Table of contents | |
Basis of Classification | |
1. Levels of Organisation | |
2. Symmetry | |
3. Diploblastic and Triploblastic Organisation | |
4. Coelom | |
5. Segmentation | |
6. Notochord | |
Habitat |
Earth is home to over a million described species of animals, each with unique structures and forms. Classification is essential to organize this vast diversity.
Classification helps in assigning a systematic position to newly described species. It provides a framework for placing new discoveries within the context of existing knowledge.
Diversity of Organisms
Classification enables a systematic study of the diverse animal kingdom. It allows scientists to group similar species together, making it easier to study and understand them.
The classification system assists in organizing animals by grouping them according to these essential characteristics given below:
In this level of organisation , organisms consist of cells that are loosely gathered together. A prime example is seen in sponges.
Sponges
The tissue level of organization represents an intermediate stage between the cellular level and the organ level.
Coelenterates
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At the organ level, the basic tissues are further organized into distinct organs. Organs are composed of multiple tissues that work together to perform specific, more specialized functions.
Platyhelminthes
Organ system-level organisation refers to the hierarchical arrangement of organs and tissues within the human body to perform specific functions and maintain overall homeostasis.
Organisms with organ level organisation
Symmetry refers to a characteristic feature of an organism's body structure, specifically its arrangement and organisation of body parts.
Different types of Symmetry
Diploblastic and triploblastic organisation are terms used to describe different levels of germ layer development in the early embryonic development of animals. Germ layers are distinct layers of cells that form during gastrulation, the process by which the embryo transforms from a single-layered structure into a more complex, multi-layered structure.
(i) Diploblastic Organisation: In diploblastic organisms, there are two primary germ layers that develop during gastrulation: the ectoderm and the endoderm.
Diploblastic organisation is typically found in simpler, radially symmetrical animals like cnidarians (e.g., jellyfish and corals). These animals lack a true mesoderm, which is a third germ layer that gives rise to structures like muscles, bones, and most internal organs in more complex organisms.
(ii) Triploblastic Organisation: In triploblastic organisms, there are three primary germ layers that develop during gastrulation: the ectoderm, mesoderm, and endoderm.
Triploblastic organisation is found in more complex animals, including most vertebrates (animals with a backbone) and many invertebrates. These animals have a greater level of developmental complexity compared to diploblastic organisms because they have three distinct germ layers, which allows for the formation of a wider range of tissues and organs.
The term "coelom" refers to the body cavity found in many animals. This body cavity is a fluid-filled space that separates the digestive tract (endoderm) from the outer body wall (ectoderm). It is lined by a layer of mesodermal tissue
There are three such categories divided on the basis of the presence or absence of coelom.
(a) Coelomates: Animals that possess a true coelom, which is a fluid-filled body cavity entirely lined by mesoderm, one of the three primary germ layers.
(b) Pseudocoelomates: Pseudocoelomates are animals with a body cavity known as a pseudocoelom, which is not fully lined by mesoderm but is located between the ectoderm (outer tissue layer) and the endoderm (inner tissue layer).
(c) Acoelomates: Acoelomates are animals that lack a true body cavity. They do not have a coelom or pseudocoelom.
Metamerism, also known as serial segmentation, is a fundamental biological phenomenon observed in certain animals where the body is divided into a series of repeating, similar segments.
Segmentation in Earthworm
The notochord is a rod-like structure that forms during embryonic development in some animals, particularly those belonging to the group called chordates. Animals with a notochord are called chordates, while those without it are called non-chordates.
Phylum ChordatesThe presence or absence of the notochord is a fundamental characteristic used in the classification of animals into these two major categories, reflecting their evolutionary relationships and developmental traits.
On the basis of coelom, animals can be:
(i) Acoelomate: The animals in which the coelom is absent are called as Acoelomates, for example flatworms. In them, the space between ectoderm and endoderm is filled with parenchyma eg. Platyhelminthes.
(ii) Pseudocoelomate: The body cavity is not completely lined with mesoderm. Instead, the mesoderm is present as scattered pouches in between the ectoderm and endoderm. Such a body cavity is called as pseudo-coelom e.g. roundworm.
(iii) Eucoelomate: The true coelom is a body cavity that arises as a cavity in embryonic mesoderm. In this case, the mesoderm of the embryo provides a cellular lining, called as coelomic epithelium or peritoneum, to the cavity. The coelom is filled with coelomic fluid secreted by the peritoneum. The coelom is found in Arthropods, Molluscs, Annelids, Echinoderms, Hemichordates, and Chordates.
The true coelom is of two types:
(a) Schizocoelom: It develops by the splitting up of mesoderm. It is found in annelids, arthropods, and molluscs. The body cavity of arthropods is called hemocoel.
(b) Enterocoelom: The mesoderm arises from the wall of the embryonic gut or enteron as hollow outgrowths or enterocoelomic pouches. It occurs in Echinoderms, Hemichordates, and Chordates.
– In some animals, the body is externally and internally divides into segments or metameres with serial repetition of atleast some organs. For example, in earthworm, the body shows metameric segmentation and the phenomenon is known as metamerism.
– Notochord is a mesodermally derived rod-like structure formed on the mid-dorsal surface during embryonic development in some animals. Animals with notochord are called chordates and those animals that do not form this structure are called non-chordates, e.g., Porifera to Echinoderms or Hemichordates.
Blood vascular system is basically of two types:
Open and Closed
(i) Open type: In open type, the blood is pumped by the heart into the blood vessels that open into blood spaces (sinuses). There is no capillary system (i.e., most arthropods, some molluscs except cephalopods and tunicates). These sinuses are actually the body cavities and are called hemocoel. The pressure of the blood is low; it moves slowly between the tissues, and finally, returns to the heart via the opened veins. In fact, the distribution of blood in the tissues is very poorly controlled. The pigments, which carry oxygen, remain dissolved in blood plasma. Body tissues and visceral organs exchange respiratory gases, nutrients, and waste products, directly with blood.
(ii) Closed type: Many invertebrates and all vertebrates, including humans, have a closed circulatory system. In the closed type, the blood flows around the body through the specific blood vessels. In this system, the same blood regularly circulates in the body under high pressure and returns back to the heart without leaving the system of tubes. The heart pumps the blood into the aorta, which branches in the body into the arteries, and in the tissues into the arterioles, to form the capillary network. The venules of the capillary network carry the blood back to the heart via veins and the vena cava. This helps in supplying the nutrients and oxygen to the tissues, and removing waste materials and caron dioxide from it reveals a comparison between open and closed circulatory systems.
Comparison of Open and Closed Circulatory Systems | |
Open System | Closed System |
These are usually low-pressure systems. | These are usually high-pressure systems. |
Blood is conveyed directly to the organs without the formation of capillaries. | Blood is conveyed directly to the organs through capillaries. |
The distribution of blood to different organs is not well regulated. | The distribution of blood to different organs is well-regulated. |
Blood returns to the heart slowly. | Blood returns to the heart rapidly. |
Found in most arthropods, non cephalopod molluscs and tunicates | Found in cephalopods (octopus, squids) and vertebrates. |
Digestive System: A digestive system is a group of organs in animals that work together to break down food into nutrients that can be absorbed by the body. It includes organs such as the mouth, esophagus, stomach, small intestine, large intestine, liver, and pancreas, each with its own specific function in the process of digestion and absorption.
There are two forms of digestive systems Complete and Incomplete Digestive system.
Circulatory System: A circulatory system is a group of organs and tubes that moves blood, oxygen, nutrients, and other important things through an animal's body. It includes the heart, blood vessels, and blood. It helps the body stay healthy by controlling temperature, pH, and fluids.
The circulatory system are of two types:
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1. What are the different levels of organization in classification? |
2. How does symmetry play a role in classification? |
3. What is the significance of coelom in classification? |
4. How does segmentation aid in classification? |
5. Why is the notochord significant in classification? |
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