) Indeterminate Cleavage: In embryonic development where every cell produced in the initial stage of cleavage has the capacity to form an embryo is called indeterminate cleavage.
(ii) Determinate cleavage: In embryonic development, the specific cells produced in the initial stage of cleavage possessing the ability to form an embryo is called determinate cleavage. Dr. Siddique Publications
Cleavage is of three types based on the cleavage plane. These are-
(i) Radial Cleavage: The cleavage process in which the cells of the zygote divide evenly and radially is called radial cleavage. Auricular cleavage occurs in animals of the order Arthropoda.
(ii) Bilateral cleavage: The process in which the zygote cleaves anteriorly up to the second cleavage and transversely along the midline from the third cleavage is called bilateral cleavage. This results in two rows of four cells each. Bilateral cleavage occurs in animals of the order Chordata.
(iii) Spiral Cleavage: After the anterior and transverse divisions of the zygote, during the third division, when the blastomeres of the animal pole change slightly with the blastomeres of the vegetal pole, it is called spiral cleavage. Spiral cleavage occurs in animals of the order Annelida and Mollusca.

Bilaterally symmetrical animals are divided into two groups based on cleavage and embryonic development.
(i) Protostomia: Cleavage in protostomia animals is spiral and definite. Their embryonic blastopore develops into a pore. Such as Annelida, Arthropoda and Mollusca.
(ii) Deuterostomia: Cleavage in Deuterostomia animals is spiral and indeterminate. Their embryonic blastopore develops into an anus. E.g. Echinodermata and Chordata.
17. Vascular system: The system through which water and blood flow is called circulatory system. Water is the main means of transportation for underdeveloped animals. Animals of the group Periphera have a vascular system and animals of the group Echinodermata have a water circulatory system. The main means of circulation in advanced animals is blood or liquid connective tissue. There are two types of circulatory system.
(i) Closed circulatory system: The circulatory system in which blood always flows through the vessels is called closed circulatory system. The circulatory system of animals of class Annelida and Chordata is closed type.
(ii) Open circulatory system: The circulatory system in which blood flows through different parts of the body is called open circulatory system. The circulatory system of Arthropoda and Mollusca animals is open type.
18. Skeleton
The system that structures the body, carries the weight of the body and preserves the body is called the skeleton. There are two types of skeletons.
(i) Exoskeleton: The skeleton that forms the outer structure of the body is called exoskeleton. Exoskeleton of vertebrates like hooves, horns, claws, scales, feathers, beaks etc. The exoskeleton is the chitinous plate of arthropods and the calcareous shell of molluscs.
(ii) Endoskeleton: The skeleton which forms the internal structure of the body is called endoskeleton. The bones and cartilage of vertebrates are the endoskeleton. Invertebrates have endoskeleton. Spicules of Parifera, calcareous plate of Echydermata etc. are endoskeleton. Molluscs do not have skeletons. Earthworms, worms, cockroaches, butterflies etc. do not have skeletons.
Taxonomy
The word taxonomy is derived from the Greek words taxis meaning arrangement and nomos meaning law. The branch of botany that deals with the basis, purpose and principles of classification of plants is called taxonomy. According to scientist E. Mayer (1969), Taxonomy is the theory and practice of classification. French botanist A. P. de Candolle first used the term taxonomy. The Swedish scientist Carolus Linnaeus contributed the most to the taxonomy of plants. That is why he is called Father of Taxonomy. Dr. Siddique Publications
Basic principles of taxonomy
1. Taxonomic character: The characteristics by which one taxon is distinguished from another taxon are called taxonomic characters. The characteristics of each plant are carefully observed and recorded to make the taxonomy. Taxonomic characteristics of plants are reproductive characteristics, genetic characteristics, chemical characteristics, morphological characteristics, physiological characteristics, behavioral characteristics, ecological characteristics etc. These features are properly mentioned during classification. Dr. Siddique Publications
2. Identification: Each plant is accurately identified for taxonomic purposes. Similarities and differences between them are determined on the basis of taxonomic characteristics. Identification may be – genetically unbalanced samples, members grown in unfavorable conditions, hybrids, recently published articles, new species etc. The collected specimens are then compared with the descriptions of other plants. A comprehensive understanding of subspecies, species, synopsis, reviews, catalogs, revisions, monographs, taxonomy, ethnography, field guides and checklists is required for accurate identification.
3. Categorization: According to the course of evolution, plants with similar characteristics are placed in a specific category. The hierarchy has a total of 7 categories or ranks. These are – Kingdom, Phylum, Class, Order, Family, Genus and Species. Among them, Kingdom is the largest and Species is the smallest.
4. Nomenclature: Making, explaining and applying principles related to the scientific name of any plant or animal is called nomenclature. Siddique Publications
(i) Binomial nomenclature: Binomial nomenclature is the giving of a specific scientific name to a particular species by two terms or words adding the species name to the end of the generic name as per ICBN or ICZN principles. In 1753, the Swedish naturalist Carolus Linnaeus introduced the system of binomial naming of organisms.
(ii) Tripad nomenclature: According to the International Principles of Nomenclature of Organisms, the name given to an organism by three terms or words genus, species and subspecies is called tripad nomenclature. German scientist Hermann Schlegel (1884) introduced tripartite nomenclature. Like- Naja naja naja.
5. Conservation: Plant samples collected in different ways should be properly preserved. Leaves, flowers, fruits, seeds, stems, roots etc. of plants are collected as samples. All these samples can be stored in dry or liquid medium. Formalin and alcohol are the best liquid preservation mediums. Various museums, conservatories, colleges and universities of the country store plant specimens in public and private ways.
Units of classification
The steps or levels into which animals are placed are called taxonomic units. Each level or unit of animal classification is called a taxon. The International Code of Zoological Nomenclature (ICZN) uses 7 recognized units or taxa of animals. During taxonomy, taxa are arranged in a specific structure. This is called the taxonomic hierarchy.
1. Species: Species is the smallest unit of taxonomy. This is called the basic unit. A group of organisms with the most physical similarities, capable of producing fertile offspring by sexual intercourse among themselves but unable to produce fertile offspring by sexual intercourse with other groups, is called a species. Behavioral and ecological characteristics of species are called niches. Species can be subdivided into subspecies, varieties etc. if necessary.
According to taxonomist E. Mayer (1969), a species is an interbreeding group of organisms that are reproductively isolated from the nearest similar group. John Ray first used the term species in 1686. Each species has a scientific name. The scientific name of all rice in the world is Oryza sativa.
2. Genus: Genus is the second unit of classification or taxon. A genus consists of several closely related species. Artocarpus genus consists of closely related species such as Jackfruit (Artocarpus heterophyllus), Chaplasha (Artocarpus chaplasha), Dewa (Artocarpus lacucha).
3. Family: Family is the third unit of taxonomy or taxon. A clan is made up of several closely related clans. aceae is added at the end of the plant family name. The family Moraceae is formed by the closely related genera Artocarpus, Ficus, Morus etc.
4. Order: Class is the fourth unit of taxonomy or taxon. Classes are made up of several closely related tribes. Ales are added to the end of plant class names. Sapindales, Morales, Malvales etc. are classes.
5. Class: A class is a higher unit of taxonomy or taxon. Classes are made up of several closely related classes. opsida is added to the end of plant class names. Magnoliopsida, Liliopsida etc. are classes.
6. Division: A division is a higher unit or taxon of taxonomy. Sections are made up of several closely related categories. Phyta is added at the end of the plant division.
7. Kingdom: All the plants of the world belong to the Plantae kingdom.

Necessity of classification
1. Theoretical necessity
(i) Gaining the identity of the living world: If you can get an idea about an animal of a group through taxonomy, you can get an idea about all the animals of that group. That is, taxonomy helps to know all the animals in a simple way.
(ii) Know about fauna: There are millions of species of animals in the world. Through taxonomy one learns about the fauna in less time and with less effort.
(iii) Identification of animals: Any branch of zoology requires accurate identification of animals for research, education, human welfare etc. Animals can be easily identified through taxonomy.
(iv) Knowledge of Animals: Our knowledge of animals can be summed up through taxonomy.
(v) Concise knowledge of animals: Taxonomy helps to summarize knowledge related to animals.
(vi) Identification of new species: Taxonomic knowledge is essential for identification of new species and their placement at various stages. New species cannot be identified without taxonomy.
(vii) Public recognition: Knowledge of taxonomy is essential in providing international public recognition of animals.
(viii) Determining the origin of animals: Modern taxonomy helps in determining the origin of animals and indicates the course of evolution.
(ix) Determination of ethnic relationship: The ethnic relationship of animals can be determined through taxonomy.
(x) International identification: Knowledge of taxonomy plays an important role in providing easy international identification of all the animals of the world.
(xi) Identification of herbivores: Identification of herbivores requires knowledge of taxonomy.
(xii) Development of improved breeds: Improved and disease resistant breeds of animals and plants are developed through artificial breeding. In this case knowledge of taxonomy is a must.
(xiii) Conservation of wild animals: Knowledge of taxonomy is necessary for control and conservation of wild animals.
(xiv) Selection of economic animals: Economic animals can be selected through classification.
(xv) Artificial Breeding: Genetic characteristics are taken into account in the classification of organisms. Knowledge of taxonomy facilitates creation of new and improved breeds of animals and birds through artificial breeding.
(xvi) Agricultural Development: Knowledge of taxonomy is essential for agricultural education, animal health improvement, pest control and crop improvement.
(xvii) Animal Husbandry: Taxonomy is required for rearing and care of poultry and cattle.
(xviii) Food chain: By means of taxonomy one can get an idea about the extinction of animals. Therefore, classification of animals is necessary to preserve animals and maintain the food chain. (xix) Position of animals: Classification is necessary to know the position of any animal in the animal kingdom.
(xx) Identification of Extinct Animals: Animals that have become extinct in the past are found as fossils. Their correct identification can be obtained by observing fossils and classifying them.
(xxi) Conservation of environment: Selection of plants suitable for the environment of any region can be done using the knowledge of taxonomy.
(xxii) Concept of Evolution: Through taxonomy, an idea of the course of evolution of organisms is obtained.
(xxiii) Development of new branches of science: Knowledge of taxonomy is essential for development of new branches of science especially biotechnology, biogeography, biomaterials etc.

2. Applied necessity
(i) Conservation of wild animals: Knowledge of taxonomy is necessary for control and conservation of wild animals.
(ii) Artificial Breeding: Genetic characteristics are taken into account in the classification of organisms. Knowledge of taxonomy facilitates creation of new and improved breeds of animals and birds through artificial breeding.
(iii) Agricultural Development: Knowledge of taxonomy is essential for agricultural education, animal health promotion, pest control and crop development.
(iv) Animal Husbandry: Taxonomy is required for rearing and care of poultry and cattle.
(v) Utilization of animals: By knowing the behavior and nature of animals and classifying them, the beneficial and harmful roles of animals can be known and they can be used accordingly.
(vi) Food chain: Taxonomy can provide an advance understanding of animal extinction. So animal taxonomy is necessary to maintain animal conservation and food chain.
(vii) Sorting of animals: Through classification it is known which are beneficial and which are harmful.
Binomial nomenclature
According to ICBN or ICZN guidelines, giving a specific scientific name to a specific species by adding the species name to the end of the generic name is called binomial nomenclature. Gaspard Bauhin first used binomial names for some plants in his book Pinax. In 1753, the Swedish naturalist Carolus Linnaeus introduced the system of binomial naming of organisms. He introduced binomial nomenclature in Species Plantarum. Binomial nomenclature rules are mentioned.
1. Ekpadi: The top six levels of species of organisms are called Ekpadi. For example- Division.
2. Binomial Name: The species name of the organism will be Binomial. The first is the genus name and the second is the species name of that genus. Part of the species name of an organism is derived from the name of a person, the name of a region or place, a characteristic of a plant, etc. For example – Mangifera indica.
3. Polynomial Name: The lower level name of the species of organism will be polynomial. For example, Brassica oleracea var. botrytis.
4. Language of the name: The scientific name of the organism must be Latin or Latinized.
5. Initials: The first letter of the genus name of the organism should be capitalized and all letters including the first letter of the species name should be written in small letter. For example – Oryza sativa.
6. Printing mode: When printing the scientific name of the organism must be italic or roman or bold.
7. Handwriting: When writing the scientific name of the organism by hand, English letters must be used and the genus and species must be underlined separately. For example – Mangifera indica.
8. Validity: Each species shall have a valid name. It must be validly published.
9. Name of originator: The name of the scientist who gives the scientific name of a plant or animal should be appended to the end of the scientific name of the plant or animal. For example, Oryza sativa L.
10. Tautonym: The genus and species parts of an organism’s scientific name may be the same. For example – Catla catla.
11. Type Specimen: Plants or animals used as specimens during scientific nomenclature should be preserved in the laboratory.
12. Name of many promoters: If it happens, scientific name of a species is given many in the same or different countries, according to the principles or priority, the first scientist who submits the documents to the ICBN first will be accepted.
Binomial nomenclature is a very important process in biology. This rule is followed with utmost respect in all areas of biology, including teaching and research.

Necessity of binomenclature
1. Identification: Each species has only one scientific name. It is known in the world by this name.
2. Identification: Each species has a unique scientific name. So it can be easily identified all over the world.
3. Universal: Each species has only one scientific name. Having only one name does not create any complications. So it is acceptable and universal to all.
4. Language of Names: Organisms are in Scientific Latin or Transliterated Latin. Latin is not the language of any country or nation.
5. Taxonomy: Scientific names help in taxonomy. That is, scientific names are necessary for the classification of organisms.
6. Place Names: Scientific names are made according to the names of places or places. So place name is known from scientific name.
7. Kinship: Scientific names express the relationship between species of the same genus.
8. Characteristic: Being scientific descriptive indicates some characteristic features of the organism.
9. Name of originator: The name of the scientist who gives the scientific name of a plant or animal should be appended to the end of the scientific name of the plant or animal. Hence the name of the promoter is known from the scientific name. For example, Oryza sativa L.

Law of Priority
The process of validating the first published name in accordance with the rules of the International Code of Nomenclature when a taxon has more than one name is called the law of priority. If it happens, scientific name of a species is given many in the same or different countries, according to the principles or priority, the first scientist who submits the documents to the ICBN first will be accepted.
As a result of the operation of the law of precedence, naming conventions are strong and clear. Deprecated names are used as synonyms or pronouns. In this the name is recognized and accepted by everyone. The law of priority will apply.
1. If any part of the animal’s body is named before naming the whole animal.
2. Different genes of a species are called by different names for physical structure, variable state or sexual state.
3. If a living creature was named before 1931.
Homonym
If the scientific names of two or more taxa are spelled the same, the names are called homonyms. According to the law of precedence, the homonym that appears first correctly is called the senior homonym. Other names are declared and abandoned as junior homonyms.
Synonym
A taxon known by two or more names is called a synonym. Synonym problems are solved according to the law of precedence. Dr. Siddique Publications

Tripod nomenclature
The nomenclature of animals using the three terms genus, species and subspecies is called tripartite nomenclature. German scientist Hermann Schlegel (1884) introduced tripartite nomenclature. For example – Khaiya Gokhra (Naja naja naja), Padma Gokhra (Naja naja kauthia), Lice (Pediculus humanus humanus), African lion (Panthera leo leo).

Tautonym
The genus and species part of the scientific name of the organism may be the same. This is called tautonym. For example – Catla (Catla catla), Gokhra (Naja naja).

The history of the sequence of kingdoms in the biosphere
1. Two-Kingdom Taxonomy: Greek philosopher Aristotle, the father of biology, divided the living world into two kingdoms. Plant Kingdom and Animal Kingdom. From Theophrastus to Carolus Linnaeus these two kingdoms were divided. In 1972, Altman and Dittmar included bacteria in the plant kingdom.
2. Three-Kingdom Taxonomy: Scientists Kurtis (1968), Stanier (1970) and Dadson (1971) proposed a third kingdom of the biosphere, Protista. Protista is named after the Greek word protistos meaning first. Bacteria, protista and sponges were included in the kingdom Protista. The proposed three kingdoms are Protista, Plantae and Animalia.
3. Four kingdom taxonomy: In 1956 scientist Copeland separated bacteria from protista and proposed kingdom Monera. The proposed four kingdoms are Monera, Protista, Plantae and Animalia.
4. Five Kingdom Taxonomy: In 1969 scientist Whittaker separated fungi from plants and established kingdom Fungi. Margulis recognized the kingdom Fungi in 1974. The proposed five kingdoms are Monera, Protista, Fungi, Plantae and Animalia
5. Sixth State Classification: In the late 1970s Monara State was divided into two separate states. Archaebacteria and Eubacteria. In the sixth kingdom taxonomy, the biosphere is divided into three domains. Archaea, Bacteria and Eukarya. Domain Archaea kingdom Archaebacteria, Bacteria kingdom Eubacteria and Eukarya kingdom Protista, Fungi, Plantae and Animalia.
Modern classification of biology
In 1969, biologist Robert H. Whittaker proposed the ‘Five World Taxonomy’, dividing the entire biosphere into 5 worlds or kingdoms, including bacteria and other microorganisms. In 1974, biologist Dr. Lynn Margulies introduced the modern taxonomy by modifying and refining the five world taxonomy in Symbiotic Planet. He considered plants and animals together as biota. He divided the living world into two super kingdoms and five worlds. Hence, it is called the five world classification. These are-

Super kingdom- Prokaryota and Super kingdom- Eukaryota

Super Kingdom- 1 Prokaryotes: They do not have a well-structured nucleus. They are unicellular and microscopic. Prokaryotes consist of only one world.

1. World-1: Monera
(i) They are unicellular, filamentous, colonial or mycelial.
(ii) The cell does not have a well-formed nucleus.
(iii) Chromatin bodies contain DNA, but no proteins.
(iv) Cells do not contain plastids, mitochondria, endoplasmic reticulum, lysosomes etc. Dr. Siddique Publications
(v) Cell wall is composed of polysaccharides and proteins.
(vi) Cell division occurs in the process of amitosis.
(vii) Takes food mainly by absorptive system. But in some cases they are photosynthetic or chemosynthetic.
(viii) Manara consists of 15 episodes.
Examples: Nostoc linka, Anabaena, Spirulina, Esherichia coli, Bacillus albus.

Super Kingdom- 2 Eukaryota: Their cells have a well-structured nucleus. They are unicellular or multicellular. Eukaryota consists of 4 kingdoms.

2. World-2: Protoctista
(i) They are unicellular or multicellular and unicellular or colonial.
(ii) Their cells have a well-formed nucleus.
(iii) Chromatin bodies contain DNA, RNA and proteins.
(iv) Cells contain plastids, mitochondria, endoplasmic reticulum, lysosomes etc. Dr. Siddique Publications
(v) Cell division takes place in the process of mitosis and meiosis.
(vi) They are mostly aquatic.
(vii) Their nutrition occurs by eating or absorbing or photosynthetically.
(viii) Multicellular embryos are not formed in their life cycle.
(ix) They are green, autophagous and self-sustaining. ie contain photosynthetic pigments.
(x) Algae are mainly gametophytic plants.
(xi) Their cell wall is composed of cellulose and pectin.
(xii) Their stored dietary sugars.
(xiii) Their genitalia are unicellular and not covered by a sterile sheath (exception- Chara).
(xiv) They do not have transport organs or vasculature. That is, they are avascular.
(xv) Sexual reproduction isogamous, anisogamous and eugamous.
(xvi) Sunlight is essential for their survival.
(xvii) Protoctista consists of 7 episodes.
Examples: Spirogyra hyalina, Amoeba proteus, Ulothrix, Chlamydomonas.
3. World-3: Fungi
(i) They are colourless, parasitic or dead.
(ii) They are unicellular or multicellular and mycelial.
(iii) Their cell walls are made of chitin.
(iv) There are no transport channels and embryos are not formed.
(v) Their stored food is glycogen.
(vi) Cells have well-organized nucleus.
(vii) Their chromatin bodies contain DNA, RNA and proteins.
(viii) Their genitalia are single-celled and not covered by a sterile sheath.
(ix) They do not have transport vessels or vascular bundles. That is, they are avascular.
(x) Their cell division is in the nature of amitosis, mitosis and meiosis.
(xi) Sexual reproduction is isogamous, anisogamous and eugamous.
(xii) Sunlight is not essential for their survival.
(xiii) Their stored food is glycogen and oil droplets.
(xiv) Their cell wall is mainly composed of chitin.
(xv) They reproduce by haploid spores.
(xvi) Their adaptability is severe (5-50°C).
4. World- 4: Plantae
(i) The main plant body is the sporophyte.
(ii) They are unicellular or multicellular and centripetal plants.
(iii) Tissue structure developed and cell wall composed of cellulose.
(iv) Stored food bleaches.
(v) Sexual reproduction is anisogamous and eugamous in nature.
(vi) They are vascular. That is, there are vascular bundles.
(vii) They produce seeds.
(viii) Their spermatozoa are flagellated or non-flagellated.
(ix) The life cycle has a clear sequence.
Example: Paddy, Wheat, Sugarcane, Bhutra etc.

Plant kingdom is divided into two grades. Bryophyta and Tracheophyta
Grade-1: Bryophyta
(i) Plants are gametophytic.
(ii) They are avascular plants. That is, there is no transport tissue.
Example: Semibarbula orientalis

Grade-II: Tracheophyta
(i) Plants are sporophytic.
(ii) They are vascular plants. That is, there is transport tissue.
Example: Oryza sativa
5. World-5: Animalia
(i) They are multicellular and centripetal organisms.
(ii) Their nutrition is Holozoic.
(iii) They are interdependent as they lack chlorophyll.
(iv) Absence of cell wall, plastid and cell cavity.
(v) Cell division occurs through mitosis and meiosis.
Examples: Homo sapiens, Panthera tigris, Labeo rohita, Bombyx mori

Classification of Animalia
Swedish naturalist Carolus Linnaeus divided the animal world into 3 groups. Primates, Secundates and Tertiates Tertiates are divided into 5 classes. Vermis, Insecta, Pisces, Amphibia and Avis.
Hickman et al. (2017) in the book Integrated Principles of Zoology divides the animal kingdom into two phases. Main phase and secondary phase.Dr. Siddique Publications
1. Major phyla: Those groups with more than 5000 species are called major phyla. There are 9 main episodes in total. Among the major episodes, 8 are non-chordata and 1 is chordata. The main groups are Porifera, Cnidaria, Platyhelminthes, Nematoda, Mollusca, Annelida, Arthropoda, Echinodermata and Chordata.
2. Minor phyla: The number of species in the group is less than 5000 is called minor phyla. If secondary phase- Placozoa, Ctenophora