Living Organisms: Unicellular and Multicellular Organisms PDF

Summary

This document provides a basic overview of unicellular and multicellular organisms, including their characteristics, functions, examples, and differences. It also details the concept of cell theory.

Full Transcript

**Living Organisms: Unicellular and Multicellular Organisms 🌿**

**Unicellular Organisms**

- Known as single-celled organisms (most primitive form of organisms)

- Main groups of unicellular organisms are:

- Bacteria

- Archaea

- Protozoa

- Algae

- Fungi

- Fall into two general categories: prokaryotic and eukaryotic
organisms (based on cellular organization)

- Oldest form of life, possibly existing 3.8 billion years ago

- Mostly microscopic (cannot be seen by naked eyes) and categorized as
microorganisms

- Examples:

- Bacteria like Escherichia coli, Mycobacteria, Bacillus sp.

- Protozoans like Amoeba, Paramecium

- Algae like Chlorella sp, Chlamydomonas, Diatoms, Euglenophyta,
Dinoflagellates

- Fungi like yeast

**Multicellular Organisms**

- Consist of many cells specialized to do different functions for
maintaining the complexity of the organism

- Most bacteria are unicellular, but some bacterial species are
multicellular like Myxobacteria

- Some species of cyanobacteria are also multicellular like Spirogyra

- Most eukaryotic organisms are multicellular

- Multicellular organisms have well-developed body structure and also
have specific organs for specific functions

- Most well-developed plants and animals are multicellular

- All animals are eukaryotic in nature and most of them are
multicellular

- Examples of unicellular plants are Chlamydomonas (green algae),
Chlorella (single-celled green algae)

- Acetabularia is the largest unicellular green algae, reaching 0.5 to
10 cm in length

**Differences between Unicellular and Multicellular Organisms**

**Unicellular Organisms** **Multicellular Organisms**
---------------------------- ----------------------------------------------------------------------------------------------- ------------------------------------------------------------------------------------------------------
**Body Structure** Made up of single cell Made up of numerous cells
**Division of Labour** May be at cellular level At the organelle level, tissue, organ, and organ system level
**Operational Efficiency** Low level of operational efficiency High degree of operational efficiency
**Cell Specialization** A single cell carries out all life processes Different cells are specialized to perform different functions
**Cell Exposure** The cell body is exposed to the environment on all sides Only outer cells are specialized to face the environment, inner cells are devoted to other functions
**Injury or Death** Injury or death of some cells does not affect the whole organism An injury to the cells can cause death of the organism
**Cell Size** Cell body cannot attain a large size due to the limit imposed by surface area to volume ratio A multicellular body can attain a large size by increasing the number of small cells
**Lifespan** Lifespan is long due to limited load of work for each cell type Lifespan is short due to heavy load of work
**Regeneration** Capacity of regeneration decreases with increasing specialization Power of division is not lost

**Common Features of Unicellular and Multicellular Organisms**

- All organisms must accomplish the same functions:

- Uptake and processing of nutrients

- Excretion of wastes

- Response to environmental stimuli

- Reproduction

**Cell: Definitions; Basic Features; Hierarchy 🧬**

**What is a Cell?**

*A cell is a basic structural, functional, and biological unit of all
living organisms (unicellular and multicellular).*

- Term originated from Latin Word Cellula or Cellus meaning small room
or little space

- Discovered by Robert Hook in 1665 while studying cork under
microscope

- Self-replicating structures that are capable of responding to
changes in the environment

- Often called building block of life

- Study of cell is called cell biology

**Cell Theory**

- Formulated by Matthias Schleiden and Theodor Schwann in 1838-1839

- Rudolf Virchow also contributed to the theory

- Basic principles of the cell theory:

1. All living organisms are composed of one or more cells.

2. The cell is the most basic unit of life.

**Essential Features of Cell Theory**

- Cells are fundamental units of structure and function in all living
organisms.

- Cells are physiological units of living organisms.

- Cell is the smallest unit of life. All activities of living
organisms are the outcome of the activities of its constituent
cells.

**Significance of Cell Theory**

- Concept of cell theory emphasizes the structural and functional
relationship among the diverse living forms from bacteria to man.

- All cells irrespective of their function and position have a nucleus
embedded in the cytoplasm and bounded by cell membrane (unity in
their structural plan).

- Same metabolic processes occur in all the cells primitive or
specialized (unity of function).

**Exceptions to the Cell Theory**

- Viruses are the exception to cell theory because they are made up of
proteins and one of the nucleic acid (DNA or RNA), lack protoplasm.

- Bacteria lack well-organised nucleus. Nuclear membrane, nucleolus,
and nucleoplasm are also absent. Nucleic acid (DNA) alone forms the
chromosome and lies in direct contact with cytoplasm. Basic proteins
associated with nucleic acid are absent in bacteria.

- Coenocytic hyphae of Rhizopus and cells of Vaucheria are
multinucleate.

**Cellular Hierarchy**

- Organism (Human)

- Organ-system (Respiratory system)

- Organ (Lung)

- Tissue (Epithelial tissue, interstitial connective tissue, and
lymphoid tissue)

- Cells

- Cell (Monocyte)\#\# Cell Principle vs Cell Theory 🧬 The cell
principle is considered better than the cell theory because:

- It is applicable to all cells present in living things, including
plants, animals, and microorganisms.

- It incorporates all modern findings related to cells.

**Diversity in Cell Size and Shape 📏**

Cells exhibit diversity in size, shape, and number. Most cells are
microscopic and can only be seen under a high-powered microscope. The
size of cells is usually measured in micrometers.

- The majority of cells are 5-15 micrometers in size, with red blood
cells being 5-8 micrometers.

- Nerve cells are the longest, measuring up to 1-2 meters in humans.

- The egg of an ostrich is about 175 mm x 135 mm.

- In the human body, cell size ranges from 3-4 microns (leukocytes) to
over 90-100 cm (nerve cells).

The nucleo-cytoplasmic ratio and surface area are two important factors
that restrict cell size.

**Factors Influencing Cell Size and Shape 🔄**

The shape of cells is related to their functions. Some cells, such as
blood cells and amoeba, can change their shape, while others have a
constant shape.

- Cells can be spherical, oval, rounded, elongated, cuboidal,
cylindrical, tubular, polygonal, plate-like, discoidal, or
irregular.

- The cell size and shape are influenced by:

- Surface area to volume ratio

- Nucleocytoplasmic ratio

- Rate of cellular activity

- Cell association

**Surface Area to Volume Ratio 📊**

*\"The interior content of the cell is separated from the external
environment by the cell membrane. This distinction, however, does not
imply isolation. The membrane allows a variety of chemicals (nutrients)
to flow through it. These nutrients are required for the cell\'s
functions to perform. A cell\'s entire surface area is just enough to
hold its internal contents. Any increase in surface area might cause a
massive rise in cell volume, which throws the balance off.\"*

**Nucleo-Cytoplasmic Ratio 📊**

*\"The coordinated activity of the cell\'s many components allows it to
operate. The coordination between the nucleus and the cytoplasm is the
most crucial. The nucleus generates chemicals that enter the cytoplasm
and regulate its activities. A cell\'s cytoplasmic region is just large
enough for a nucleus to regulate. The nucleus will be unable to control
its activity if the cytoplasmic region becomes too large.\"*

**Rate of Cellular Activity ⚡️**

Cells that are metabolically more active are generally smaller, with a
higher surface-volume ratio and nucleo-cytoplasmic ratio than larger
cells.

**Cell Association 🤝**

In multicellular forms that exhibit some rigidity, cell-to-cell
attachment is critical. The degree of attachment has a significant
impact on the structure of the cell and its functional properties.

**Types of Cells based on Morphology 🔍**

Cells can be classified into three types:

- **Prokaryotic cells**: Simple cells with no membrane-bound
organelles, such as Golgi complex, mitochondria, chloroplast, or
lysosomes. The hereditary material is a highly coiled circular
chromosome lying naked in the cytoplasm. Example: Bacterial cells.

- **Eukaryotic cells**: Cells that contain a true nucleus. The
hereditary material, DNA, is associated with basic proteins inside
the nucleus, separated from the cytoplasm by a nuclear envelope.
Membrane-bound organelles are present, such as plant and animal
cells.

- **Mesokaryotic cells**: Cells with a nuclear membrane present around
the nucleus, but DNA is not associated with histones. These cells
are more advanced than prokaryotes and less advanced than
eukaryotes. Example: Dinoflagellates, marine algae.

**Structure of Eukaryote and Prokaryote Cells 📈**

**Criteria** **Prokaryotes** **Eukaryotes**
---------------------------- ---------------------------------------------------- -----------------------------------------------------------
Type of Cell Always unicellular Unicellular and multicellular
Cell Size Ranges in size from 0.1 μm to 5.0 μm in diameter Size ranges from 10 μm to 100 μm in diameter
Cell Wall Usually present, chemically complex in nature When present, chemically simple
Nucleus Absent, instead have a nucleoid region in the cell Present
Ribosomes Present; smaller in size and circular in shape Present; comparatively larger in size and linear in shape
DNA arrangement Circular in nature Linear in nature
Membrane-bound organelles Absent Present
Plasmids Present Rarely found in eukaryotes
Lysosome Absent Present
Cell division/Reproduction Binary fission/Asexual Sexual and asexual
Examples Archaea and Bacteria Plant and Animal Cells

**Essential Features of Mesokaryotic Cells 🔍**

Mesokaryotic cells have the following characteristics:

- Medium-sized cells, with a size between prokaryotic and eukaryotic
cells.

- No cell wall, but instead have a pellicle or theca.

- Cell membrane is present.

- Nucleus is well-organized and surrounded by a membrane.

- Membrane-bound cell organelles, such as mitochondria, plastids, and
endoplasmic reticulum, are present in the cytoplasm.

- Ribosomes in the cytoplasm are 80s type.

- Histone protein is completely absent in the cell.

- Chromosome is present and formed with the help of acidic proteins.

- Cell division occurs through the method of amitosis.

- Flagella are present and consist of filaments.

**Plant Cell Wall Structure 🌱**

The plant cell wall is multi-layered and consists of up to three
sections:

1. **Middle Lamella**: The outermost layer of the cell wall, containing
polysaccharides called pectins (calcium pectate). Pectins aid in
cell adhesion by helping the cell walls of adjacent cells to bind to
one another.

2. **Primary Cell Wall**: This layer is formed between the middle
lamella and plasma membrane in growing plant cells. It is primarily
composed of cellulose microfibrils contained within a gel-like
matrix of hemicellulose fibers and pectin polysaccharides.

3. **Secondary Cell Wall**: This layer is formed between the primary
cell wall and plasma membrane in some plant cells. Once the primary
cell wall has stopped dividing and growing, it may thicken to form a
secondary cell wall. This rigid layer strengthens and supports the
cell.

**Plasmodesmata 🌿**

Plasmodesmata are cytoplasmic junctions or bridges between adjacent
cells that permit the passage of molecules directly from one cell to
another.

- Plasmodesmata are mostly found in plant cells.

- In animal cells, similar structures are called gap junctions.

- Plasmodesmata permit the passage of molecules weighing less than 800
Da.

- Transport through plasmodesmata is also found under complex
regulation, which may involve Ca2+ and protein phosphorylation.

**Structure of Plasmodesmata 🔍**

Plasmodesmata have their own plasma membrane lining called plasmalemma,
which is an extension from the membrane of the cell. The structure is
similar to having a phospholipid bilayer.

- **Plasma Membrane Lining**: The plasmalemma is the extension from
the membrane of the cell.

- **Cytoplasmic Sleeve**: A fluid-filled space surrounded by the
plasmalemma is called a cytoplasmic sleeve and is a continuous
extension of the cytosol.

- **Desmotubule**: A structure that is thought to create nanochannels
of varying size within the cytoplasmic sleeve.\#\# 🌿 Plant Cell Wall
Structure and Function

**Desmotubule**

The desmotubule is a dense rod or narrower cylindrical structure that
runs from cell to cell through the center of plasmodesmata in most
cases. It is connected to the smooth endoplasmic reticulum of adjacent
cells.

- Diameter of desmotubule: about 15 nm

- The annulus of the cytosol is present between the outside-inside of
the desmotubule and cylindrical plasma membrane respectively.

- The space between desmotubules and plasma membrane contains 8-10
microchannels, used to transport lipid molecules.

**Plant Cell Wall Functions**

The cell wall plays a crucial role in maintaining the shape and form of
the cell. It is composed of cellulose fibers, structural proteins, and
other polysaccharides.

- **Support**: The cell wall provides mechanical strength and support,
controlling the direction of cell growth.

- **Withstand turgor pressure**: The cell wall helps the plant to
remain rigid and erect, but can also cause a cell to rupture.

- **Regulate growth**: The cell wall sends signals for the cell to
enter the cell cycle in order to divide and grow.

- **Regulate diffusion**: The cell wall is porous, allowing some
substances, including proteins, to pass into the cell while keeping
other substances out.

- **Communication**: Cells communicate with one another via
plasmodesmata (pores or channels between plant cell walls that allow
molecules and communication signals to pass between individual plant
cells).

- **Protection**: The cell wall provides a barrier to protect against
plant viruses and other pathogens, and helps to prevent water loss.

- **Storage**: The cell wall stores carbohydrates for use in plant
growth, especially in seeds.

**🧬 Bacterial Cell Wall Structure**

**Peptidoglycan**

Peptidoglycan is a polymer composed of sugars and amino acids (protein
subunits) that gives the cell wall rigidity and helps to give bacteria
shape.

*\"Peptidoglycan is a glycopeptide, also known as murein, that is unique
to bacterial cell wall composition.\"*

**Bacterial Cell Wall Composition**

**Gram-Positive Bacteria** **Gram-Negative Bacteria**
------------------------------- ----------------------------------------------------------------------------------------- -----------------------------------------------------------------
**Peptidoglycan** 40-80% of dry weight, several layers 2-7 nm thick, lower percentage of peptidoglycan
**Teichoic Acids** Present, play role in adjusting to adverse conditions, pathogenicity, and ion transport Absent
**Lipopolysaccharides (LPS)** Absent Present, acts as endotoxin and receptor, blocks immune response

**Gram-Positive Bacterial Cell Wall**

- **Teichoic Acids**: Located in the outer layer of Gram-positive
bacteria, made up of glycerol phosphate or ribitol phosphate.

- **Lipoteichoic Acids**: Teichoic acids that are covalently linked to
the lipid in the cytoplasmic membrane.

- **Wall Teichoic Acids**: Teichoic acids that are covalently attached
to muramic acid in the wall peptidoglycan.

**Gram-Negative Bacterial Cell Wall**

- **Lipopolysaccharides (LPS)**: A unique outer membrane component,
acts as endotoxin and receptor, blocks immune response.

- **Porins**: Form passive pores that do not bind their substrates,
generally form water-filled pores, through which relatively small
solutes diffuse.

**Lipopolysaccharide (LPS) Structure**

- **O-antigen**: Repetitive glycan polymer attached to the core
oligosaccharide, varies from strain to strain.

- **Core**: Contains an oligosaccharide component that attaches
directly to lipid A, commonly contains sugars such as heptose and
3-Deoxy-D-manno-oct-2-ulosonic acid (KDO).

- **Lipid A**: A phosphorylated glucosamine disaccharide decorated
with multiple fatty acids, responsible for much of the toxicity of
Gram-negative bacteria.

**🔬 Gram Staining Protocol**

The Gram stain is fundamental to the phenotypic characterization of
bacteria, differentiating organisms of the domain Bacteria according to
cell wall structure.

- **Gram-positive cells**: Have a thick peptidoglycan layer and stain
blue to purple.

- **Gram-negative cells**: Have a thin peptidoglycan layer and stain
red to pink.\#\# Bacterial Gram Staining Protocol 🧬 The Gram stain
is a complex and differential staining procedure used to
differentiate bacteria according to their cell wall composition.

**Gram-Positive Bacteria**

- Cell walls contain thick layers of peptidoglycan (80% of cell wall)

- Stain purple

**Gram-Negative Bacteria**

- Cell walls have thin layers of peptidoglycan (10% of wall) and high
lipid content

- Stain pink

**Steps of the Gram Stain**

1. Applying a primary stain (crystal violet) to a heat-fixed smear

2. The addition of a mordant (Gram\'s Iodine)

3. Rapid decolorization with alcohol, acetone, or a mixture of alcohol
and acetone

4. Counterstaining with safranin

**Plasma Membrane Basics 🌐**

The plasma membrane, also known as the cell membrane or cytoplasmic
membrane, is a dynamic fluid structure that forms the external boundary
of cells.

*\"The plasma membrane is a selectively permeable membrane that permits
the entry of selective materials in and out of the cell according to the
requirement.\"*

**Functions of the Plasma Membrane**

- Provides shape and protects the inner contents of the cell

- Regulates the movement of materials in and out of the cell

**Structure of the Plasma Membrane 🌈**

The plasma membrane is composed of a lipid bilayer with embedded
proteins.

**Components of the Plasma Membrane**

**Component** **Description**
--------------------- ------------------------------------------------------------
Phospholipids The main fabric of the plasma membrane
Cholesterol Found between phospholipids and phospholipid bilayers
Integral Proteins Embedded within phospholipid layers
Peripheral Proteins Bound to the outer layer of the membrane
Carbohydrates Attached to proteins/lipids on the outside of the membrane

**Lipids in the Plasma Membrane 💧**

Lipids are used for energy storage and form the matrix of cellular
membranes.

**Types of Lipids**

- Phospholipids

- Glycolipids

- Sterols (Cholesterol and Stigmasterol)

**Function of Lipids**

- Provide a barrier function

- Allow for budding, fission, and fusion of membranes

- Enable segregation of specific chemical reactions

**Plasma Membrane Proteins 🧬**

Membrane proteins are responsible for most of the dynamic processes in
the plasma membrane.

**Types of Membrane Proteins**

- Peripheral Proteins

- Integral Proteins (Transmembrane Proteins)

**Characteristics of Plasma Membrane Proteins**

**Property** **Peripheral Proteins** **Integral Proteins**
------------------------------- --------------------------------------------------------------- -----------------------------------------------------------
Treatment Mild treatment: extreme pH change, exposure to ionic solvents Detergents, organic solvents
Association with lipids Usually soluble, free of lipids Usually associates with lipids when solubilized
Solubility after dissociation Soluble and molecularly dispersed in neutral aqueous buffer Usually insoluble or aggregated in neutral aqueous buffer

**Classification of Membrane Proteins 📈**

Membrane proteins are classified according to their function.

**Types of Membrane Proteins**

- Transport Proteins (Carrier or Channel Proteins)

- Catalytic Proteins

- Structural Proteins

**Examples of Membrane Proteins**

- Glucose transporter

- Chloride-bicarbonate exchange protein

- Aquaporins and Ionophores\#\# Cell Membrane 🌐

**Plasma Membrane Structure**

The plasma membrane is a semi-permeable membrane that surrounds the cell
and regulates the movement of materials in and out. It is composed of a
phospholipid bilayer with embedded proteins.

**Receptors and Ion Channels**

- **Receptors**: proteins that bind to chemicals (e.g., drugs) outside
of the cell, causing a chemical response on the inside of cells.

- **Ion Channels**: membrane proteins that allow the transport of
chemical species into and out of cells.

**Fluid Mosaic Model 🌊**

The fluid mosaic model, proposed by Jonathan Singer and Garth Nicolson
in 1972, describes the structure of biological membranes as a
two-dimensional fluid in which proteins are inserted into lipid
bilayers.

*\"The fluid mosaic model postulates that lipids and integral proteins
are disposed in a kind of mosaic arrangement, and that biological
membranes are quasi-fluid structures in which both lipids and integral
proteins are able to perform translational movements within the
bilayer.\"*

**Plasma Membrane Fluidity 🌈**

Membrane fluidity refers to the fact that lipids have considerable
freedom of lateral or transverse movements.

**Type of Movement** **Description**
---------------------- --------------------------------------------------------------------
Rotation Rotation along its long axis
Lateral Diffusion Exchanging places with neighboring molecules in the same monolayer
Transverse Diffusion Flip-flop from one monolayer to another

**Factors Affecting Membrane Fluidity**

- **Temperature**: Increase in temperature increases membrane
fluidity, while decrease in temperature results in a gel-like
structure.

- **Lipid Composition**: Lipids with short/unsaturated fatty acyl
chains undergo phase transition at lower temperatures than lipids
with long or saturated fatty acids.

**Techniques to Visualize/Study Plasma Membrane 🔍**

- **Hydropathy Plots**: Identify the number of alpha-helical protein
residues in integral proteins.

- **Fluorescence Recovery after Photobleaching (FRAP)**: Visualize the
rapid lateral movement of membrane lipids.

- **Freeze-fracture Technique**: Obtain a 3D view of the cell membrane
with transmission electron microscope.

**Cytoplasm 🌿**

**Cytoplasm Basics**

Cytoplasm is a rich, semifluid material present in cells of organisms
that are closed off by the cell membrane. It contains various
cytoplasmic components, such as cytosol, cytoplasmic organelles, and
inclusion bodies.

**Theories on Physical Nature of Cytoplasm 🤔**

- **Sol-Gel Form**: Cytoplasm behaves similarly to a sol-gel, a
mixture of molecules that sometimes act like a liquid and other
times act like a solid.

- **Glass-like Behavior**: Cytoplasm sometimes acts as though it is
approaching the glass transition as a glass-forming liquid.

- **Non-Brownian Motion of Cytoplasmic Components**: Constituents of
cytoplasm move as a separate entity, channeled by motor proteins.

**Structural Features and Composition of Cytoplasm 🌈**

- **Cytosol**: The liquid-like portion of the cytoplasm, mostly made
up of water, dissolved minerals, and cytoskeleton filaments.

- **Organelles**: Specialized structures within cells that carry out
specific tasks for the cell.

**Parts and Function of Cell Cytoplasm: Cytosol 💧**

*\"The cytosol is the site where many chemical reactions take place. It
serves as the site for osmoregulation and cell signaling, and is
involved in generating action potentials in cells, such as nerve and
muscle cells.\"*

**Parts and Function of Cell Cytoplasm: Cell Organelles 🌿**

- **Nucleus**: The organelle that contains the genetic material and
controls cellular activities such as metabolism, growth, and
reproduction.

- **Chloroplasts**: Plastids containing green pigments essential for
photosynthesis.

- **Mitochondria**: The organelles that synthesize energy for
multifarious metabolic processes.

- **Endoplasmic Reticulum**: An interconnected network of flattened
sacs or tubules involved in lipid synthesis, carbohydrate
metabolism, drug detoxification, and attachment of receptors on cell
membrane proteins.\#\# Cell Organelles 🧬

Cell organelles are structures within a cell that perform specific
functions. They are classified into three categories based on the
presence or absence of a membrane.

**Types of Organelles**

**Type** **Description** **Examples**
----------------------- ----------------------------------- -----------------------------------------------------------
Non-membrane bound Organelles without a membrane Ribosomes, Cytoskeleton
Single membrane-bound Organelles with a single membrane Vacuole, Lysosome, Golgi Apparatus, Endoplasmic Reticulum
Double membrane-bound Organelles with two membranes Nucleus, Mitochondria, Chloroplast

**The Nucleus 🌐**

The nucleus is a double membrane-bound organelle that contains the
cell\'s genetic material, DNA.

**Structure and Characteristics**

- The nucleus is the largest organelle in the cell, accounting for
about 10% of the cell\'s volume.

- The average diameter of the nucleus is approximately 6 μm in
mammalian cells.

- The shape of the nucleus is usually spherical or oblong.

**Parts of the Nucleus**

- **Nuclear Envelope**: A phospholipid bilayer that surrounds the
nucleus, with tiny openings called nuclear pores.

- **Nuclear Pores**: Enable the selective transport of water-soluble
molecules through the nuclear membrane.

- **Nuclear Lamina**: A meshwork of protein filaments that line the
inner nuclear membrane, providing support and structure to the
nucleus.

- **Nucleoplasm**: A gelatinous substance inside the nucleus, composed
mainly of water with dissolved salts, enzymes, and suspended organic
molecules.

- **Nucleolus**: A non-membrane bound dynamic body that is the site of
transcription of ribosomal RNA and assembly of ribosomes.

**Nucleolus Structure**

- **Fibrillar Centres**: Containing rRNA genes in the form of partly
condensed chromatin.

- **Dense Fibrillar Component**: Surrounds the fibrillar center,
containing RNA molecules in the process of transcription.

- **Granular Regions**: Contains mature ribosomal precursor particles
(pre-ribosome assembly).

**Chromatin and Chromosomes**

- **Chromatin**: An organized structure of DNA and protein found in
the nucleus of eukaryotic cells.

- **Chromosome**: A highly condensed and extended DNA molecule.

*\"Chromatin is less condensed and extended DNA, while chromosomes are
highly condensed and extended DNA.\"*

**Functions of the Nucleus**

- Controls and coordinates the functioning of the entire cell.

- Regulates the flow of molecules into and out of the nucleus through
nuclear pores.

- Provides a medium for the transport of enzymes and fragments of
genetic materials (DNA or RNA) throughout the nucleus.

**Cytoplasm 🌊**

Cytoplasm is the region between the cell membrane and the nucleus, where
many metabolic processes take place.

**Functions of Cytoplasm**

- **Support and Structure**: Provides support and structure to the
cell, maintaining its shape and turbidity.

- **Protection**: Protects the cell and its components from damage.

- **Storage**: Contains materials such as storage units and enzymes
essential for many metabolic activities.

- **Transport**: Assists with the transport of organelles and
cytoplasmic inclusions throughout the cell.

**Cytoplasmic Inclusions**

- **Lipid Droplets**: Used by both plant and animal cells to store
lipids like fatty acids.

- **Vacuoles**: Store excess glucose during photosynthesis in plants.

**Cytoplasmic Streaming**

- A process that occurs in plant and animal cells, where the cytoplasm
moves within the cell membrane.

- Enables the transport of organelles and cytoplasmic inclusions
throughout the cell.\#\# Cell Morphology 🧬

**Chromosome Structure 🧬**

- A chromosome is a thread-like structure that carries hereditary
information in the nucleus of living cells.

- The constricted region of linear chromosomes is known as
the **centromere**.

- The centromere serves as the site of association of sister
chromatids and as the attachment site for microtubules of the
mitotic spindle.

*\"The centromere is a specialized region on a chromosome that links
sister chromatids or the point where the microtubules of the spindle
attach.\"*

- The regions on either side of the centromere are referred to as the
chromosome\'s **arms**.

**Telomeres 🔗**

- **Telomeres** are specialized structures that cap the ends of
eukaryotic chromosomes.

- They consist of a long array of short, tandemly repeated sequences.

- Telomeres have a high G content in the strand with its 3\' end.

*\"Telomeres are repetitive DNA sequences that protect the ends of
chromosomes from deterioration or from fusion with neighboring
chromosomes.\"*

**Origin of Replication 🔁**

- The **origin of replication** (also called the replication origin)
is a particular sequence in a chromosome at which replication is
initiated.

- One chromosome contains multiple origins of replication.

**Chromosome Number 📊**

**Species** **Chromosome Number**
------------- -----------------------
Human 46 (diploid)
Fruit Fly 8 (diploid)
Wheat 42 (hexaploid)

- Every cell maintains a characteristic number of chromosomes.

- The number of chromosomes in a species has no specific significance
nor does it indicate any relationship between two species that may
have the same chromosome number.

**Function of Nucleus 🧬**

- The nucleus contains genetic information.

- It governs genetic expression and other vital functions of the cell.

- It facilitates DNA replication for mitosis.

- It produces ribosomes responsible for protein synthesis.

**Ribosomes (Cell Protein Factories) 🏭**

**Structure of Ribosomes 🔍**

- Ribosomes are large ribonucleoproteins consisting of RNAs and
proteins.

- They are approximately globular in structure, with an average
diameter ranging from 2.5 nm (Escherichia coli) to 2.8 nm (mammalian
cells).

- The functional ribosomes consist of two subunits of unequal size,
known as the large and small subunits.

**Types of Ribosomes 🤝**

**Type** **Description**
---------------------- --------------------------------------------------------------------------
Cytosolic Ribosomes 80S type, found in the cytosol of eukaryotic cells
Organellar Ribosomes Smaller than cytosolic ribosomes, found in mitochondria and chloroplasts

**Biogenesis of Ribosomes 🔨**

- Ribosomes are not self-replicating particles.

- The synthesis of various components of ribosomes, such as rRNAs and
proteins, is under genetic control.

- In eukaryotes, the biogenesis of ribosomes is the result of the
coordinated assembly of several molecular products that converge
upon the nucleolus.

**Functions of Ribosomes 🔄**

- Ribosomes take part in protein synthesis.

- They play a protective function during protein synthesis, protecting
the mRNA strand and nascent polypeptide chains from degradation.

**Ribosomal Protein Targeting and Translocation 🚪**

**Types of Protein Translocation 🚪**

**Type** **Description**
------------------------- --------------------------------------------------------------------------------------------
Gated Transport Protein translocation between the cytosol and nucleus through nuclear pores
Transmembrane Transport Direct transport of specific proteins across a membrane from the cytosol into an organelle
Vesicular Transport Movement of proteins from one organelle to another through transport vesicles

**Endoplasmic Reticulum: Basics 📦**

**Structure of Endoplasmic Reticulum 🔍**

- The endoplasmic reticulum (ER) is a large organelle made of
membranous sheets and tubules that begin near the nucleus and extend
across the cell.

- The ER is contiguous with the outer nuclear membrane.

**Types of Endoplasmic Reticulum 🤝**

**Type** **Description**
------------------------------------ ------------------------------------------------------------------------------------------
Rough Endoplasmic Reticulum (RER) Studded with ribosomes on the outer surface, involved in protein synthesis and transport
Smooth Endoplasmic Reticulum (SER) Lacking attached ribosomes, involved in lipid synthesis and detoxification

**Functions of Endoplasmic Reticulum 🔄**

- The ER creates, packages, and secretes many of the products created
by a cell.

- It processes most of the instructions from the nucleus.

- It interacts closely with other organelles, such as the Golgi
apparatus.\#\# Endoplasmic Reticulum Structure 🌐

The endoplasmic reticulum (ER) is a type of organelle found in
eukaryotic cells. It is differentiated into two distinct
regions: **Rough Endoplasmic Reticulum (RER)** and **Smooth Endoplasmic
Reticulum (SER)**.

**Rough Endoplasmic Reticulum (RER)**

*The RER is a type of ER that is studded with ribosomes on its surface,
giving it a \"rough\" appearance.*

The RER is commonly found near the nucleus and is involved in protein
synthesis. It contains membrane-bound ribosomes that translate proteins
destined for the lumen of the ER.

**Smooth Endoplasmic Reticulum (SER)**

*The SER is a type of ER that lacks ribosomes on its surface, giving it
a \"smooth\" appearance.*

The SER is involved in lipid metabolism, calcium storage, and
detoxification. It is often found near the periphery of the cell.

**Functions of Endoplasmic Reticulum 📈**

**Protein Synthesis and Folding**

**Function** **Description**
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Protein Synthesis Occurs in the RER, where ribosomes translate proteins destined for the lumen of the ER.
Protein Folding Occurs in the RER, where proteins are folded into their proper conformation.
Protein Modification Occurs in the RER, where proteins undergo modifications such as N-linked glycosylation, disulfide bond formation, and proteolytic cleavage.

The RER is also involved in the synthesis of proteins that are destined
for secretion, such as hydrolytic enzymes found in lysosomes.

**Lipid Synthesis**

The SER is involved in the synthesis of lipids, including cholesterol
and phospholipids. It is enriched in enzymes involved in sterol and
steroid biosynthetic pathways.

**Calcium Storage**

The SER acts as a calcium store for the cell, releasing calcium ions in
response to signals. This is particularly important in muscle cells,
where calcium ions are necessary for contraction.

**Detoxification**

The SER is also involved in detoxification, particularly in hepatic
cells, where it helps to remove xenobiotics from the cell.

**Interactions with Other Organelles 🤝**

The ER interacts with other organelles, including the Golgi apparatus,
mitochondria, and plasma membrane. These interactions are important for
the regulation of cellular processes, including metabolism, signal
transduction, and apoptosis.