CHEM-3B-Group-3-Cells.pdf

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Exploring
Cells
Group 3
BS CHEM - 3B
 Today, you
will...
Undertstand the fundamental concepts
of cell, including the definition and
importance of cells.

Understand how cells differentiate and
specialize to form tissues and organs.

Analyze how cells communicate through
signaling pathways and the role of
receptors and second messengers.
 Let’s start!

Introduction
Cells are the fundamental units of life, essential
for the survival, growth, and reproduction of all
organisms, from simple bacteria to complex
multicellular forms. They carry out crucial
processes such as metabolism, energy
production, and genetic regulation, and work
together to maintain homeostasis and adapt to
environmental changes. Cells are categorized
into prokaryotic cells, which lack a nucleus, and
eukaryotic cells, which have a defined nucleus
and specialized organelles, reflecting the
diversity and complexity of life.
 A cell is the smallest unit of a living
What is a cell? thing. It is the basic building block of all
living organisms.
 Importance of Cells
Basic unit of life
unicellular organisms: made of single cell that performs all
life functions
multicellular organisms: made of different cells that
specialize to perform various functions.
Genetic Information:
DNA
Metabolism:
Chemical reactions that occur within a cell to maintain life
Reproduction:
Asexual: mitosis, binary fission, budding
Sexual: meiosis
Response to stimuli
Adaptation
Discovering
the Cell
 Discovering the Cell

Robert Hooke
English scientist
“Micrographia”
Observation of cork
Coined the term ‘cell’ in
1665.
 Discovering the Cell

Antonie van
Leeuwenhoek
Dutch microbiologist
“Father of Microbiology”.
First person to observe living
cells in detail.
“animalcules”(little
animals), which now we
recognize as single-celled
organisms like bacteria,
protozoa.
 Cell Theory

Matthias Schleiden Theodor Schwann,

Rudolf Virchow

1. All living organisms are
composed of one or more cells.
2.The cell is the basic unit of
structure and function in living
things.
3.All cells arise from pre-existing
cells.
 Types of
Cells
Prokaryotic cell
vs. Eukaryotic cell
 Prokaryotic Cell Unicellular Organisms
-Single cell performs all life functions
Characteristics:
No nucleus; DNA is in a circular form.
Lack of membrane-bound organelles.
Smaller and simpler structure compared to
eukaryotic cells
Function:
survival, growth, and reproduction
Reproduction: Asexual process
Binary fission
Budding
Adaptation:
Highly adaptable
Size:
Generally microscopic
 Eukaryotic Cell Multicellular Organisms
-Made up of more than one cell, often organized
Characteristics: into tissues, organs, and systems.
Contain nucleus; DNA is organized into
chromosomes
Have various membrane-bound organelles.
Function:
survival, growth, and reproduction
Reproduction:
Asexual : Mitosis
Sexual: Meiosis
Adaptation:
More complex
Size:
from microscopic to large organisms
 Structure of
Prokaryotic Cell
Cell Wall:
A rigid structure outside the cell membrane,
composed primarily of peptidoglycan in bacteria.
Cytoplasm:
A jelly-like fluid that fills the interior of the cell,
containing water, salts, and various organic
molecules.
Nucleoid:
A region in the cytoplasm where the cell’s
circular DNA is located; not surrounded by a
membrane.
Ribosomes:
Small structures made of ribosomal RNA and
proteins found throughout the cytoplasm.
 Structure of
Prokaryotic Cell
Plasmids:
Small, circular, double-stranded DNA
molecules found in addition to the nucleoid
DNA.
Flagellum:
Long, whip-like appendages that can be
single or multiple
Plasma membrane:
also known as the cell membrane, is a thin,
flexible barrier that surrounds the cell.
Capsule:
thick, gelatinous outer layer that surrounds
the cell wall in some bacteria.
 Structure of
Eukaryotic Cell
Lysosomes:
contains enzymes for digestion of cellular
waste and macromolecules.
Ribosomes:
are small, non-membrane-bound structures
found in all cells, composed of RNA and
proteins
Nucleus:
a membrane-bound organelle that contains
the cell's genetic material (DNA).
Smooth Endoplasmic Reticulum:
lacks ribosomes; synthesizes lipids and
detoxifies substances.
 Structure of
Eukaryotic Cell
Rough Endoplasmic Reticulum:
studded with ribosomes; synthesizes
proteins.
Transport Vesicles:
are small, membrane-bound sacs that
shuttle molecules, like proteins and lipids.
Cristernae:
are flattened, membrane-bound sacs
found in the Golgi apparatus and the
endoplasmic reticulum.
 Feature Plant Cell Animal Cell

Absent; only a flexible cell
Cell Wall Present; made of cellulose
membrane

Present; site of Absent; do not perform
Chloroplasts
photosynthesis photosynthesis

Large, central vacuole for
Central Vacuole Small or absent
storage and support

Regular, rectangular shape Irregular, more flexible
Shape
due to the cell wall shape
 Feature Plant Cell Animal Cell

Present; help in cell
Centrioles Usually absent in plant cells
division (mitosis)

Energy Storage Starch Glycogen

Present; involved in
Lysosomes Rare or absent digestion and waste
removal

Surrounded by a cell wall and Only a plasma membrane,
Plasma Membrane
plasma membrane no cell wall
The Plasma
Membrane
Determine its structure and
functions.
Plasma Structural Components of the
Membrane Plasma Membrane

also known as the cell
membrane, is a semipermeable Phospolipid Bilayer:
barrier that surrounds the
cytoplasm of the cell. The plasma membrane is primarily made up
of two layers of phospholipids. The bilayer
forms the basic structure of the membrane,
creating a barrier.
 Structural Components of the
Plasma Membrane
Plasma Protein:
Membrane
Embedded within the phospholipid bilayer
also known as the cell are proteins that can either span the entire
membrane, is a semipermeable membrane (integral proteins) and be
barrier that surrounds the attached to the surface (peripheral proteins)
cytoplasm of the cell.

Proteins perform a variety of roles:
1. Transport proteins
2.Receptor proteins
3.Enzymatic proteins
Plasma Structural Components of the
Membrane Plasma Membrane

also known as the cell
membrane, is a semipermeable
barrier that surrounds the Cholesterol:
cytoplasm of the cell.
Cholesterol molecules are scattered within
the phospholipid bilayer.
Plasma Structural Components of the
Membrane Plasma Membrane

also known as the cell
membrane, is a semipermeable Carbohydrates:
barrier that surrounds the
cytoplasm of the cell. Carbohydrates are attached to proteins
(glycoproteins) or lipids (glycolipids) on the
outer surface of the membrane.
The Nucleus
The nucleus is the control center of a
eukaryotic cell. It contains most of the
cell’s genetic material (DNA) and
regulates activities like growth,
metabolism, and reproduction.
Structural Components of the Nucleus:
Nuclear Envelope:
A double membrane that surrounds the nucleus.
Nuclear Pores:
Small openings in the nuclear enevelope.
Nucleoplasm:
The gel-like substance inside the nucleus.
Chromatin:
DNA combined with proteins (mainly histones).
Nucleolus:
A dense region inside the nucleus.
Ribosomes:
Are not directly located in the nucleus, but they are produced in a
specific part of the nucleus called nucleolus.
 Energy Production
Energy production in cells is a crucial process that involves
converting nutrients into usable energy, which is essential
for maintaining cellular functions and sustaining life.

Functions of Energy Production:
Cellular Work, Metabolism, Growth and Repair.

Examples of Energy Production Processes:
Cellular Respiration, Fermentation, Photosynthesis
 Protein Synthesis Protein synthesis
involves two main
phases:
Protein synthesis is process in which
polypeptide chains are formed from Transcription:
coded combinations of single amino DNA is converted into
acids inside the cell. messenger RNA (mRNA)
by RNA polymerases in
the nucleus.
The synthesis of new polypeptides
requires a coded sequence, enzymes, Translation:
and messenger, ribosomal, and transfer mRNA is used by
ribonucleic acids (RNAs). ribosomes to synthesize
proteins.
Certain parts of the cell are essential for protein synthesis
RIBOSOMES
Responsible for synthesizing proteins by translating the genetic code
transcribed in mRNA into an amino acid sequence. Ribosomes use cellular
accessory proteins, soluble transfer RNAs, and metabolic energy to
accomplish the initiation, elongation, and termination of peptide
synthesis.

ROUGH ENDOPLASMIC RETICULUM
The site for synthesis of proteins that are destined to be exported from
the cell. The ER also has mechanisms for maintaining the quality of the
proteins synthesized, especially those destined for transport.
Certain parts of the cell are essential for protein synthesis

GOLGI APPARATUS
The Golgi apparatus, or Golgi complex, functions as a factory in which
proteins received from the ER are further processed and sorted for
transport to their eventual destinations: lysosomes, the plasma
membrane, or secretion. In addition, as noted earlier, glycolipids and
sphingomyelin are synthesized within the Golgi.
Cell Division
Mitosis and Meiosis: Phases and Significance

Mitosis Meiosis

Mitosis, a process of cell duplication, or Meiosis, is the process in eukaryotic,
reproduction, during which one cell gives sexually reproducing animals that
rise to two genetically identical daughter reduces the number of chromosomes in a
cells. Strictly applied, the term mitosis is cell before reproduction. Many organisms
used to describe the duplication and package these cells into gametes, such as
distribution of chromosomes, the egg and sperm.
structures that carry the genetic
information.
Cell Division (Mitosis)
Prophase
The replicated pairs of chromosomes condense and compact themselves.
The pairs of chromosomes that have been replicated are called sister
chromatids, and they remain joined at a central point called the
centromere. A large structure called the mitotic spindle also forms from
long proteins called microtubules on each side, or pole, of the cell.

Metaphase
The nuclear envelope that encloses the nucleus breaks down, and the
nucleus is no longer separated from the cytoplasm. Protein formations
called kinetochores form around the centromere.
Cell Division (Mitosis)
Anaphase
The sister chromatids are separated simultaneously at their centromeres.
The separated chromosomes are then pulled by the spindle to opposite
poles of the cell. Anaphase ensures that each daughter cell receives an
identical set of chromosomes.
Telophase
Telophase, a nuclear membrane forms around each set of chromosomes
to separate the nuclear DNA from the cytoplasm. The chromosomes
begin to uncoil, which makes them diffuse and less compact. Along with
telophase, the cell undergoes a separate process called cytokinesis that
divides the cytoplasm of the parental cell into two daughter cells.
Cell Division (Meiosis I)
Prophase I
The complex of DNA and protein known as chromatin condenses to form
chromosomes. The pairs of replicated chromosomes are known as sister
chromatids.

Metaphase I
The pairs of homologous chromosome form tetrads. Within the tetrad, any pair of
chromatid arms can overlap and fuse in a process called crossing-over or
recombination.
Cell Division (Meiosis I)
Anaphase I

The spindle fibers contract and pull the homologous pairs, each with two
chromatids, away from each other and toward each pole of the cell.

Telophase I

The chromosomes are enclosed in nuclei. The cell now undergoes a process
called cytokinesis that divides the cytoplasm of the original cell into two
daughter cells.
Cell Division (Meiosis II)
Prophase II Metaphase II

The chromosomes condense, The centromeres of the
and a new set of spindle paired chromatids align
fibers forms. The along the equatorial plate in
chromosomes begin moving both cells.
toward the equator of the cell

Anaphase II Telophase II
The chromosomes separate at The chromosomes are
the centromeres. The spindle enclosed in nuclear
fibers pull the separated membranes. Cytokinesis
chromosomes toward each follows, dividing the
pole of the cell. cytoplasm of the two cells.
 What is a Cell Communication?
The study of cell communication focuses on how a cell gives and receives
messages with its environment and with itself. Indeed, cells do not live in
isolation. Their survival depends on receiving and processing information from
the outside environment, whether that information pertains to the availability of
nutrients, changes in temperature, or variations in light levels.
Two Types of Cell Communication:
Intercellular Intracellular
Communication Communication
the communication the communication
between cells within a cell
Catergories AUTOCRINE SIGNALING

of Chemical a cell targets itself

Signaling PARACRINE SIGNALING
a cell signals a nearby cell
Autocrine Signaling
Paracrine Signaling
Endocrine Signaling
ENDOCRINE SIGNALING
Direct Signaling
a cell targets a distant cell through the bloodstream

DIRECT SIGNALING
a cell targets a neighboring cell through a gap junction
Examples:
GAP JUNCTIONS
a type of cell junction in which adjacent cells are connected through connection
channels. it allow direct cell-cell transfer of ions, small molecules, and electrical
impulses.

NEUROTRANSMITTERS
are chemical messengers that carry, boost, and balance signals between nerve cells
and target cells throughout the body.

HORMONES
a chemical that is made by specialist cells, usually within an endocrine gland, and it
is released into the bloodstream to send a message to another part of the body.
 Specialized Cells

What are specialized cells?
a cell that has a unique structure that allows it to carry out a specific job in the
body.
Examples of Specialized Cells:
neurons
muscle cells
epithelial cells
others: red blood cells, white blood cells, reproductive cells, and many more
 Specialized Cells
Neurons
the basic working unit of the brain. it is a specialized cell designed to transmit
information to other nerve cells, muscle, or gland cells.

Muscle Cells
are found in bundles which make up our muscles. these cells are able to contract
(get shorter) and relax (return to original length).

Epithelial Cells
are a type of cell that covers the inside and outside of the surfaces of your body. it
covers the skin, body cavities, and blood vessels. they perform a variety of
functions that include protection, secretion, absorption, excretion, filtration,
diffusion, and sensory reception.
 Summary Importance of Understanding
Cell Biology:
Cells are the primary building blocks of
life, and it is essential to understand their
structure, metabolism, and division to
comprehend life processes. Aside from
that, it provides explanation of
inheritance patterns, shows evolutionary
processes, and gives insight into how cells
differentiate and organize into tissues
What are cells?
and organs that helps us understand
A cell is the smallest unit of a living development and growth. To conclude,
thing. An organism may be made of one studying cells offers a way to learn about
cell or many cells. growth, reproduction, and all other
functions that living things perform.