09 Biology

1. Introduction

What this Chapter Covers

Cell as the unit of life: This chapter teaches that the cell is the basic building block of all living things, whether plants or animals.
Protoplasm: You’ll learn about protoplasm, the living substance found inside every cell.
Prokaryotic vs. Eukaryotic cells: The difference between cells with a true nucleus (eukaryotic) and those without (prokaryotic) is explored.
Plant cell vs. Animal cell: The chapter compares plant and animal cells, particularly focusing on cell wall, centrosome, vacuoles, and plastids.
Cell Structure and Organelles: You’ll study the structure of both plant and animal cells. Special attention is given to each cell part and organelle, such as:
- Cell Membrane
- Cell Wall
- Nucleus & Nucleolus
- Mitochondria
- Endoplasmic Reticulum
- Ribosome
- Golgi Bodies
- Plastids
- Lysosomes
- Centrosome
- Vacuole

Key Takeaways

The cell theory and its basics are a crucial foundation.
The functions of each cell organelle are discussed.
Differences between plant and animal cells are highlighted for better understanding.

This chapter builds your concepts for further studies in biology, helping you understand how all living organisms function at the cellular level.

इस Chapter में क्या-क्या पढ़ना है?

Cell as the unit of life: इसमें आपको cell के बारे में सीखना है, जो हर जीव-जन्तु और पौधे का सबसे बुनियादी हिस्सा है।
Protoplasm: आपको protoplasm के बारे में जानकारी मिलेगी, जो cell के अंदर पाई जाती है और जिसके कारण cell जिंदा होता है।
Prokaryotic और Eukaryotic Cells का difference: इसमें आप जानेंगे कि कुछ cells में nucleus नहीं होता (prokaryotic) और कुछ में proper nucleus होता है (eukaryotic)।
Animal cell और Plant cell का difference: आप animal cells और plant cells की तुलना करना सीखेंगे, खासतौर पर cell wall, centrosome, vacuoles, plastids के मामले में।
Cell Structure और Organelles: आप cell के structure को समझेंगे यानी cell के सभी भाग (organelles) जैसे –
- Cell Membrane
- Cell Wall
- Nucleus, Nucleolus
- Mitochondria
- Endoplasmic Reticulum
- Ribosome
- Golgi Bodies
- Plastids
- Lysosomes
- Centrosome
- Vacuole

मुख्य बातें

Cell theory और उसकी तीन basic बातें समझनी हैं।
हर organelle का function समझना है।
Plant cell और animal cell में क्या differences हैं, इनको भी अच्छे से जानना है।

यह Chapter आपको biology के basic concepts मजबूत करने में मदद करेगा, ताकि आप आगे biology पढ़ सकें और जान सकें कि हर जीव चीज़ किस तरह से काम करती है।

2. THE INVENTION OF THE MICROSCOPE AND THE DISCOVERY OF CELL

The first microscope was constructed by Dutch scientist Antony van Leeuwenhoek (1632–1723). He was an ordinary public official who used to grind lenses and make microscopic observations as a hobby. It is said that he constructed around 400 microscopes. All his microscopes had a single biconvex lens and were called simple microscopes. Some of these could magnify objects up to 200 times. In Leeuwenhoek’s microscope, you had to look closely at the lens from one side and place the object on a needle-like screw point on the other side.
Robert Hooke (1635–1703), an English scientist, developed a microscope that used two lenses for higher magnification. These were known as compound microscopes. In Hooke’s microscope, the object was placed below, and light from an oil lamp was focused on it using a concave mirror.
Hooke examined a thin slice of cork under his microscope and noticed that it was made of many tiny “boxlike” compartments stacked together. These looked like the rooms (cells) in a monastery, so he called them “cells.” What Hooke saw were all dead cells—the empty box-walls.
The modern compound microscope is a much-improved version of Hooke’s original design.
After this, the invention of the electron microscope enabled scientists to discover many more facts about cells. The electron microscope can magnify up to 200,000 times, whereas an ordinary compound microscope can magnify up to about 2,000 times. The compound microscope uses light, bent by glass lenses, to magnify images, whereas the electron microscope uses beams of electrons, bent by magnets, for magnification.

PROGRESS CHECK
Name the following:
(i) The kind of microscope that consists of a single biconvex lens.
(ii) The kind of mirror used for throwing light on the object in Hooke’s microscope.
What is the maximum magnification that can usually be achieved by:
(i) a compound microscope
(ii) an electron microscope

सबसे पहला microscope Dutch scientist Antony van Leeuwenhoek (1632-1723) ने बनाया था। वो एक normal public official थे, जिन्हें lens बनाना और microscopic observations करना hobby के तौर पर अच्छा लगता था। ऐसा कहा जाता है कि उन्होंने करीब 400 microscopes बनाये। उनके सभी microscopes में एक single biconvex lens होता था और इन्हें simple microscope कहा जाता था। इनमें से कुछ microscope 200 times तक image को बड़ा कर सकते थे। Leeuwenhoek के microscope में एक side पर आँख lens के पास लगती थी और दूसरी side पर object एक needle जैसे screw point पर रखा जाता था।
Robert Hooke (1635-1703), जो एक English scientist थे, उन्होंने दो lens use करके microscope बनाया जिससे और ज्यादा magnification मिल सके। ऐसे microscopes को compound microscope कहा जाने लगा। Hooke के microscope में object नीचे stage पर रखा जाता था और oil lamp की light एक concave mirror से object पर focus की जाती थी।
Hooke ने एक पतली cork slice को अपने microscope में देखा और इसमें छोटे-छोटे “boxlike” compartments notice किये। ये box वैसे दिख रहे थे जैसे monastery में monk के rooms होते हैं, इसलिए उन्होंने इन्हें “cells” नाम दे दिया। जो cells Hooke ने देखे थे, वो सब dead cells थे, सिवाय खाली दीवारों (walls) के।
Aaj ka modern compound microscope, Hooke के design से भी ज्यादा advanced है।
इसके बाद electron microscope ke invention ने scientists को cells के बारे में और भी ज्यादा details जानने में मदद की। Electron microscope में magnification power 200,000 times तक हो सकती है, वहीं ordinary compound microscope लगभग 2,000 times तक magnify करता है। Compound microscope में glass lenses से light को bend करके image बड़ी की जाती है, जबकि electron microscope में electrons की beams को magnet से bend करा जाता है ताकि image को magnify किया जा सके।

PROGRESS CHECK
Name the following:
(i) वह microscope जिसमें single biconvex lens होता है।
(ii) Hooke के microscope में object पर light डालने के लिए किस type का mirror use होता है?
Maximum magnification कितनी achieve की जा सकती है:
(i) Compound microscope से
(ii) Electron microscope से

3. CELL THEORY

In 1838, Matthias Schleiden, a German botanist, announced that every plant is made up of a large number of cells. He added that each of these cells performed various life processes. A year later, Theodor Schwann, a German zoologist, made similar discoveries in animals. He declared that all animals and plants are composed of cells, which serve as the units of structure and function. This, in short, is called the Cell Theory, having been proposed by Schwann and Schleiden in the year 1839. Rudolf Virchow in 1858 made an addition to the cell theory by saying that all cells arise from pre-existing cells.

The Cell Theory states three major points:

The cell is the smallest unit of structure of all living things.
The cell is the unit of function of all living things.
All cells arise from pre-existing cells.

What does the cell theory mean? Take two examples, a plant such as mango and an animal such as a frog.

Structural Unit: If we take any part of the body of a frog or any part of a mango plant and examine it under a microscope, it will show a cellular structure.
Functional Unit: Any function in the body of the frog or in the mango plant is due to the activity in its cells. For example, movement of the frog is due to the contractions of muscle cells, food is digested by the enzymes which the cells of the gut secrete, digested food is absorbed by the cells and absorbed food is used up in cells for various metabolic activities. In a mango plant, photosynthesis occurs in the cells of leaves, the root cells absorb water from the soil, and so on.
Cells die and are replaced: The body of the frog, or of the mango tree, is composed of millions and millions of cells. Many of these cells continuously die and are replaced by new ones which are formed by the division of younger cells. Formation of cells from pre-existing cells is a never-ending chain.
All life starts as a single cell: The life of the frog and the life of the mango tree started as an egg and as a seed respectively. The egg was a single cell produced by the cells of the ovary of the mother frog. The mango seed had an embryo which also started as a single cell in the ovary of the flowers of the parent mango tree.

1838 में Matthias Schleiden, जो एक German Botanist थे, ने announce किया कि हर plant बहुत सारी cells से बना होता है। उन्होंने कहा कि ये हर cell कई life processes perform करता है। एक साल बाद, Theodor Schwann, जो एक German Zoologist थे, ने animals में भी ऐसा ही पाया। उन्होंने कहा कि सभी animals और plants cells से बने होते हैं, जो उनकी structure और function की units होती हैं। इसे ही short में Cell Theory कहते हैं, जिसे Schwann और Schleiden ने 1839 में propose किया था। 1858 में Rudolf Virchow ने इस theory में add किया कि सभी cells पहले से मौजूद cells से ही बनती हैं।

Cell Theory के तीन मुख्य points हैं:

Cell सभी living चीजों की सबसे छोटी structural unit है।
Cell सभी living चीजों की functional unit है।
सभी cells पहले से मौजूद cells से बनती हैं।

अब समझते हैं Cell Theory का मतलब। ले लेते हैं दो examples – एक plant जैसे mango और एक animal जैसे frog।

Structural Unit: अगर हम frog के body का कोई भाग या mango plant का कोई part microscope में देखें, तो हमें cells ही नजर आएंगी।
Functional Unit: frog या mango के शरीर का कोई भी काम cells की activity की वजह से होता है। जैसे frog का movement muscle cells के contract होने से होता है, खाना digest enzymes cells produce करती हैं, digested food cells absorb करती हैं और वो food cells में energy या बाकी metabolic कामों के लिए use होता है। mango plant में photosynthesis leaves की cells में होता है, और root cells मिट्टी से पानी absorb करती हैं।
Cells मरती हैं और नई बनती हैं: frog या mango के body में लाखों करोड़ों cells होते हैं। उनमें से कई cells continuously मरती हैं और नई cells young cells के division से बनती रहती हैं। ये सिलसिला चलता रहता है।
सारा जीवन एक single cell से शुरू होता है: frog का life एक egg से शुरू होता है, और mango plant का life seed से। ये egg frog की mother के ovary की cells से बनती है। mango seed का embryo भी एक single cell से शुरू होता है, जो parent mango के flower के ovary में होता है।

4. CELLS – HOW NUMEROUS?

The number of cells in an organism depends on its size — the larger the organism, the greater the number of cells in its body.

Single-celled organisms: Many small plants and animals consist of just one cell. Examples are bacteria, yeast, and amoeba.
Few-celled organisms: Some very small plants and animals have relatively few cells — just a few hundred or a few thousand. Examples include Spirogyra and Volvox.
Multi-celled organisms: Most plants and animals we see, including humans, have millions or billions of cells. Examples are human beings and mango trees.

An average adult human has approximately:

1,000 million million (trillion) cells,
10,000 million nerve cells in the brain cortex,
5-6 million red blood cells and 7,000 white blood cells per cubic millimeter of blood.

Organism का size जितना बड़ा होगा, उसके body में cells की संख्या भी उतनी ज्यादा होगी।

Single-celled organisms: कुछ छोटे plants और animals सिर्फ एक ही cell से बने होते हैं। जैसे bacteria, yeast, amoeba।
Few-celled organisms: कुछ छोटे plants और animals में थोड़ी संख्या में cells होती हैं, जैसे Spirogyra, Volvox।
Multi-celled organisms: ज्यादातर plants और animals, जैसे humans और mango के पेड़, लाखों करोड़ों cells से बने होते हैं।

एक average size adult human body में लगभग:

1,000 million million यानी trillion cells होती हैं,
दिमाग़ की cortex में 10,000 million nerve cells होते हैं,
और blood में 5-6 million red blood cells और 7 हजार white blood cells हर cubic millimeter में होते हैं।

5. CELLS – HOW SMALL?

Cells are very small and can only be seen with the help of a microscope.

The smallest cells are bacteria (0.3 to 5 micrometers).
Human red blood cells are about 7 micrometers in size.
The longest cells are nerve cells, which can extend from the fingertip to the spinal cord.
The largest cells are bird eggs, mainly the central yellow sphere. For example, the ostrich egg is the largest single cell.

SMALLNESS OF CELLS: A GREATER EFFICIENCY

Cells usually remain small for two main reasons:

Different parts of a cell need to communicate rapidly for efficient functioning.
Small cells have a larger surface area relative to their volume, which helps better diffusion of substances in and out of the cell.

For understanding surface area to volume ratio, imagine a cube with sides of 2 mm.

Total surface area = 2 × 2 × 6 = 24 mm²
If you cut this cube into eight smaller cubes by halving each side to 1 mm:
- Surface area of each small cube = 1 × 1 × 6 = 6 mm²
- Total surface area of all 8 cubes = 6 × 8 = 48 mm², which is double the original.

The total volume remains the same but the total surface area increases, allowing more efficient exchange of materials.

Small size of cell presents a larger surface area / volume ratio

A large surface area relative to volume means:

More nutrients can diffuse into the cell,
More metabolic wastes can diffuse out,
Respiratory gases (oxygen in, carbon dioxide out) can move more efficiently,
Damage to the cell can be repaired easily.

Organism का size जितना बड़ा होगा, उसके body में cells की संख्या भी उतनी ज्यादा होगी।

Single-celled organisms: कुछ छोटे plants और animals सिर्फ एक ही cell से बने होते हैं। जैसे bacteria, yeast, amoeba।
Few-celled organisms: कुछ छोटे plants और animals में थोड़ी संख्या में cells होती हैं, जैसे Spirogyra, Volvox।
Multi-celled organisms: ज्यादातर plants और animals, जैसे humans और mango के पेड़, लाखों करोड़ों cells से बने होते हैं।

एक average size adult human body में लगभग:

1,000 million million यानी trillion cells होती हैं,
दिमाग़ की cortex में 10,000 million nerve cells होते हैं,
और blood में 5-6 million red blood cells और 7 हजार white blood cells हर cubic millimeter में होते हैं।

Cells बहुत छोटी होती हैं, इन्हें बिना microscope के नहीं देखा जा सकता।

सबसे छोटी cells bacteria की होती हैं (0.3 से 5 micrometer तक),
human red blood cells लगभग 7 micrometer की होती हैं,
longest cells nerve cells होती हैं जो finger tips से spinal cord तक extend कर सकती हैं,
सबसे बड़ी cells bird के eggs होते हैं, जैसे ostrich का अंडा, जो सबसे बड़ा single cell है।

Smallness of Cells: ज्यादा efficient होने का कारण

Cells आम तौर पर छोटे ही रहते हैं क्योंकि:

Cell के अलग-अलग parts को जल्दी communicate करना पड़ता है ताकि वह अच्छा काम कर सके।
छोटे cells का surface area उनके volume की तुलना में ज्यादा होता है, जिससे materials का exchange (diffusion) जल्दी और बेहतर होता है।

मानिए एक cube है जिसके हर side 2 mm है:

इसका surface area = 2 × 2 × 6 = 24 mm²
अगर इसे 8 छोटे cubes में काटा जाये, हर side 1 mm का:
- हर छोटे cube का surface area = 1 × 1 × 6 = 6 mm²
- आठों cubes का total surface area = 6 × 8 = 48 mm² (जो कि original से double है)

लेकिन total volume दोनों cases में same रहता है। इसका मतलब है कि छोटी cells ज्यादा surface area provide करती हैं, जिससे substances का efficient exchange होता है।

Cell का छोटा size surface area/volume ratio ज्यादा दिखाता है

इसका फायदा यह होता है कि:

ज्यादा nutrients cell के अंदर आ पाते हैं,
metabolic wastes जल्दी बाहर निकल पाती हैं,
oxygen अंदर आता और carbon dioxide बाहर जाता है अच्छी तरह,
और cell damage होने पर उसे repair भी जल्दी किया जा सकता है।

6. CELL SHAPES – TO SUIT FUNCTIONAL REQUIREMENT

Cells come in many different shapes, and their shape is often related to the function they perform in the body. Here are some examples:
Epithelial cells: These are flat and have a protective role (like those on our skin).
Human red blood cells: They are circular and biconcave, which allows them to pass easily through narrow capillaries and helps in oxygen transport.
White blood cells: These have an amoeboid shape (like amoeba), and can change shape to squeeze out through capillary walls.
Nerve cells: These are long and thin, which helps them carry signals (“impulses”) from different body parts to the brain and vice versa.
Muscle cells: Long and contractile; they help in movement and pulling actions.
Guard cells (in plants): Bean-shaped cells found near stomatal pores on leaves, which help control opening and closing of pores for gas exchange.
Cells take shapes that are best suited for the job they do.

PROGRESS CHECK (With Answers)
Name the following:
(i) Any two one-celled organisms:
Amoeba, yeast
(ii) The longest cells in animals:
Nerve cells
(iii) Amoeboid cells in humans:
White blood cells (WBCs)
(iv) Outermost layer in plant cells:
Cell wall
(v) A cell component which is visible only in cell division stages:
Chromosomes
List three categories of substances which ensure greater diffusion due to large surface/volume ratio of the cells:
Nutrients
Wastes
Respiratory gases (oxygen and carbon dioxide)

किसी भी cell का shape उसका काम बताता है। अलग-अलग cells अलग shapes में मिलती हैं, और उनका काम भी उसी हिसाब से होता है। उदाहरण के लिए:
Epithelial cells: ये flat और protective होती हैं, जैसे हमारी skin पर।
Human red blood cells: इनका shape circular और biconcave होता है जिससे ये narrow capillaries में आसानी से जा सकती हैं और oxygen transport करती हैं।
White blood cells: इनका shape amoeboid (यानि amoeba जैसा) होता है, जिससे ये shape बदलकर capillary walls से बाहर निकल सकती हैं।
Nerve cells: लंबी और पतली होती हैं, जिससे ये signal (impulse) body parts से brain तक या brain से body parts तक ले जा सकती हैं।
Muscle cells: लंबी और contractile होती हैं, जिससे movement और pulling होता है।
Guard cells (plants में): ये bean-shaped होती हैं और leaf के stomatal pores को खोलने और बंद करने का काम करती हैं। इससे gas exchange control होता है।
Cells का shape उनके काम के हिसाब से best designed होता है।

PROGRESS CHECK (Answers Hindi-English Mix)
इनका नाम बताएं:
(i) कोई भी दो single-celled organisms:
Amoeba, yeast
(ii) Animals में सबसे लंबी cells:
Nerve cells
(iii) Human body में amoeboid cells:
White blood cells (WBCs)
(iv) Plant cell की outermost layer:
Cell wall
(v) ऐसा cell component जो सिर्फ cell division के time दिखता है:
Chromosomes
Cell के surface/volume ratio ज्यादा होने पर किन तीन categories के substances का diffusion better होता है?
Nutrients
Wastes
Respiratory gases (oxygen, carbon dioxide)

7. STRUCTURE OF A CELL

A cell has a general structure that is common in both plant and animal cells. Most cells have three main parts:
Cell Membrane (Plasma Membrane)
It is the outer boundary of the cell which controls what enters and exits the cell.
Cytoplasm
This is the jelly-like substance inside the cell where most chemical reactions happen. It contains various cell organelles (little organs) that do specific jobs.
Nucleus
The control center of the cell. It contains genetic material (DNA) and regulates cell activities.

PARTS OF A CELL (Blue Table Explanation)
Living Parts:
Cell Membrane: Thin, flexible, living boundary that controls what goes in and out (selectively permeable).
Endoplasmic Reticulum: Network of membranes that transports materials, can be rough (with ribosomes) or smooth.
Mitochondria: “Powerhouse” – makes energy by respiration.
Golgi Apparatus: Packs and ships proteins, helps in secretion.
Ribosomes: Protein synthesis happens here.
Lysosomes: Digestion and waste removal (“suicide bags”).
Centrosome: Only in animal cells, helps in cell division.
Plastids: Only in plant cells, stores food or pigments (includes chloroplast for photosynthesis).
Non-living Parts:
Cell Wall: Only in plant cells, made of cellulose. Gives support and protection.
Granules: Stores food, pigments, or waste.
Vacuoles: Storage places inside the cell, big in plant cells.
In the Cytoplasm:
Endoplasmic Reticulum
Mitochondria
Golgi Apparatus
Ribosomes
Lysosomes
Centrosome (animal cell only)
Plastids (plant cell only)
Granules
Vacuoles
In the Nucleus:
Nuclear Membrane: Boundary around nucleus.
Nucleoli: Makes ribosomes.
Chromatin Fibers: DNA threads inside nucleus.
Nucleoplasm: Fluid inside nucleus.

7.1 CELL MEMBRANE and CELL WALL

Cell Membrane (Plasma Membrane)

The cell membrane is the thin, flexible outer covering of every cell.
It has tiny pores that allow certain substances to enter and leave the cell.
The cell membrane is selectively permeable, which means it lets only selected materials pass through.
In plant cells, the membrane is just inside the cell wall.

Cell Wall (Only in Plant Cells)

The cell wall is an extra, rigid, non-living layer outside the cell membrane.
It is mainly made of cellulose.
The cell wall gives the plant cell shape, protection and a certain amount of rigidity.
Unlike the membrane, the cell wall is freely permeable, allowing substances in solution to easily enter or leave.
The cell wall’s main job is structure and protection, not controlling what goes in or out.

7.2 CYTOPLASM

Cytoplasm
Cytoplasm is a semi-liquid, jelly-like substance inside the cell membrane.
It is colorless, transparent, and watery under a microscope.
Most chemical reactions of the cell happen in the cytoplasm.
Sub-parts/Organelles in Cytoplasm:
Endoplasmic Reticulum (ER):
A network of double membranes found throughout the cytoplasm.
Connects outer cell membrane to nuclear membrane.
ER can be rough (with attached ribosomes) or smooth (without ribosomes).
Helps transport materials and forms the supporting framework for the cell.
Ribosomes:
Tiny granules found freely in cytoplasm or attached to ER.
Known as the “protein factories” where proteins are made.
Mitochondria:
Double-walled, sausage-shaped organelles.
Known as the “powerhouse” of the cell.
Site of cellular respiration and energy (ATP) production.
Golgi Apparatus:
Packs and distributes proteins and other materials.
Mostly found near the nucleus.
Lysosomes:
Small vesicles with digestive enzymes.
Help digest food, destroy foreign substances, and remove damaged cell parts.
Centrosome (only in animal cells):
Helps in cell division.
Plastids (only in plant cells):
Stores food and pigments, includes chloroplasts for photosynthesis.
(a) Leucoplasts
These are colorless plastids without any pigment.
Their primary function is to store food materials like starch.
For example, cells in potato tubers have numerous leucoplasts to store starch.
(b) Chromoplasts
These plastids have color pigments other than green.
They are responsible for giving colors like yellow, orange, and red to flowers and fruits.
The pigments found in chromoplasts include xanthophyll (yellow) and carotene (orange-red).
Chromoplasts help in attracting insects for pollination by coloring petals and fruits.
(c) Chloroplasts
These are green plastids containing the green pigment chlorophyll.
Chloroplasts are responsible for photosynthesis – the process by which plants make their own food using sunlight, carbon dioxide, and water.
Chloroplasts also contain other pigments like carotenoids but the green chlorophyll masks these colors.
They have their own DNA and can divide independently within the cell.
Non-living inclusions in cytoplasm:
Granules (food, pigment, waste)
Vacuoles (storage spaces, especially large in plant cells)

7.3 NUCLEUS

Nucleus is the most important part of a cell. It acts as the “control center” of the cell and has several key functions:

Regulates and Coordinates Activities: The nucleus controls all the activities inside the cell, like growth, metabolism, and reproduction.
Cell Division: It plays a major role in cell division (mitosis and meiosis), making sure genetic material is properly passed to new cells.
Contains Genetic Material: Inside the nucleus are chromatin fibers, which are made of DNA. DNA contains genes that carry hereditary information from parents to offspring.

Structure of the Nucleus:

Nuclear Membrane: A thin double-layered covering around the nucleus, with tiny pores that allow substances to enter and leave.
Nucleoplasm: The jelly-like substance inside the nucleus.
Nucleolus: A small, round body (sometimes more than one) inside the nucleus. It helps with the production of ribosomes, which make proteins.
Chromatin Fibres: Thin threads seen in the resting nucleus. During cell division, these fibers condense and become chromosomes.

Types of Cells:

Prokaryotic cells: Do not have a proper nuclear membrane. Their genetic material is free in the cytoplasm (example: bacteria).
Eukaryotic cells: Have a well-defined nuclear membrane (example: plant and animal cells).

Additional Points:

The number of chromosomes is fixed for each species (humans have 46 chromosomes).
Genes are specific segments of DNA and are responsible for inherited characters.

Cell की structure almost सभी plant और animal cells में similar होती है। इसमें मुख्य तौर पर ये तीन parts होते हैं:
Cell Membrane (Plasma Membrane)
Cell की outer boundary होती है, जो decide करती है क्या अंदर जाए और क्या बाहर आए (selectively permeable)।
Cytoplasm
यह cell के अंदर jelly जैसा substance होता है जिसमें अलग-अलग organelles होती हैं और chemical reactions होती हैं।
Nucleus
ये cell का control center होता है, इसमें genetic material (DNA) रहता है और cell के सारे activities regulate होते हैं।

PARTS OF A CELL (Blue Table – Hindi-English Mix)
Living Parts:
Cell Membrane: पतली, flexible boundary जो अंदर-बाहर substances को control करती है।
Endoplasmic Reticulum: एक network जो cell के अंदर materials को transport करता है, rough (ribosomes के साथ) या smooth हो सकता है।
Mitochondria: Powerhouse है, respiration से energy देता है।
Golgi Apparatus: Proteins को pack और ship करता है, secretion में help करता है।
Ribosomes: यहां protein synthesis होती है।
Lysosomes: Cell के waste को digest करता है, “suicide bag” भी कहते हैं।
Centrosome: सिर्फ animal cells में होता है, cell division में काम करता है।
Plastids: सिर्फ plant cells में होते हैं, food या pigments store करते हैं (chloroplast photosynthesis करता है)।
Non-living Parts:
Cell Wall: सिर्फ plant cells में होती है, cellulose से बनी होती है, support और protection देती है।
Granules: Food, pigments या waste को store करता है।
Vacuoles: Storage space होता है, plant cells में बड़े होते हैं।
Cytoplasm में पाए जाने वाले:
Endoplasmic Reticulum
Mitochondria
Golgi Apparatus
Ribosomes
Lysosomes
Centrosome (सिर्फ animal cell में)
Plastids (सिर्फ plant cell में)
Granules
Vacuoles
Nucleus में पाए जाने वाले:
Nuclear Membrane (nucleus का boundary)
Nucleoli (ribosomes बनाता है)
Chromatin Fibers (DNA के threads)
Nucleoplasm (nucleus के अंदर का fluid)

7.1 सेल मेम्ब्रेन और सेल वॉल

Cell Membrane (Plasma Membrane)

Cell membrane हर cell की बाहर की पतली, flexible layer होती है।
इसमें छोटे pores होते हैं, जिससे selected substances अंदर जा सकते हैं या बाहर आ सकते हैं।
Cell membrane selectively permeable होती है, यानि सिर्फ कुछ चीजों को ही अंदर-बाहर जाने देती है।
Plant cells में membrane cell wall के just अंदर होती है।

Cell Wall (सिर्फ Plant Cells में)

Cell wall एक extra, rigid, non-living layer है, जो cell membrane के बाहर होती है।
Cellulose से बनी होती है।
Cell wall plant cell को proper shape, protection और rigidity देती है।
Cell wall freely permeable होती है मतलब कि जितने भी substances solution में होते हैं, वो अंदर-बाहर आसानी से जा सकते हैं।
Cell wall mainly structure और protection के लिए होती है, membrane की तरह filtering का काम नहीं करती।

7.2 साइटोप्लाज्म (Cytoplasm)

Cytoplasm
Cytoplasm cell membrane के अंदर का semi-liquid, jelly जैसा substance होता है।
Microscope में देखने पर ये colorless, transparent और watery दिखता है।
Cell के ज्यादातर chemical reactions cytoplasm में होते हैं।
Cytoplasm में क्या-क्या होता है (Organelles and Inclusions):
Endoplasmic Reticulum (ER):
Cytoplasm में फैला हुआ double membrane का network।
बाहर cell membrane और अंदर nucleus से जुड़ा रहता है।
Rough ER में ribosomes लगे होते हैं, Smooth ER में नहीं।
Cell में materials को transport करने, और supporting framework बनाने में help करता है।
Ribosomes:
बहुत छोटे granules हैं, cytoplasm में free या ER पर attached रहते हैं।
इन्हें “protein factories” कहा जाता है क्योंकि proteins यहीं बनते हैं।
Mitochondria:
Double-walled, sausage-shaped bodies।
“Powerhouse” है cell का।
Respiration और energy (ATP) यहीं बनती है।
Golgi Apparatus:
Proteins और दूसरी चीजों को pack और distribute करता है।
Usually nucleus के पास होता है।
Lysosomes:
छोटे vesicles जिनमें digestive enzymes होते हैं।
Food digest करते हैं, foreign substances और damaged cell parts को destroy करते हैं।
Centrosome (सिर्फ animal cells में):
Cell division में important role play करता है।
Plastids (सिर्फ plant cells में):
Pigments और food store करते हैं, chloroplasts photosynthesis करते हैं।
(a) Leucoplasts
ये colorless plastids होते हैं, जिनमें कोई pigment नहीं होता।
इनका मुख्य काम food materials जैसे starch को store करना होता है।
उदाहरण के तौर पर, potato के cells में बहुत सारे leucoplasts होते हैं जो starch जमा करते हैं।
(b) Chromoplasts
ये plastids color pigments रखते हैं जो green नहीं होते।
ये फूलों और फलों को पीला, नारंगी और लाल रंग देने के लिए जिम्मेदार होते हैं।
Chromoplasts में pigments जैसे xanthophyll (yellow) और carotene (orange-red) पाए जाते हैं।
Chromoplasts की वजह से flowers और fruits रंगदार होते हैं जो insects को attract करते हैं।
(c) Chloroplasts
ये हरे plastids होते हैं जिनमें हरा pigment chlorophyll होता है।
Chloroplasts का काम होता है photosynthesis – plants का अपने लिए खाना बनाना जो sunlight, carbon dioxide, और पानी का उपयोग करके होता है।
Chloroplasts में carotenoids जैसे अन्य pigments भी होते हैं, लेकिन हरा chlorophyll उनकी रंगत छुपाता है।
इनमें खुद का DNA होता है और ये अपने आप cell में divide भी कर सकते हैं।
Cytoplasm में non-living inclusions भी होते हैं:
Granules (food, pigment, waste)
Vacuoles (storage spaces, plant cells में बड़े होते हैं)

7.3 न्यूक्लियस

Nucleus किसी भी cell का सबसे important पार्ट है। इसे cell का “control center” भी कहते हैं और ये कई जरूरी काम करता है:

Activities Regulate और Coordinate करता है: Nucleus cell के अंदर होने वाली सारी activities जैसे growth, metabolism, reproduction को control करता है।
Cell Division: Nucleus cell division (mitosis और meiosis) करवाने में main role play करता है ताकि genetic material सही तरीके से नई cells में पहुंचे।
Genetic Material Store करता है: Nucleus के अंदर chromatin fibers होते हैं, जो DNA से बने होते हैं। इसी DNA में genes होते हैं, जो heredity यानी parents से बच्चों में आने वाली qualities को carry करते हैं।

Nucleus की Structure:

Nuclear Membrane: Nucleus को चारों तरफ से एक thin double-layered membrane घेरती है, जिसमें छोटे-छोटे pores होते हैं ताकि substances nucleus में आ-जा सकें।
Nucleoplasm: Nucleus का अंदर का jelly जैसा हिस्सा, जिसमें बाकी सब चीजें रहती हैं।
Nucleolus: Nucleus के अंदर एक (या कभी-कभी एक से ज्यादा) गोल structure होता है, जो ribosome बनाता है (protein synthesis में help करता है)।
Chromatin Fibers: Nucleus के अंदर thin threads जैसे दिखते हैं। Cell division के time ये condense होकर chromosome बन जाते हैं।

Cells के Types:

Prokaryotic cells: इनमें nuclear membrane proper नहीं होती, genetic material cytoplasm में free रहता है (जैसे bacteria)।
Eukaryotic cells: इनमें nuclear membrane proper होती है (जैसे plant और animal cells)।

Extra Points:

हर species में chromosomes की संख्या fix होती है (human में 46 यानी 23 pairs)।
Genes small DNA segments होते हैं, जो inherited characters के लिए responsible होते हैं।

Chromosome Numbers of Some Common Animals and Plants

Every species has a fixed number of chromosomes in its cells, which is a characteristic feature of that species. Chromosomes are structures inside the nucleus made of DNA and proteins, containing genetic information.

हर species के cells में chromosomes की संख्या fix होती है। Chromosomes nucleus में होते हैं, ये DNA और protein से बने होते हैं, और genetic information रखते हैं।

Here are some examples of chromosome numbers in different plants and animals:

कुछ plants और animals में chromosome numbers:

Organism	Number of Chromosomes
Human	46
Ascaris (Roundworm)	2
Garden Pea	14
Onion	16
Maize	20
Honey-bee	32
Lion	38
Mouse	40
Wheat	42
Potato	48
Chimpanzee	48
Monkey	54
Chicken	78
Dog	78
Sugarcane	80
Crayfish	200
Some insects	More than 1000

Note: The number of chromosomes can be very different even between closely related species.
ध्यान दें: Chromosome की संख्या species-species में अलग हो सकती है, बहुत high या low भी हो सकती है।

Genes, not the number of chromosomes, determine the characteristics (traits) of an organism. For example, a lion, tiger, and house cat all have 38 chromosomes, but they look different because of their different genes.

Genes ही actual में किसी organism के traits तय करते हैं, सिर्फ chromosome की संख्या नहीं। जैसे lion, tiger और house-cat के chromosomes एक जैसे (38) हैं पर genes अलग-अलग होने की वजह से ये अलग दिखते हैं।

DNA – Fingerprinting

DNA fingerprinting is a scientific technique used to identify people based on their unique DNA patterns.

Each person has a unique DNA sequence (except identical twins).
In this process, scientists analyze specific regions of DNA that vary greatly among individuals.
DNA fingerprinting can be used for:
- Identifying people in criminal cases
- Determining parentage (who is the real parent)
- Solving cases with unidentifiable bodies
Example: In a famous case in Delhi in 1995, DNA from a charred body was matched with the parents’ DNA to confirm the victim’s identity.

Just like fingerprints, everyone’s DNA pattern is unique, which is why this method is called “DNA fingerprinting.”

DNA fingerprinting एक scientific तकनीक है जिससे किसी भी person की पहचान उसके DNA pattern से की जाती है।

हर इंसान का DNA pattern unique होता है (सिवाय identical twins के)।
इस technique में scientist DNA के कुछ ऐसे हिस्सों को चेक करते हैं जो हर इंसान में differently arranged होते हैं।
DNA fingerprinting किन चीजों में useful है:
- Crime केस में व्यक्ति की पहचान
- Parentage check करना (किसके बच्चे हैं)
- मृत व्यक्ति की पहचान जहाँ body पहचान में नहीं आ रही हो
Example: 1995 में Delhi में एक murder case में जल चुकी body का DNA parents से match कर के identity confirm की गई थी।

जैसे हर इंसान की उंगलियों के निशान अलग होते हैं, वैसे ही DNA pattern भी unique होता है इसलिए इसे “DNA fingerprinting” कहते हैं।

8. THE PLANT AND ANIMAL CELLS

Both plant and animal cells share a basic structure—cell membrane, cytoplasm, nucleus, endoplasmic reticulum, Golgi bodies, mitochondria, and ribosomes. However, there are key differences that help to easily distinguish between these two types of cells. These differences are important to understand, especially in topics like cell wall, centrosome, vacuoles, and plastids.

Differences Between Plant and Animal Cells (English)

Feature	Plant Cells	Animal Cells
Cell Wall	Present, made of cellulose	Absent
Centrosome	Absent	Present
Vacuoles	One or few, large and permanent	Small, many, temporary, mainly for secretion/excretion
Plastids	Present (chloroplasts, chromoplasts, leucoplasts)	Absent
Size	Usually larger, more well-defined outline	Usually smaller, boundaries less distinct
Cytoplasm	Usually not very dense	Dense and granular
Cytoplasm arrangement	Thin lining at periphery, vacuole occupies most space	Fills most of the cell

Explanation:

Plant cells have a rigid cell wall made of cellulose; animal cells do not have a cell wall.
Large vacuoles are prominent in plant cells, storing water and other substances, while animal cells have small, temporary vacuoles.
Centrosome is found only in animal cells; it helps in cell division.
Plant cells always contain plastids (like chloroplasts for photosynthesis), whereas animal cells completely lack plastids.
The cytoplasm in plant cells forms a thin lining against the wall due to a large central vacuole, while in animal cells, cytoplasm fills almost the entire cell and is denser.

अगर कहीं confusion है तो हमेशा ये chart देखकर plant और animal cell को पहचान सकते हैं!

फीचर	प्लांट सेल	एनिमल सेल
Cell Wall	Cell wall होती है, cellulose से बनी होती है	Cell wall नहीं होती
Centrosome	Centrosome नहीं मिलता है	Centrosome होता है
Vacuole	Vacuole बड़ी और permanent रहती है (एक या ज्यादा)	Vacuole छोटी, temporary और secretion/excretion के लिए होती है
Plastids	Plastids होते हैं – जैसे chloroplasts, chromoplasts	Plastids नहीं होते
Size	Usually size बड़ा और outline साफ होती है	Usually छोटा और border less clear होती है
Cytoplasm	Cytoplasm dense नहीं होता, vacuole ज़्यादा जगह लेती है	Cytoplasm dense और granules वाली होती है
Cytoplasm का arrangement	Cytoplasm cell wall के किनारे thin lining बनाता है	Cell का almost सारा part cytoplasm से भरा होता है

Explanations ( समझना ) :

Plant Cell में कड़ा cell wall होती है, जो cellulose से बनी होती है; animal cell में cell wall नहीं होती।
Plant cell में बड़ी vacuole होती है जिसमें पानी और दूसरी चीजें store रहती है, जबकि animal cell में vacuole छोटी होती है और ज़्यादातर temporary या secretion/excretion के लिए होती है।
Centrosome सिर्फ animal cell में मिलता है, cell division में काम आता है।
Plant Cell में plastids जैसे chloroplasts दिखेंगे, जिससे photosynthesis होता है, animal cell में ऐसा कुछ नहीं मिलेगा।
Plant cell में cytoplasm दिया हुआ vacuole के किनारे thin layer सा ही रहता है, जबकि animal cell में cytoplasm पूरा cell में फैला रहता है।
Plant cell का आकार अक्सर animal cell से बड़ा और साफ दिखता है।

9. Protoplasm

Protoplasm is the living substance inside a cell. It is often called the “living material” because it carries out all the vital processes of life in the cell. It consists mainly of water, proteins, lipids, carbohydrates, mineral salts, and various chemicals.

Protoplasm is very complex and varies slightly from cell to cell, but the basic elements such as carbon, hydrogen, oxygen, nitrogen, sulphur, phosphorus, and iron are common to all living cells.

Scientists have not been able to analyze protoplasm exactly because once it is removed from the living cell, it loses its properties and does not behave like living matter.

Protoplasm mainly consists of two parts:

Nucleus – the control center of the cell.
Cytoplasm – the jelly-like substance surrounding the nucleus where most cellular activities occur.

In summary, the cell is formed by living protoplasm enclosed in a cell membrane (plus an outer cell wall in plants).

Protoplasm एक living substance होता है जो cell के अंदर पाया जाता है। इसे “living material” भी कहा जाता है क्योंकि यही cell के अंदर सारे जरूरी life processes करता है।

Protoplasm मुख्य रूप से water, proteins, lipids, carbohydrates, mineral salts और कई chemicals से मिला होता है।

Protoplasm बहुत complex होता है और cell से cell थोड़ा अलग हो सकता है, लेकिन उसके basic elements जैसे carbon, hydrogen, oxygen, nitrogen, sulphur, phosphorus और iron सभी cells में common होते हैं।

वैज्ञानिक protoplasm की exact analysis नहीं कर पाए हैं क्योंकि जब इसे living cell से बाहर निकाल दिया जाता है, तो वह living matter जैसा behavior नहीं करता।

Protoplasm के दो मुख्य भाग होते हैं:

Nucleus – cell का control center।
Cytoplasm – jelly जैसी substance जो नाभिक के आस-पास होता है और जहाँ cell के ज्यादा activities होती हैं।

इसीलिए कहा जाता है कि cell living protoplasm का बना होता है जो cell membrane में enclosed होता है (plants में इसमें extra outer wall भी होता है)।

10. PROKARYOTIC AND EUKARYOTIC CELLS

Cells are broadly classified into two types based on the presence or absence of a well-defined nucleus:

Prokaryotic Cells

These cells do not have a well-defined nucleus or nuclear membrane.
Genetic material (DNA) floats freely in the cytoplasm in an unorganized form called chromatin.
They have smaller ribosomes and lack membrane-bound organelles like mitochondria and chloroplasts.
Prokaryotes are considered the most primitive and earliest forms of life (examples: bacteria, blue-green algae).

Eukaryotic Cells

These cells possess a distinct nucleus enclosed by a nuclear membrane.
Their DNA is organized into multiple chromosomes within the nucleus.
They have larger ribosomes and many membrane-bound organelles such as mitochondria, endoplasmic reticulum, chloroplasts (in plants).
Eukaryotic cells make up all plants, animals, fungi, and protists—more complex, advanced organisms.

Table 2.3: Differences Between Prokaryotic and Eukaryotic Cells

Feature	Prokaryotic Cell	Eukaryotic Cell
Nuclear Membrane	Absent	Present
DNA	Single circular DNA floating in cytoplasm	Multiple linear chromosomes inside nucleus
Ribosomes	Smaller (70S)	Larger (80S)
Membrane-bound Organelles	Absent (no mitochondria, chloroplasts, etc.)	Present (mitochondria, ER, chloroplasts, etc.)
Examples	Bacteria, Blue-green algae	Plants, Animals, Fungi

PROGRESS CHECK with Answers

Name the part of a cell in which:
(i) Many chemical reactions occur with enzymes?
Answer: Cytoplasm
(ii) A network of chromatin fibres occurs?
Answer: Nucleus
(iii) Cellulose forms the main component?
Answer: Cell wall
Differentiate between:
(i) An organ and an organelle?
Answer: An organ is a tissue group in an organism performing a specific function, while an organelle is a tiny structure inside a cell performing a specific job.
(ii) A plant cell and an animal cell pertaining to presence of plastids?
Answer: Plant cells contain plastids (like chloroplasts) but animal cells do not.

Name the cell organelles concerned with:
(i) Secretion of enzymes?
Answer: Golgi apparatus
(ii) Trapping solar energy?
Answer: Chloroplasts
(iii) Synthesis of proteins?
Answer: Ribosomes
(iv) Intracellular digestion?
Answer: Lysosomes
(v) Production of ATP?
Answer: Mitochondria
Name the cell part which is:
(i) Composed of cellulose?
Answer: Cell wall
(ii) Formed of irregular network of tubular double membranes?
Answer: Endoplasmic reticulum
(iii) A clear space with water or other substances in solution?
Answer: Vacuole
True or False? If false, correct it:
(i) Prokaryotic cells have larger ribosomes.
Answer: False, prokaryotic cells have smaller ribosomes.
(ii) Eukaryotic cells have mitochondria.
Answer: True
(iii) Amoeba is an example of prokaryotes.
Answer: False, Amoeba is a eukaryote.
(iv) Bacteria have no nuclear membrane but possess chloroplasts.
Answer: False, bacteria have no nuclear membrane and no chloroplasts.

Cells को दो types में बांटा जाता है जो nucleus के presence पर depend करता है:

प्रोकैरियोटिक सेल्स

इनमें well-defined nucleus या nuclear membrane नहीं होता।
Genetic material (DNA) cytoplasm में freely रहता है और इसे chromatin कहते हैं।
Ribosomes छोटे होते हैं और mitochondria या chloroplast जैसे membrane-bound organelles नहीं होते।
ये primitive और सबसे पुराने प्रकार के life forms हैं (जैसे bacteria और blue-green algae)।

युकैरियोटिक सेल्स

इनमें एक distinct nucleus होता है जो nuclear membrane से घिरा होता है।
DNA nucleus में organized chromosomes के रूप में होता है।
Ribosomes बड़े होते हैं और mitochondria, endoplasmic reticulum, chloroplast जैसे कई organelles होते हैं।
Plants, animals, fungi और protists जैसे complex organisme युकैरियोटिक हैं।

टेबल 2.3 – प्रोकैरियोटिक और युकैरियोटिक सेल्स के बीच अंतर

फीचर	प्रोकैरियोटिक सेल्स	युकैरियोटिक सेल्स
Nuclear Membrane	नहीं होता	होता है
DNA	Circular, cytoplasm में free	Linear chromosomes, nucleus के अंदर
Ribosomes	छोटे (70S)	बड़े (80S)
Membrane-bound Organelles	नहीं होता	mitochondria, chloroplasts, ER होते हैं
उदाहरण	bacteria, blue-green algae	plants, animals, fungi

प्रोग्रेस चेक के उत्तर

(i) Enzymes की मदद से कई chemical reactions कहाँ होती हैं?
उत्तर: Cytoplasm
(ii) Chromatin fibers किसमें होते हैं?
उत्तर: Nucleus
(iii) Cellulose मुख्य रूप से कहाँ पाया जाता है?
उत्तर: Cell wall

(i) Organ और organelle में अंतर बताएं?
उत्तर: Organ शरीर का tissue group होता है, organelle cell के अंदर एक छोटी structure जो अपना काम करती है।
(ii) Plant cell और animal cell में plastids को लेकर अंतर?
उत्तर: Plant cells में plastids होते हैं, animal cells में नहीं।

(i) Enzymes के secretion से जुड़ा organelle?
उत्तर: Golgi apparatus
(ii) Solar energy को trap करने वाला organelle?
उत्तर: Chloroplasts
(iii) Protein synthesis होता है?
उत्तर: Ribosomes
(iv) Intracellular digestion होता है?
उत्तर: Lysosomes
(v) ATP का production कहाँ होता है?
उत्तर: Mitochondria

(i) Cellulose किस cell part में होता है?
उत्तर: Cell wall
(ii) Irregular network of tubular double membranes?
उत्तर: Endoplasmic reticulum
(iii) Water या dissolved substances वाला clear space?
उत्तर: Vacuole

(i) Prokaryotic cells के ribosomes बड़े होते हैं।
गलत, प्रोकैरियोटिक सेल्स में छोटे ribosomes होते हैं।
(ii) Eukaryotic cells में mitochondria होते हैं।
सही
(iii) Amoeba प्रोकैरियोटिक सेल है।
गलत, Amoeba युकैरियोटिक सेल है।
(iv) Bacteria में nuclear membrane नहीं होती पर chloroplast होते हैं।
गलत, bacteria में neither nuclear membrane होती है न chloroplast।

11. EVERY ACTIVITY OF A LIVING ORGANISM IS THE OUTCOME OF CELLULAR ACTIVITY

All the activities that living organisms perform—such as growth, repair, movement, nutrition, respiration, protection from diseases, sensation, reproduction, and more—are the result of activities happening inside their cells. Here’s how various essential life activities are carried out at the cellular level:

Growth: Increase in body size and substance is due to the increase in the number and size of cells.
Repair and Regeneration: Repair of injuries or regrowth of lost parts (like lizard’s tail) happens because of cell division.
Movement: Movements (walking, running, swimming, etc.) are possible because muscle cells contract and move bones; even blood flow and food movement in the gut are due to cell activity.
Nutrition: Different steps in feeding like tasting, chewing, swallowing, digestion, absorption, and storage (like fat in fat cells and glycogen in liver) are all done by specific cells.
Circulation: Blood and other fluids move in the body due to contractions of muscle cells in the heart and other organs.
Respiration: Blood cells transport respiratory gases (oxygen, carbon dioxide) within the body.
Immunity: White blood cells protect from disease-causing germs by devouring them or producing antibodies and antitoxins.
Sensation & Response: Sensory cells are responsible for seeing, hearing, smelling, tasting, and feeling, as well as giving instructions from the brain to muscles or glands.
Temperature Regulation: Body heat is managed by cell activity—like cooling by sweating from gland cells.
Reproduction: Producing offspring, seeds, or eggs occurs through activities of special cells (egg and sperm cells).
Absorption in Plants: Root cells absorb water/nutrients; stem cells conduct these substances.
Photosynthesis: Leaf cells with chloroplasts perform food production using sunlight.
Attraction: Cell pigments attract insects for pollination, and nectars are also secretions of cells.
Inheritance: Genes in germ cells (egg or sperm) ensure transfer of parental features to next generation.

Summary: Every activity in living organisms is the result of cellular activity, with different cells performing specialized roles.

PROGRESS CHECK with Answers

Match the items:

Column I (Activity)	Column II (Cellular activity)
(i) Repair	(c) Cell division
(ii) Cooling of body	(d) Gland cells give out sweat for evaporation
(iii) Movement	(a) Contractility of cells
(iv) Protection from diseases	(b) Cells devour germs

Which cell organelle is the key to the life of the cell?
Answer: Nucleus
How do you say a cell also has life span and death? Give one example.
Answer: Old and weak cells die and new ones replace them, e.g., skin cells are replaced regularly.
All organisms excrete. Does an individual cell do it? Give one example.
Answer: Yes, cells remove waste—carbon dioxide is removed by cells during respiration.
Every organism needs food. Does a cell also need it?
Answer: Yes, to perform vital activities, a cell needs nutrients for energy and growth.

Extra Information

Stem Cells:

Stem cells are unspecialized cells that can divide indefinitely and develop into different cell types.
Types:
(a) Embryonic stem cells: Can form any tissue type (pluripotent).
(b) Tissue-specific stem cells: Become capable of forming only one type of tissue (like blood cells from bone marrow).
(c) Induced pluripotent stem cells (iPS): Ordinary skin cells can be changed into stem cells using certain chemicals. For example, type 1 diabetes can be corrected by regenerating pancreatic beta cells using iPS technology.

हर living organism जो भी काम करता है—growth, repair, movement, nutrition, respiration, diseases से protection, sensation, reproduction—all ये सब cell के अंदर activities की वजह से possible होते हैं। यहाँ कुछ examples दिए गए हैं:

Growth: Body का size बढ़ना और substances बनना, यह सब cells के number और size बढ़ने की वजह से होता है।
Repair और Regeneration: जब body में चोट लगती है या कोई part (जैसे लिज़र्ड की tail) regenerate होती है, तो यह cell division की वजह से होता है।
Movement: Walk करना, run करना, swim करना, ये सब muscle cells की contraction की वजह से possible है। Blood flow और food gut में move होना भी cell activities की वजह से है।
Nutrition: Taste करना, chew करना, swallow करना, digest करना, absorb करना, और खाना store करना—इन सब steps को अलग-अलग cells करते हैं।
Circulation: Blood और दूसरी fluids body में circulate होती हैं क्योंकि heart और अन्य organs के muscle cells contract करते हैं।
Respiration: Blood cells body में oxygen और carbon dioxide transport करते हैं।
Immunity: White blood cells (WBCs) germs को destroy करते हैं या antibodies/antitoxins बनाते हैं।
Sensation और Response: Sensory cells हमें देखने, सुनने, smelling, tasting, touch वगैरह allow करते हैं। Brain cell से orders muscles या glands तक पहुँचाते हैं।
Temperature Regulation: हमारा body temperature cell activities से control होता है—gland cells sweat देकर body cool करते हैं।
Reproduction: Young ones (eggs, seeds) produce करने का काम special cells (egg और sperm) से होता है।
Plants में Absorption: Root cells पानी और nutrients absorb करते हैं, stem cells इन्हें पूरे plant तक पहुंचाते हैं।
Photosynthesis: Leaf cells जिनमें chloroplasts होते हैं, वे sunlight से food बनाते हैं।
Attraction: Flowers के colors और nectar—cells की वजह से हैं जो insects को attract करते हैं।
Inheritance: Egg और sperm में मौजूद genes parental features को बच्चों तक पहुंचाते हैं।

Summary: Body का हर activity different cells की activity की वजह से होता है, हर cell की अलग-अलग responsibility होती है।

PROGRESS CHECK के Answers

(i) Repair → (c) Cell division
(ii) Cooling of body → (d) Gland cells give out sweat for evaporation
(iii) Movement → (a) Contractility of cells
(iv) Protection from diseases → (b) Cells devour germs

सबसे जरूरी सेल organelle कौन सा है?
उत्तर: Nucleus
Cell की life span और death कैसे होती है? एक example दें।
उत्तर: पुरानी और कमजोर cells मर जाती हैं और नई cells उन्हें replace करती हैं, जैसे skin cells।
क्या cell excrete करता है? Example दें।
उत्तर: हाँ, जैसे respiration के समय cell carbon dioxide बाहर निकालता है।
क्या cell को भी food चाहिए? संक्षेप में explain करें।
उत्तर: हाँ, cell को energy और growth के लिए food/nutrients चाहिए होते हैं।

Extra Information (Stem Cells)

Stem cells ऐसे cells होते हैं जो अभी किसी particular tissue के लिए fix नहीं हुए हैं—इनमें किसी भी tissue type में बदलने की ability होती है।

Embryonic stem cells: ये किसी भी तरह का tissue बना सकते हैं (pluripotent)।
Tissue-specific stem cells: कुछ stage के बाद वे सिर्फ एक ही type के tissue बना सकते हैं जैसे bone marrow से सिर्फ blood cells बनते हैं।
iPS (induced pluripotent) stem cells: Normal skin cells को special chemical से pluripotent stem cell में बदल सकते हैं। Type 1 diabetes में ये technique pancreas के beta cells regenerate करने के लिए use होती है।

Points to Remember

All plants and animals are made up of cells.
Every organism starts as a single cell.
Cell theory: (1) The cell is the unit of structure, (2) the unit of function, and (3) all cells develop from pre-existing cells.
Plant cells have a rigid cell wall of cellulose and large vacuoles.
Cell membrane is selectively permeable, cell wall is freely permeable.
Ribosomes make proteins, mitochondria produce energy (ATP), Golgi bodies help in secretion, lysosomes destroy foreign materials.
Plastids are various types in plants.
Nucleus has genes and controls cell activities.
Prokaryotic cells have no real nucleus or organelles except ribosomes; they were the first forms of life on earth.

सारे plants और animals cells से बने हैं।
हर organism एक single cell से शुरू होता है।
Cell theory: (1) Cell structure unit है, (2) function unit है, (3) सारी cells pre-existing cells से बनती हैं।
Plant cells में rigid cell wall और बड़ी vacuoles होती हैं।
Cell membrane selectively permeable है, cell wall freely permeable है।
Ribosome protein बनाता है, mitochondria energy (ATP) produce करता है, golgi bodies secretion में help करता है, lysosomes foreign materials destroy करते हैं।
Plant cells में अलग-अलग plastids होते हैं।
Nucleus में genes होते हैं और वही cell को control करता है।
Prokaryotic cells में असली nucleus या organelles नहीं होते, बस ribosome होते हैं—ये earth पर life का पहला form थे।

Review Questions and Answers

A. MULTIPLE CHOICE TYPE

1. Which one of the following cell organelles is correctly matched with its function?
(a) Ribosomes Synthesis of proteins
(b) Mitochondria – Secretion of enzymes
(c) Plasma membrane Freely permeable
(d) Centrosome – Carries genes
Answer: (a) Ribosomes Synthesis of proteins
Reason: Ribosomes are the sites where proteins are made inside the cell.

2. All life starts as
(a) an egg
(b) a single cell
(c) a gene
(d) a chromosome
Answer: (b) a single cell
Reason: Every living being begins life as a single cell, like a fertilized egg.

3. Which one of the following is found both in the cells of a mango plant and a monkey?
(a) chloroplasts
(b) centrioles
(c) cell wall
(d) cell membrane
Answer: (d) cell membrane
Reason: Both plant and animal cells have cell membranes, but not cell walls or chloroplasts.

4. A plant cell can be identified from an animal cell by the:
(a) absence of centrosome.
(b) presence of cell membrane.
(c) presence of vacuoles
(d) none of the above
Answer: (c) presence of vacuoles
Reason: Plant cells have a prominent vacuole, which is not found in animal cells in the same way.

5. Plant cell has a cell wall made of:
(a) Protein
(b) Fructose
(c) Cellulose
(d) Fatty acids
Answer: (c) Cellulose
Reason: Plant cell walls are primarily made of cellulose.

6. The cell organelle that helps in respiration of the cell is:
(a) Mitochondria
(b) Lysosome
(c) Ribosome
(d) Centrosome
Answer: (a) Mitochondria
Reason: Mitochondria are the powerhouses of the cell and release energy during respiration.

B. VERY SHORT ANSWER TYPE

1. Name the part of the cell concerned with the following?
(a) Liberation of energy
Answer: Mitochondria
(b) Synthesis of proteins
Answer: Ribosome
(c) Transmission of hereditary characters from parents to offspring
Answer: Chromosomes
(d) Initiation of cell division
Answer: Centrosome
(e) Hydrolytic in function
Answer: Lysosome
(f) Entry of only certain substances into and out of the cell.
Answer: Plasma membrane (cell membrane)

C. SHORT ANSWER TYPE

1. It is said that the protoplasm cannot be analysed chemically. Why?
Because as soon as protoplasm is removed from the cell, it loses its living nature and properties, so its exact chemical composition cannot be determined outside the cell.

2. What is the difference between an organ and an organelle?
An organ is a part of an organism made of many tissues working together for a function, like the heart or kidney. An organelle is a small structure inside the cell, like the nucleus or mitochondria, which performs a specific function within that cell.

3. Do you think the cells of an elephant would be larger than the cells of a rat? Explain briefly.
No, the size of individual cells in an elephant and a rat is almost the same. The difference in body size is because elephants have many more cells, not because their cells are bigger.

4. Differentiate between the following pairs of terms:
(a) Protoplasm and cytoplasm:
Protoplasm is the living content of a cell, including the nucleus and cytoplasm. Cytoplasm is the jelly-like part outside the nucleus but inside the cell membrane.

(b) Nucleolus and nucleus:
The nucleus is a large, dense organelle containing the cell’s genetic material; the nucleolus is a small body inside the nucleus where ribosomes are made.

(c) Centrosome and chromosome:
The centrosome helps in cell division by forming spindle fibres, while chromosomes carry genetic information and are visible during cell division.

(d) Cell wall and cell membrane:
The cell wall is a rigid outer covering found only in plant cells; the cell membrane is thin, flexible, present in both plant and animal cells, and controls substance entry and exit.

(e) Plant cell and animal cell:
Plant cells have a cell wall, plastids, and large vacuoles. Animal cells lack a cell wall and plastids and have small, temporary vacuoles.

(f) Prokaryotes and eukaryotes:
Prokaryotes have no well-defined nucleus or membrane-bound organelles (example: bacteria). Eukaryotes have a nucleus with a nuclear membrane and many organelles (example: plants, animals).

5. Mention three features found only in plant cells and one found only in animal cells.
Plant cells: cell wall, plastids (like chloroplasts), large central vacuole.
Animal cell: centrosome.

6. Why are the cells generally of a small size?
Cells stay small to allow nutrients and waste to move quickly in and out. A high surface area to volume ratio helps cells function efficiently.

D. LONG ANSWER TYPE

1. What is the cell theory? Who propounded it and when?
Cell theory explains that all living things are made of cells, cells are the basic unit of structure and function, and all cells come from pre-existing cells. Matthias Schleiden and Theodor Schwann proposed it in 1839, and Rudolf Virchow added the third point in 1858.

2. Mention any three differences between a living cell and a brick in a wall.
A living cell is alive, can grow, divide, and respond to stimuli, but a brick is non-living, can’t grow, reproduce, or sense things. Cells are made of protoplasm, have a cell membrane, and can metabolize, while bricks are made of clay, have a hard surface, and don’t perform life activities.

3. Name the plastid and pigment likely to be found in the cells of:
(a) petals of sunflower – Chromoplast, xanthophyll
(b) ripe tomato – Chromoplast, carotene
(c) skin of green mango – Chloroplast, chlorophyll
(d) cells of potato – Leucoplast, no pigment (stores starch)

4. How many chromosome pairs are found in human cells?
23 pairs (total 46 chromosomes).

5. State the major functions of the following:
(a) Plasma membrane – Controls entry and exit of substances in the cell.
(b) Ribosome – Synthesizes proteins.
(c) Lysosome – Carries out intracellular digestion and breaks down old organelles.
(d) Mitochondria – Releases energy by cellular respiration (“powerhouse” of the cell).

6. Match the items in column ‘A’ with those in column ‘B’.
(a) Vacuoles – (iii) Covered by tonoplast
(b) Nucleolus – (v) Forms RNA
(c) Lysosomes – (i) Intracellular digestion
(d) Anthocyanin – (iv) Dissolved in the cytoplasm
(e) Cristae – (ii) Respiratory enzymes

7. Fill in the blanks:
(a) Lysosome consists of membranous sacs and secretes 40 types of digestive enzymes.
(b) Centrosome is surrounded by microtubules, located near the nucleus.
(c) Very thin flexible, living membrane which is differentially permeable, is called cell membrane (plasma membrane).
(d) More than 1000 chromosomes are found in the nucleus of certain insects.
(e) Genes are hereditary units.
(f) Leucoplast is a plastid which stores starch.

8. List any six features found both in plant and animal cells.
Both have: cell membrane, nucleus, cytoplasm, mitochondria, ribosomes, Golgi apparatus.

9. Given below are the sketches of two types of cells A and B
(a) Which one of these is a plant cell? Give reason in support of your answer.
The cell that shows cell wall, chloroplasts, and a large vacuole is the plant cell.

(b) List the cell structures which are common to both the types.
Cell membrane, nucleus, cytoplasm, mitochondria, Golgi bodies, endoplasmic reticulum, ribosomes.

(c) Name the structures found only in plant cells and those found only in animal cells.
Only in plant cells: cell wall, plastids (chloroplasts), large vacuole.
Only in animal cells: centrosome.

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Table of Contents

1. Introduction

What this Chapter Covers

Key Takeaways

इस Chapter में क्या-क्या पढ़ना है?

मुख्य बातें

2. THE INVENTION OF THE MICROSCOPE AND THE DISCOVERY OF CELL

3. CELL THEORY

4. CELLS – HOW NUMEROUS?

5. CELLS – HOW SMALL?

6. CELL SHAPES – TO SUIT FUNCTIONAL REQUIREMENT

7. STRUCTURE OF A CELL

7.1 CELL MEMBRANE and CELL WALL

7.2 CYTOPLASM

7.3 NUCLEUS

7.1 सेल मेम्ब्रेन और सेल वॉल

7.2 साइटोप्लाज्म (Cytoplasm)

7.3 न्यूक्लियस

Chromosome Numbers of Some Common Animals and Plants

DNA – Fingerprinting

8. THE PLANT AND ANIMAL CELLS

9. Protoplasm

10. PROKARYOTIC AND EUKARYOTIC CELLS

Table 2.3: Differences Between Prokaryotic and Eukaryotic Cells

PROGRESS CHECK with Answers

टेबल 2.3 – प्रोकैरियोटिक और युकैरियोटिक सेल्स के बीच अंतर

प्रोग्रेस चेक के उत्तर

11. EVERY ACTIVITY OF A LIVING ORGANISM IS THE OUTCOME OF CELLULAR ACTIVITY

PROGRESS CHECK with Answers

Extra Information

PROGRESS CHECK के Answers

Extra Information (Stem Cells)

Points to Remember

Review Questions and Answers