Cell 9th PDF - CBSE Class 9 Science
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Saraswati Shiksha Mandir
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This document looks like notes about cell biology for CBSE class 9 science students. It covers topics including the history of cell discoveries, the cell theory, and introductory cellular structures and functions.
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The Fundamental Unit of Life CBSE Class 9 Science Chapter 5 notes: All living organisms in this universe are made up of cells. They either exist as a single cell or as a combination of multiple cells. Discoveries about Cells – The Fundamental Unit of Life Discovered By Per...
The Fundamental Unit of Life CBSE Class 9 Science Chapter 5 notes: All living organisms in this universe are made up of cells. They either exist as a single cell or as a combination of multiple cells. Discoveries about Cells – The Fundamental Unit of Life Discovered By Period of What did they discover? time Robert Hooke 1665 noticed the presence of cells in a cork slice Leeuwenhoek 1674 found the presence of living cells in the pond water Robert Brown 1831 recognized the existence of a nucleus in the cell Purkinje 1839 invented the term ‘Protoplasm’ which is the liquid present in a cell Schleiden and 1838, 1839 presented the cell theory that all organisms are Schwann actually made up of cells Virchow 1855 suggested that all cells come from cells that already exist in nature The Cell Theory 1. A cell is the structural and functional unit of all living organisms. 2. All living organisms are made up of cells. 3. Cells are formed from pre-existing cells. Unicellular Organisms – The organisms that consist of a single cell such as Amoeba. Multicellular Organisms – The organisms which contain various cells that perform different functions in the organism such as plants fungi and animals How can multicellular organisms originate from a single cell? A cell can divide itself into cells of its own type. Therefore, more cells can generate from an already existing cell. The Shape of the Cell The shape of the cell may vary depending upon the type of function they perform in an organism. Cells are capable of changing their shape. For example, the white blood cells and amoeba can change shapes on their own. Figure 1 - Cells can have different Shapes and Sizes How can cells perform distinct functions in organisms? Cells are capable of performing multiple functions in an organism. A cell contains specific components which are called Organelles. Each organelle in the cell can perform different functions such as making new cells or clearing the waste of the cell. Thus, organelles allow a cell to perform several kinds of activities in an organism. The Organisation of a Cell Figure 2 – The Structure of Cells in Plants and Animals A cell contains three features – The Plasma Membrane Nucleus Cytoplasm Plasma Membrane It is just like an envelope that covers the whole cell. Therefore, a cell gets separated from the external environment because it has a plasma membrane. The plasma membrane can decide which materials should enter or leave the cell and which should not. That is why it is also called a ‘Selectively Permeable Membrane’. The Fluid Mosaic Model of Plasma Membrane The Fluid Mosaic model explains the structure of the plasma membrane. According to it, the plasma membrane comprises 3 components - Lipids, Proteins and Carbohydrates. These components can flow freely and fluidly inside the plasma membrane. There are two types of lipids (fats) in the plasma membrane – Phospholipid – It is a lipid made up of glycerol, two fatty acids, and phosphate. It creates a semi-permeable membrane that allows the flow of only certain materials inside/ outside the cell Cholesterol - It is a lipid that provides fluidity to the surface of the plasma membrane. The proteins act as receptors of the cell and help in transportation across the cell membrane. The carbohydrates attach themselves with the lipids and proteins and are found on the extracellular side of the membrane. Figure 3 -Structure of the Plasma Membrane How can substances move in and out of a cell? Gaseous Exchange between the Cell and its External Environment – Movement of Oxygen and Carbon dioxide to and from the cell is carried out through diffusion. Gaseous substances tend to move to areas where their concentration is less from the areas where there is higher. This movement is defined as the process of diffusion. Diffusion can take the place of solids, liquids, and gases. Movement of Water between the Cell and its External Environment – It is carried out by the means of osmosis. Osmosis is a process in which water moves from the region of high concentration to one where its concentration is low through a semipermeable membrane. Therefore we can say that Osmosis is just a special case of the process of diffusion. Hypotonic Solutions If the concentration of water outside the cell is higher than the concentration of water inside the cell gains water by the process of osmosis. Water can move into the cell from the cell membrane. In the case of hypotonic solutions, more water enters the cells which result in swelling of the cells. Figure 4 - Hypotonic Solution Isotonic Solutions If the cells are put in an environment that has a similar concentration of water as present inside. This state allows for the free movement of water across the membrane without changing the concentration of solutes on either side. Therefore, the size of the cell does not vary in an isotonic solution because there is no net movement of water. Figure 5 - Isotonic Solution Hypertonic Solutions If the cells are kept in an environment that has a lower concentration of water than what is present inside the cells then due to the process of osmosis water moves out of the cells. This results in a decrease in the size of the cells (they shrink) as more water comes out of the cell. Figure 6 - Hypertonic Solution What is Endocytosis? (Olympiad) It is a process by which the plasma membrane engulfs food and other materials inside the cell. Cell Wall The cell wall is an outer, hard covering of the cell which maintains the shape of the cell. The cell wall is generally made up of cellulose. What is plasmolysis? Plasmolysis is a process in which the contents of the cell that are away from the cell wall shrink or contract when a cell loses water due to Osmosis when it is kept in hypertonic solution. Can dead cells absorb water? No, dead cells cannot absorb water through osmosis. How plants, fungi, and bacteria can exist in the hypotonic medium? Plants, fungi, and bacteria exist in such situations because of their rigid cell membranes. Even if the cells swell up the cell membrane is able to prevent them from bursting out. The Nucleus Nucleus is a prominent organelle present in the cell which is the controlling centre of all activities of the cell. Figure 7 - Nucleus of a Cell The Structure of the Nucleus A nucleus has a nuclear membrane that covers it all around. There are pores present on the nuclear membrane that allow the movement of substances in and out of the nucleus. There are chromosomes, rod-shaped structures present in the nucleus which contain genetic information. The chromosomes contain two types of things - 1. DNA - This is responsible for organising and constructing new cells 2. Proteins - These help in the packaging and condensation of DNA. Chromatin Chromatin is thread-like material present in a cell. The chromatin organises itself into chromosomes whenever the cell is about to divide. Figure 8 – Chromosomes and Chromatin Nucleolus It is called the Brain of the Nucleus. It comprises 25% of the volume of the nucleus. It consists of proteins and ribonucleic acids (RNA). It helps in the formation of ribosomes which help in the formation of proteins inside the cell. Figure 9 - Nucleolus inside a Nucleus What is a nucleoid? Sometimes cells do not have a well-defined nucleus because they lack a nuclear membrane. Such a nucleus with no definite nuclear boundaries is called a Nucleoid. What are the prokaryotes? Organisms whose cells do not have a definite cell membrane are called Prokaryotes. What are eukaryotes? Organisms whose cells contain a well-defined nuclear membrane are called Eukaryotes. Are there any further differences between prokaryotes and eukaryotes? Prokaryotes Eukaryotes There is no presence of nucleus The nucleus exists in the cells A single chromosome is present There are multiple chromosomes They undergo asexual reproduction They undergo sexual as well as a sexual reproduction They are generally unicellular They are generally multicellular organisms organisms There are no membrane-bound cell There are membrane-bound cell organelles organelles present inside the cells Example – Bacteria, Blue-green algae Example – Fungi, Plants and Animals (Cyanobacteria) Figure 10 - Eukaryotic and Prokaryotic Cells Cytoplasm The plasma membrane has a fluid-like substance in it which is called the cytoplasm. The cytoplasm contains several organelles that can perform distinct functions of the cell Functions of Cytoplasm It supports and suspends the cell organelles and molecules. The cellular processes occur in the cytoplasm such as the formation of proteins. It allows the movement of substances in the cell such as hormones. It dissolves cellular wastes. The Cell Organelles In the case of Eukaryotic organisms, the cells contain organelles that have their own membranes apart from the overall cell membrane of the cell. Figure 11 - Different Cell Organelles What is the significance of membrane-bound organelles in a cell? The cells perform several functions. The organelles are useful because they allow the separation of different functions that are being performed by the cell. Organelles which carry out important activities in a Cell – 1. Endoplasmic Reticulum 2. Golgi Apparatus 3. Lysosomes 4. Mitochondria 5. Plastids 6. Vacuoles 7. Centrioles 8. Ribosomes 9. Peroxisomes Endoplasmic Reticulum (ER) Figure 12 - Endoplasmic Reticulum The structure of the ER is quite similar to that of the plasma membrane. It is a network-like structure that consists of membrane-bound tubes and sheets. Two types of ER – Rough ER Smooth ER Rough ER contains ribosomes that are responsible for the manufacturing of proteins in the cells. They give a rough texture to the cell. The smooth ER manufactures fats or lipids in the cell which allow the functioning of the cell. What are the functions of lipids and proteins? Proteins and lipids synthesised on ER are used for making cell membranes. The process is known as Membrane Biogenesis. Proteins can act as an enzyme Both protein and lipids can act as hormones Functions of ER Transportation of material between different parts of the cytoplasm and also between the nucleus and cytoplasm Folding of proteins which are synthesised by ribosomes on RER. Detoxifying poisons and drugs out of the cell is the function of SER. Golgi Apparatus Figure 12 – Golgi Apparatus Camillo Golgi discovered the Golgi Apparatus. It contains vesicles that are arranged parallel in stacks. These stacks are called Cisterns. These vesicles have their own membranes. These membranes are sometimes connected to those of the ER. Functions of Golgi Apparatus Golgi apparatus carries materials synthesised by the ER to different parts of the cell. The material is stored and packaged in vesicles. Formation of complex sugar Formation of lysosomes. Lysosomes Figure 13 – Structure of Lysosome They are single-membrane vesicles that are responsible for cleaning the cell. They can digest any foreign material such as food or bacteria and even the worn-out cell organelles. How can lysosomes digest any foreign material that enters the cell? Lysosomes are capable of doing so because they have digestive enzymes in them. These enzymes break the materials and digest them. These enzymes are synthesised by RER and packaged into lysosomes by Golgi bodies. Why lysosomes are called ‘suicide bags’? If the cell’s own material gets damaged or dead, there are chances that lysosomes burst out, thus digesting its own cell. Mitochondria It is a double membrane organelle that has its own DNA and that is why often called ‘Semi - Autonomous Organelle’ Figure 15 – Structure of Mitochondria The cell requires energy in order to carry out several activities. This energy is generated by mitochondria which are often called the ‘Powerhouse’ of the Cell. Mitochondria are the site of cellular respiration. They use oxygen from the air to oxidise the carbohydrates and thereby release energy. What are the energy currencies of a cell? The Mitochondria generates ATP (Adenosine Triphosphate) which are energy giving molecules of the cell that are often called their ‘Energy Currency’. The two membranes of Mitochondria Outer Membrane – Porous in Nature Inner Membrane – Deeply Folded The Inner Membrane of Mitochondria called as Cristae Facilitates Generation of ATP molecules as it has a larger surface area. Plastids Just like mitochondria, Plastids are also double membraned organelles that have their own DNA and ribosome. Plastids exist in plant cells only. Depending upon the type of function they play in the cell they can be classified as – Figure 15 – Types of Plastids Chromoplast Leucoplast Coloured in nature, contain a Colourless in nature pigment called chlorophyll Cause photosynthesis in plants Act as storage spaces of the cells Contain orange and yellow pigments Contain starch, proteins and oil Can further be divided into Can further be divided into amyloplast, elaioplast Chloroplasts and proteinoplast or aleuroplast. Classification of Plastids 1. Amyloplast They are found in tubers, cotyledons and endosperm in plants. They are used to store starch. 2. Elaioplast They are found in epidermal cells of the plants They store oil. 3. Proteinoplast They are found in seeds and nuts. They store proteins. Chloroplasts Chloroplasts are cell organelles that conduct photosynthesis in plants. Chloroplast is derived from two Greek words Chloro and Plasts which means green and plants respectively. Chloroplasts contain photosynthetic pigments called ‘Chlorophyll’ along with lipids, carbohydrates, minerals, DNA, RNA, grana, thylakoids and stroma. The main functions of chloroplasts are: Conducting photosynthesis in plants. Protein synthesis Releases oxygen Storage of Starch Figure 16 – Chloroplast containing thylakoids, stroma and grana Light-dependent Reactions in Photosynthesis – During photosynthesis chlorophyll absorbs the light energy which is then used for two molecules ATP and NADPH. Thylakoids – They are pillow-shaped compartments in the chloroplast. The light-dependent reactions in photosynthesis take place in the thylakoids. Stroma – It is a fluid-filled matrix in the chloroplasts. It is a colourless fluid that contains all the enzymes that are needed for the light-dependent reactions in Photosynthesis. Grana – Stacks of thylakoids are called Grana. They are found in the stroma. They provide a large surface area so that the reactions of photosynthesis can take place. Vacuoles Vacuoles are the places where cells can store liquids and solids. They are present in both plants and animals but the plant vacuoles are bigger in size than the animal vacuoles. Plant Cell Vacuoles Animal Cell Vacuoles Plant cell vacuoles store all the material that is Animal cell vacuoles contain food required for the plant to stay alive such as water items in unicellular organisms Plant vacuoles maintain the turgidity of the plant Animal vacuoles can also expel cell water and waste out of the cell Plant cells generally contain a single large vacuole Animal cell contain several small vacuoles Plant vacuoles are present in the centre of the cell Animal vacuoles are scattered throughout the cell Types of Vacuoles Sap Vacuoles Contractile Vacuoles Food Vacuoles Sap Vacuoles Figure 17 - Sap Vacuoles These vacuoles are filled with a fluid called Vascular Sap. The fluid contains Amino Acids, Salt, Sugar, Proteins, Water, and Waste Materials. Sap vacuoles are separated from the cytoplasm by a semipermeable membrane called Tonoplast. Their main function is to allow rapid exchange between the cytoplasm and the surrounding environment. Several sap vacuoles are found in young plant cells and animal cells. In mature plants, the small sap vacuoles combine to form a single large central vacuole. Contractile Vacuoles Figure 18 – Osmoregulation in Amoeba through Contractile Vacuoles They are found in protistan and algal cells in freshwater. The membrane of the contractile vacuoles is highly extensible and collapses easily. These vacuoles are responsible for osmoregulation (maintaining the water content of the cells) and excretion in t he cells. Food Vacuoles Figure 19 – Food Vacuoles and Digestion They are found in the cells of protozoans and several lower animals. Food vacuoles are responsible for the digestion of food in the cells as they contain food enzymes. The digested food then passes into the cytoplasm. Found in single-celled organisms like Amoeba. Centrioles A centriole is a small set of microtubules arranged in a specific way. Their main purpose is to help a cell in cell division. They are found near the nucleus but can be seen only during the cell division. They are found in pairs and form a special substance called Centrosome which appears near the nucleus. When the cell divides, the centrosome divides into two parts and each part moves to opposite sides of the cell. Figure 20 - Centrioles Ribosomes They are cell organelles responsible for protein synthesis. Ribosomes can be found in both prokaryotes and eukaryotes because the synthesis of proteins is important in both of them. In prokaryotes, the ribosomes float freely in the cytoplasm. In eukaryotes, they can be found floating in the cytoplasm or they are often attached to the endoplasmic reticulum. The ribosomes attached to the ER synthesise proteins that are to be exported out of the cell while the ribosomes floating inside the cell synthesise proteins that are used inside the cell. Peroxisomes Peroxisomes are small vesicles found in the cells. These enzymes are used to break the toxic materials inside the cell. They digest the fatty acids of the cell as well as amino acids by carrying out oxidation reactions in the cell. They are also responsible for the digestion of alcohol in the human body. Hence, the liver contains a large number of Peroxisomes. Figure 21 - Peroxisomes in a cell Cell Division The process by which new cells are made is called cell division. There are two main types of cell division, that is, mitosis and meiosis. Mitosis The process of cell division by which most cells divide for growth is called mitosis. In this process, each cell, called the mother cell, divides to form two identical daughter cells. The daughter cells have the same number of chromosomes as the mother cells. Mitosis helps in the growth and repair of tissues in organisms. Meiosis The process of cell division by which specific cells of reproductive organs or tissues in animals and plants divide to form gametes is called meiosis. When a cell divides by meiosis, it produces four new cells instead of just two. The new cells only have half the number of chromosomes as the mother cells. Meiosis helps in the production of gametes—sex cells, sperm, and eggs.