(a) Robert Brown did not discover the cell. The cell was discovered by Robert Hook.
Cells are the basic units of life capable of doing all the required biochemical processes that a normal cell has to do in order to live. The basic needs for the survival of all living organisms are the same. All living organisms need to respire, digest food for obtaining energy, and get rid of metabolic wastes.
Cells are capable of performing all the metabolic functions of the body. Hence, cells are called the functional units of life.
Nuclear pores are tiny holes present in the nuclear membrane of the nucleus. They are formed by the fusion of two nuclear membranes.
These holes allow specific substances to be transferred into a cell and out from it. They allow molecules such as RNA and proteins to move in both directions, between the nucleus and the cytoplasm.
Lysosomes are membrane-bound vesicular structures holding a variety of enzymes such as lipases, proteases and amylases. The purpose of lysosomes is to digest worn out cells. They are involved in the intracellular digestion of foreign food particles and microbes. Sometimes, they also act as suicidal bags. They are involved in the self digestion of cells. They are a kind of waste disposal systems of a cell. On the other hand, vacuoles are storage sacs found in cells. They might store the waste products of cells. In unicellular organisms, the food vacuole contains the consumed food particles. It also plays a role in expelling excess water and some wastes from the cell.
(i) Nucleus
Nucleus controls all the cellular activities of the cell. It is spherical in shape. It is composed of the following structures:
Nuclear membrane: It is a double membrane separating the contents of the nucleus from the cytoplasm. The narrow space between the two membranes is called the perinuclear space. Nuclear membrane has tiny holes called nuclear pores. These holes allow specific substances to be transferred into a nucleus and out from it.
Nucleoplasm/Nuclear matrix: It is a homogenous granular fluid present inside the nucleus. It contains the nucleolus and chromatin. Nucleolus is a spherical structure that is not bound by any membrane. It is rich in protein and RNA molecules, and is the site for ribosome formation. Chromatin is an entangled mass of thread-like structures. It contains DNA and some basic proteins called histones.
(ii) Centrosome
Centrosome consists of two cylindrical structures called centrioles. Centrioles lie perpendicular to each other. Each has a cartwheel-like organisation.
A centriole is made up of microtubule triplets that are evenly spaced in a ring. The adjacent triplets are linked together. There is a proteinaceous hub in the central part of a centriole. The hub is connected to the triplets via radial spokes. These centrioles help in organising the spindle fibres and astral rays during cell division. They form the basal body of cilia and flagella as well.
Centromere is a constriction present on the chromosomes where the chromatids are held together.
Chromosomes are divided into four types based on the position of the centromere.
(i) Metacentric chromosome
The chromosomes in which the centromere is present in the middle and divides the chromosome into two equal arms is known as a metacentric chromosome. During anaphase, they appear V-Shaped.
(ii) Sub-metacentric chromosome
The chromosome in which the centromere is slightly away from the middle region is known as a sub-metacentric chromosome. In this, one arm is slightly longer than the other. During anaphase, they appear L-Shaped.
(iii) Acrocentric chromosome
The chromosome in which the centromere is located close to one of the terminal ends is known as an acrocentric chromosome. In this, one arm is extremely long and the other is extremely short. During anaphase, they appear J-Shaped.
(iv) Telocentric chromosome
The chromosome in which the centromere is located at one of the terminal ends is known as a telocentric chromosome. During anaphase, they appear i-Shaped.
(c) According to the biogenic theory, new cells can only arise from pre-existing cells. Only complete cells, in favourable conditions, can give rise to new cells.
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Column I |
Column II |
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(a) |
Cristae |
(ii) |
Infoldings in mitochondria |
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(b) |
Cisternae |
(iii) |
Disc-shaped sacs in Golgi apparatus |
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(c) |
Thylakoids |
(i) |
Flat membranous sacs in stroma |
(c) Membrane-bound organelles are organelles surrounded by a double or a single membrane like Nucleus, mitochondria, chloroplasts, Lysosomes, ER, Golgi bodies etc. are examples of such organelles. These cell organelles are absent in prokaryotes.
(a) Only eukaryotic cells have nuclei. They are absent in prokaryotes.
(b) Cell walls are only present in plant cells. They are absent in all animal cells.
(d) All cells arise from pre-existing cells.
Mesosome is a convoluted membranous structure formed in a prokaryotic cell by the invagination of the plasma membrane. Its functions are as follows:
(1) These extensions help in the synthesis of the cell wall and replication of DNA. They also help in the equal distribution of chromosomes into the daughter cells.
(2) It also increases the surface area of the plasma membrane to carry out various enzymatic activities.
(3) It helps in secretion processes as well as in bacterial respiration.
Plasma membrane is the outermost covering of the cell and regulates the movement of substances into the cell and out from it. It allows the entry of only some substances and prevents the movement of other materials. Hence, the membrane is selectively-permeable.
Movement of neutral solutes across the cell membrane – Neutral molecules move across the plasma membrane by simple passive diffusion. Diffusion is the movement of molecules from a region of higher concentration to a region of lower concentration.
Movement of polar molecules across the cell membrane – The cell membrane is made up of a phospholipid bilayer and proteins. The movement of polar molecules across the non-polar lipid bilayer requires carrier-proteins. Which are integral protein particles having certain affinity for specific solutes. As a result, they facilitate the transport of molecules across the membrane.
Mitochondria and chloroplasts are the two organelles that are double-membrane-bound.
Characteristics of the mitochondria
Mitochondria are double- membrane-bound structures. The membrane of a mitochondrion is divided into the inner and outer membranes, distinctly divided into two aqueous compartments – outer and inner compartments. The outer membrane is very porous, while the inner membrane is deeply-folded.
These folds are known as cristae. They are the sites for ATP-generating chemical reactions. The membrane and matrix of a mitochondrion contains specific enzymes meant for aerobic respiration. They have their own DNA and ribosomes. Thus, they are able to make their own proteins. This is why they are considered as semi-autonomous organelles
Characteristics of chloroplasts
Chloroplasts are double-membrane-bound structures.
They are divided into outer and inner membranes, further divided into two distinct regions:
(i) Grana are stacks of flattened discs containing chlorophyll molecules. The flattened membranous sacs are called thylakoids. The thylakoids of adjacent grana are connected by membranous tubules called stroma lamellae.
(ii) Stroma is a homogenous mixture in which grana are embedded. It contains several enzymes that are used for the synthesis of carbohydrates and proteins. It also contains its own DNA and ribosomes and hence semi-autonomous organelle.
Functions of the mitochondria:
(i) They are the sites for cellular respiration.
(ii) They provide energy in the form of ATP for all vital activities of living cells.
(iii) They have their own DNA and ribosomes. Hence, they are regarded as semi-autonomous organelles.
(iv) They have several enzymes, intermediately required for the synthesis of various chemicals such as fatty acids, steroids, and amino acids.
Functions of chloroplasts:
(i) They trap solar energy and utilise it for manufacturing food for plants. Hence, they are involved in the process of photosynthesis.
(ii) They contain the enzymes required for the synthesis of carbohydrates and proteins.
The characteristics of prokaryotic cells are as follows:
(i)They are generally small in size. The size of a prokaryotic cell varies from 0.5 – 5 µm.
(ii) The nuclear region of a prokaryotic cell is poorly-defined because of the absence of a nuclear membrane. Hence, a prokaryotic cell lacks a true nucleus.
(iii) The genetic materials of prokaryotic cells are naked. They contain single, circular chromosomes. In addition to the genomic DNA, they have a small, circular plasmid DNA.
(iv) They have specialised membranous structures called mesosomes. Mesosomes are formed by the invagination of the cell membrane. These extensions help in the synthesis of the cell wall and replication of DNA. They also help in the equal distribution of chromosomes into the daughter cells.
(v) Membrane-bound cell organelles such as mitochondria, plastids, and endoplasmic reticulum are absent from a prokaryotic cell.
(vi) Most prokaryotic cells contain a three-layered structure – outermost glycocalyx, middle cell wall, and the innermost plasma membrane. This structure acts as a protective unit.
Examples of prokaryotic cells include blue green algae, bacteria, etc.
Multicellular organisms are made up of millions and trillions of cells. All these cells perform specific functions. All the cells specialised for performing similar functions are grouped together as tissues in the body. Hence, a particular function is carried out by a group of cells at a definite place in the body. Similarly, different functions are carried out by different groups of cells in an organism and this is known as division of labour in multicellular organisms.
Following attributes must cell have to be called a living cell:-
Yes, Plastids are Interchangeable in their form depending upon different circumstances chloroplast, chromoplasts and Leucoplast are getting converted from one type to another:
Chloroplast - Green Colour
Chromoplast - Red, Yellow, Orange
Leucoplast - Colourless
(a) Rudolf Virchow
(b) Schleiden and Schwann
Cell theory was formulated by Schleiden and Schwann together (1838-39). They proposed that all living beings are made up of one or more cells. They also said that cells are the basic functional and structural unit of life. However this theory did not explain as to how new cells were formed.
Yes, extra Genomic DNA is present in prokaryotes and Eukaryotes. Many bacteria have small circular DNA outside the Genomic DNA called Plasmids.
In Eukaryotic organisms, the extra genomic DNA or plasmid is present in two organelles mitochondria and Plastids.
In Bacteria, this plasmid DNA is used to monitor bacterial transformation with foreign DNA.
In Plants and Animals, function and structure of Plasma membrane are correlated. It is made up of Proteins carbohydrates and lipids. The lipids are arranged with their hydrophilic polar head directed outwards and nonpolar hydrophobic tail directed inward providing fluidity to the membrane. Glycocalyx present in cell membranes also helps in cellular attachment. In the case of the plants, minerals are absorbed from the soil. The Plasma membrane possesses a proteinaceous carrier.
a. Not be bound by a membrane
Non-membrane bound cell organelle are - Ribosomes, Centriole, nucleolus, Cytoskeleton structures.
b. Bound by a single membrane
Endoplasmic Reticulum, Golgi bodies, lysosome, vacuoles, Thylakoid.
c. Bound by a double membrane
Plastids, mitochondria and Nucleus.
For humans (Homo sapiens) the genomic content in the nucleus is constant i.e. 46 chromosomes but the mitochondria present in the human will have a different amount of extra chromosomal DNA.
As like in Human beings, bacteria will have the same amount of Genomic DNA but different extra genomic DNA present in mitochondria and plastids.
Each mitochondrion is a double membrane bound structure with the outer membrane and the inner membrane. The mitochondria are involved in releasing energy from food. This process is known as cellular respiration. This process produces cellular energy in the form of ATP (high grade fuel of the cell). ATP is used to bring about energy requiring activities in the cell. It is the reason that mitochondria are often referred to as the Powerhouses of the cell.
Yes, Plastids are species specific or region specific. They are found in plant cells and Euglenoids and can be observed easily under microscope as they are large. They bear some specific pigments, thus imparting specific colours to the plants.
According to the types of Pigments plastids are divided into three:
1. The chromoplasts contain fat-soluble carotenoid pigments like carotene, xanthophylls and others are present. These are commonly found in exposed parts like flowers and fruits. Being coloured, chromoplasts attract animals for pollination and fruit dispersal.
2. The chloroplasts contain chlorophyll which is a green pigment and carotenoid pigments. Because of these pigments chloroplasts impart green colour. Chloroplasts capture light energy from the sun to produce food for the plant by combining the sun's energy with water and carbon dioxide.
3. The Leucoplasts are the colourless plastids of varied shapes and sizes with stored nutrients.
a. Centromere
It holds two Chromatids together and also facilitates the proper segregation of sister chromatids.
b. Cell wall
It provides shape to the cell and also protects the cell from Mechanical damage. It also helps in cell to cell interaction and provides a barrier to undesirable macromolecules.
c. Smooth ER
In animal cells lipid like steroidal hormones are synthesized in SER.
d. Golgi apparatus
Glycoproteins and Glycolipids are formed in the Golgi apparatus.
e. Centrioles
The basal body of cilia or flagella and spindle fibres that give rise to spindle apparatus.