7 Most SAQ’s of The Unit of Life Chapter in Inter 1st Year Botany (TS/AP)

4 Marks

SAQ-1 : Describe the cell organelle which contains chlorophyll pigments.

Introduction

Chloroplasts are essential cell organelles responsible for photosynthesis, the process by which plants and some other organisms convert sunlight into energy-rich molecules like carbohydrates. These organelles are specific to plant cells and some algae. Here are some key points about chloroplasts:

1. Structure: Chloroplasts are double-membrane bound structures, giving them a unique appearance under a microscope.
2. Stroma: The space enclosed by the inner membrane of the chloroplast is called the stroma. It contains various enzymes required for carbohydrate and protein synthesis.
3. Thylakoids: Inside the stroma, there are numerous flattened membranous sacs called thylakoids, where chlorophyll pigments are located.
4. Grana: Thylakoids are arranged in stacks known as grana (singular: granum) – much like stacks of coins. Grana are connected by membranous tubules called stroma lamellae.
5. Lumen: The space enclosed by the thylakoid membrane is called the lumen.
6. DNA and Ribosomes: Chloroplasts contain their own small, double-stranded circular DNA molecules and ribosomes, which are essential for synthesizing some of their proteins.
7. Function: The main function of chloroplasts is to perform photosynthesis, where sunlight is absorbed by the chlorophyll pigments within thylakoids. The absorbed energy is used to convert carbon dioxide and water into carbohydrates (like glucose) and oxygen.

Summary

Chloroplasts are the cell organelles containing chlorophyll pigments, crucial for photosynthesis in plants and certain algae. They consist of a double membrane, thylakoids, grana, stroma, stroma lamellae, DNA, and ribosomes. Chloroplasts capture light energy during photosynthesis, enabling the synthesis of carbohydrates and oxygen production, essential for plant growth and survival.

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SAQ-2 : Describe the structure and function of power houses of cell.

Introduction

Mitochondria are essential organelles in eukaryotic cells responsible for producing energy in the form of ATP through aerobic respiration. Here’s a breakdown of their structure and functions:

Structure

1. Mitochondria are often referred to as the “powerhouses of the cell” due to their role in energy production.
2. They are double-membrane-bound structures, with both inner and outer membranes.
3. The typical shape of a mitochondrion is sausage-shaped or cylindrical.
4. The inner membrane creates folds, forming structures called cristae. These cristae increase the surface area available for energy production.
5. The space enclosed by the inner membrane is known as the matrix. It contains circular DNA, 70S ribosomes, and RNA molecules, allowing mitochondria to partially self-replicate and produce some of their proteins.
6. The outer membrane forms the continuous boundary of the mitochondrion.

Functions

1. Mitochondria are the primary sites of aerobic respiration in eukaryotic cells. They use oxygen to break down carbohydrates and fatty acids to produce ATP, which is the cell’s main energy currency.
2. The process of aerobic respiration takes place in the mitochondria’s inner membrane and matrix. Through a series of chemical reactions, energy-rich molecules like ATP are generated.
3. Mitochondria play a critical role in providing energy to perform various cellular functions, including muscle contraction, active transport, and cellular signaling.

Summary

Mitochondria, the powerhouses of the cell, are double-membrane-bound structures with an inner membrane that forms cristae to increase surface area. The matrix contains DNA, ribosomes, and RNA. Mitochondria are responsible for aerobic respiration, producing ATP, and providing energy for various cellular processes, making them essential organelles for the functioning of eukaryotic cells.

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SAQ-3 : Describe the structure of nucleus.

Introduction

The nucleus is a vital organelle in eukaryotic cells, often referred to as the cell’s control center. It houses the cell’s genetic material and is responsible for regulating gene expression and cell division. Here is a detailed description of the nucleus’s structure:

Structure of the Nucleus

1. Nuclear Envelope:
   • The nucleus is enclosed by a double membrane called the nuclear envelope.
   • This envelope consists of an outer membrane and an inner membrane, separated by a narrow space.
   • The outer membrane is continuous with the endoplasmic reticulum.
2. Nuclear Pores:
   • The nuclear envelope is perforated by structures known as nuclear pores.
   • These pores regulate the transport of molecules between the nucleus and the cytoplasm.
3. Nucleoplasm:
   • Inside the nuclear envelope is a gel-like substance called nucleoplasm or karyoplasm.
   • It is similar in composition to the cytoplasm but contains a variety of solutes specific to the nucleus.
4. Chromatin:
   • The nucleoplasm contains chromatin, a complex of DNA and proteins.
   • Chromatin appears as a diffuse network in non-dividing cells and condenses to form chromosomes during cell division.
5. Nucleolus:
   • Often present within the nucleus is a dense structure called the nucleolus.
   • It is the site of ribosomal RNA (rRNA) synthesis and ribosome assembly.
6. Genetic Material:
   • The nucleus contains the cell’s genetic material in the form of DNA.
   • This genetic material is responsible for controlling the activities of the cell and hereditary transmission.

Summary

The nucleus is a crucial component of eukaryotic cells, featuring a complex structure that includes the nuclear envelope, nuclear pores, nucleoplasm, chromatin, and often a nucleolus. Its primary role is to house the cell’s genetic material and oversee vital processes such as gene expression and cell division. Understanding the structure of the nucleus is key to comprehending its functions and the overall workings of eukaryotic cells.

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SAQ-4 : Briefly describe the cell theory.

Introduction

The cell theory is a fundamental concept in biology that explains the properties and functions of cells. It is one of the basic principles of biology and provides a framework for understanding the structure and function of all living organisms.

Key Points of the Cell Theory

1. Basic Unit of Life:
   • The cell is the smallest unit of life.
   • All living organisms are composed of one or more cells.
2. Cell Origin:
   • All cells arise from the division of pre-existing cells.
   • This emphasizes the continuity of life from one generation to the next.
3. Functional Unit:
   • The cell is the fundamental unit of structure, physiology, and organization in living organisms.
   • All physiological processes of life occur within cells.
4. Genetic Information:
   • Cells contain the organism’s hereditary information (DNA) and pass it from one generation to the next.
   • This aspect underlines the role of cells in genetic continuity.
5. Energy Flow:
   • Cells are the site of energy flow and metabolism within living organisms.
   • This highlights the role of cells in maintaining life processes through biochemical reactions.
6. All Living Organisms:
   • The theory applies to all living organisms, whether they are unicellular or multicellular.
   • This universality underscores the cell’s central role in biology.

Summary

The cell theory is a crucial concept in biology that establishes the cell as the basic unit of life, the origin of all cells from pre-existing cells, and the cell as the fundamental unit of structure, function, and organization in all living organisms. It emphasizes the importance of cells in genetic continuity, energy flow, metabolism, and applies universally to all living organisms. Understanding the cell theory is essential for studying biology and all related life sciences.

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SAQ-5 : Differentiate between rough endoplasmic reticulum (RER) and smooth endoplasmic reticulum (SER).

Introduction

Cells contain a complex network of membrane-bound organelles, and two of the important structures in this network are the Rough Endoplasmic Reticulum (RER) and the Smooth Endoplasmic Reticulum (SER). While they are both parts of the endoplasmic reticulum, they have distinct functions and characteristics. Let’s differentiate between RER and SER:

1. Rough Endoplasmic Reticulum (RER):
   • RER is so named because it is studded with ribosomes on its outer surface, giving it a rough appearance under the microscope.
   • Function: RER is actively involved in protein synthesis and plays a crucial role in the production, folding, and modification of proteins.
   • Location: It is often found near the nucleus and is abundant in cells that produce a large number of proteins, such as those involved in secretion or for export from the cell.
2. Smooth Endoplasmic Reticulum (SER):
   • SER lacks ribosomes on its surface, giving it a smooth appearance under the microscope.
   • Function: SER is primarily involved in lipid metabolism and synthesis. It plays a key role in the production of lipids, including phospholipids and cholesterol. Additionally, SER is involved in the detoxification of drugs and harmful substances in the liver cells.
   • Location: SER is found in various cell types throughout the body, including liver cells and muscle cells.

Summary

Rough Endoplasmic Reticulum (RER) is involved in protein synthesis and has ribosomes on its surface, while Smooth Endoplasmic Reticulum (SER) is involved in lipid metabolism and lacks ribosomes on its surface. The distinction between these two types of endoplasmic reticulum allows cells to carry out specialized functions related to protein synthesis and lipid metabolism.

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SAQ-6 : What are nucleosomes? What are they made of?

Introduction

Nucleosomes are the basic structural units of eukaryotic chromosomes. They play a crucial role in organizing and compacting the DNA within the nucleus of the cell. Nucleosomes consist of DNA wrapped around a core of histone proteins.

Structure of Nucleosomes

1. Histone Octamer: The core of the nucleosome is made up of eight histone proteins arranged in an octamer. The histone octamer consists of two copies each of four types of histone proteins: H2A, H2B, H3, and H4.
2. DNA Double Helix: The DNA double helix, which contains genetic information, is coiled around the histone octamer. A typical nucleosome contains about 200 base pairs (bp) of DNA double helix, which is equivalent to about two turns around the histone core.
3. H1 Histone Protein: There is an additional histone protein called H1 (also known as linker histone) that binds to the linker DNA, which is the DNA segment between adjacent nucleosomes. H1 helps in stabilizing the nucleosome structure and further compacts the chromatin fiber.

Function of Nucleosomes

Nucleosomes play a vital role in regulating gene expression and packaging the DNA within the limited space of the cell nucleus. They help in condensing the long DNA molecules into a compact and organized structure, which is essential for fitting the entire genome within the cell nucleus. Additionally, nucleosomes control the accessibility of the DNA to various cellular processes, such as transcription, DNA replication, and DNA repair.

Summary

Nucleosomes are the fundamental building blocks of eukaryotic chromosomes. They consist of an octamer of histone proteins around which approximately 200 base pairs of DNA are wrapped. Nucleosomes help in organizing and regulating the expression of genetic information in eukaryotic cells.

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SAQ-7 : What are the characteristics of prokaryotic cell?

Introduction

Prokaryotic cells are the simplest and most primitive type of cells. They are characterized by several key features:

Characteristics of Prokaryotic Cell

1. Cell Wall and Cell Membrane:
   • Prokaryotic cells have a cell wall that provides structural support and protection.
   • In addition to the cell wall, they also have a cell membrane that encloses the cytoplasm and regulates the movement of substances in and out of the cell.
2. Absence of Nucleus: Unlike eukaryotic cells, prokaryotic cells lack a well-defined nucleus. The genetic material, typically a single circular DNA molecule, is present in the cytoplasm and is not enclosed within a nuclear membrane.
3. Size and Shape: Prokaryotic cells are generally smaller and simpler in structure compared to eukaryotic cells. They vary greatly in shape and size, and their small size allows them to multiply rapidly.
4. Cytoplasm: The cytoplasm is the fluid matrix inside the cell where various cellular processes occur. It contains the genetic material, ribosomes, and other cellular components.
5. Genetic Material: The genetic material in prokaryotic cells is naked, meaning it is not associated with histone proteins or enclosed in a nucleus. It usually consists of a single circular chromosome.
6. Plasmids: Prokaryotic cells may contain smaller circular DNA molecules called plasmids. Plasmids often carry genes that provide advantages to the cell, such as antibiotic resistance.
7. Lack of Membrane-Bound Organelles: Prokaryotic cells lack membrane-bound organelles such as mitochondria, endoplasmic reticulum, and Golgi apparatus. The only organelles present are ribosomes, which are involved in protein synthesis.
8. Mesosomes: Prokaryotic cells may have invaginations or infoldings of the plasma membrane called mesosomes. Mesosomes play a role in various cellular processes such as respiration and DNA replication.
9. Organisms with Prokaryotic Cells: Prokaryotic cells are found in bacteria, blue-green algae (cyanobacteria), mycoplasma, and PPLO (PleuroPneumonia-Like Organisms).

Summary

Prokaryotic cells are characterized by the absence of a well-defined nucleus, presence of a cell wall, lack of membrane-bound organelles (except ribosomes), and smaller size. They contain a single circular DNA molecule as the genetic material and may have additional plasmids. Prokaryotic cells are found in bacteria, cyanobacteria, mycoplasma, and PPLO.