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Science

PLANT
CELLS
Mermaid’s wineglass (Acetabularia)

three parts: a delicate base that anchors it
to a rock or piece of coral, a long slender
stalk, and a cap

(A. mediterranea) is smooth and cup
shaped, and another (A. crenulata) is
rounded with a series of fingerlike
projections
INTRODUCTION
In the 1600s, Anton van Leeuwenhoek (1632– 1723) perfected
the art of grinding lenses (pieces of glass with curved surfaces)
and used them in microscopes of his own design to produce
clear, magnified images.

In 1665, Robert Hooke used a microscope to examine a cork
sliver, observed tiny compartments he named cells, and
recognized that while he saw only the cell walls of dead cells,
the contents of living cells were also important.
19th century so that biologists were able to observe tiny
structures within cells, which they called organelles (little
organs).
1830 Robert Brown a Scottish botanist, first identified and
named the cell’s nucleus (an organelle that serves as its control
center).
INTRODUCTION
By the late 1830s, after examining various tissues, biologists
concluded that all organisms are composed of cells, a concept
formally stated by German biologists Matthias Schleiden and
Theodor Schwann in 1838 and 1839, respectively, which
became known as the cell theory.
Another German scientist, Rudolf Virchow, extended the cell
theory in 1855 by stating that all cells come from preexisting
cells. That is, cells divide to give rise to new cells.
In 1880 August Weismann pointed out that since cells come
from preexisting cells, all cells in existence today trace their
origins back to ancient cells.
PLANT BIOLOGIST TODAY USE A VARIETY OF METHODS
TO STUDY CELLS
EUKARYOTIC CELLS AND
PROKARYOTIC CELLS
Cells are composed of cytoplasm surrounded by a
plasma membrane, which serves as the outer
boundary of the cell, though plant cells also have a
cell wall.
All cells contain DNA, the genetic material that
controls cellular activities.
Eukaryotic cells have their genetic material enclosed
within a membrane-bound nucleus, while prokaryotic
cells lack a nucleus, with DNA present in the
cytoplasm.
Prokaryotic cells are generally smaller and simpler,
lacking membrane-bound organelles and nuclei, and
evolved before eukaryotic cells; only archaea and
bacteria are prokaryotes.
Eukaryotic cells are larger, more complex, and
contain membrane-bound organelles; they are found
THE STRUCTURE OF PLANT CELLS
THE STRUCTURE OF PLANT CELLS

The plasma membrane serves as the outer
boundary of the cell, confining its contents to an
internal compartment and regulating the flow of
materials in and out. Acting as a selective barrier, it
allows some substances to pass freely while
controlling or blocking the passage of others,
maintaining a distinct internal environment.
THE STRUCTURE OF PLANT CELLS

The nucleus serves as the cell's control center,
housing DNA, which directs cellular activities.
DNA in the nucleus is continually used to guide cell
functions and is replicated during cell division.
THE STRUCTURE OF PLANT CELLS

The nucleus is enclosed by a double membrane, the
nuclear envelope, with selective pores that regulate
the entry and exit of materials.
Inside the nucleus, DNA combines with proteins to
form chromatin, which condenses into
chromosomes during cell division.
Nucleoli within the nucleus are responsible for
making and assembling ribosome subunits,
essential for protein synthesis.
THE STRUCTURE OF PLANT CELLS

Chloroplasts, found in algal and plant cells, convert
light energy into chemical energy through
photosynthesis.
Chloroplasts are a type of plastid surrounded by a
double membrane, containing enzymes and
chlorophyll necessary for photosynthesis.
During photosynthesis, chloroplasts use light
energy to convert carbon dioxide and water into
carbohydrates like glucose.
THE STRUCTURE OF PLANT CELLS
Chloroplasts are typically disc-shaped in plant
cells and come in various shapes in algae, with
their interior containing thylakoids stacked into
grana, embedded in a jellylike stroma where
photosynthesis occurs.
Chloroplasts contain small amounts of DNA and
ribosomes, suggesting they evolved from free-
living ancestors.
Plant cells also contain leucoplasts, colorless
plastids that store starch, oils, or proteins,
commonly found in seeds, roots, and modified
stems for food storage.
Leucoplasts can transform into chloroplasts when
exposed to light, synthesizing chlorophyll, as seen
when potato tubers are exposed to light.
Chromoplasts, another type of plastid, contain
pigments that provide yellow, orange, and red
THE STRUCTURE OF PLANT CELLS

Mitochondria are the powerhouses of eukaryotic cells,
converting the chemical energy from food molecules into
ATP through cellular respiration.
Cellular respiration occurs in mitochondria, where fuel
molecules are broken down into carbon dioxide and water,
releasing energy stored in ATP.
Mitochondria are bounded by a double membrane, with the
inner membrane forming folds called cristae, which house
enzymes for cellular respiration.
The matrix, the fluid inside the inner mitochondrial
membrane, also contains enzymes involved in respiration.
Mitochondria contain small amounts of DNA and ribosomes,
indicating a possible evolutionary link to free-living
ancestors.
THE STRUCTURE OF PLANT CELLS

Ribosomes are small organelles responsible for protein synthesis,
using DNA instructions to join amino acids in precise sequences.
Ribosomes consist of two subunits made of RNA and protein, and are
found in the nucleus, plastids, mitochondria, and cytoplasm.
In the cytoplasm, ribosomes are either free or attached to the
endoplasmic reticulum (ER), where they are involved in protein
production.
The endoplasmic reticulum (ER) is an extensive network of
membranes and is continuous with both the plasma membrane and
the nuclear envelope.
Rough ER, with attached ribosomes, is a site of protein synthesis,
while smooth ER is involved in lipid synthesis.
The ER also plays a role in synthesizing membranes for various
organelles, including the nuclear envelope and Golgi apparatu
THE STRUCTURE OF PLANT CELLS

The Golgi body, or dictyosome, processes and packages proteins
and polysaccharides, consisting of flattened sacs surrounded by
membranes.
Vesicles formed at the edges of the Golgi body transport materials to
the plasma membrane, other organelles, or outside the cell.
The collective term for all Golgi bodies in a cell is the Golgi apparatus,
which is responsible for exporting and processing cellular materials.
In plant cells, the Golgi apparatus produces and transports
polysaccharides for the cell wall and collects materials for vacuoles.
Proteins synthesized by ribosomes on the rough ER are transported
in vesicles to the Golgi body, where they are modified and packaged
for export.
Vesicles from the Golgi body fuse with the plasma membrane,
releasing their contents outside the cell.
THE STRUCTURE OF PLANT CELLS

A vacuole is a membrane-bound sac containing water, dissolved
salts, ions, pigments, and waste products, commonly found in plant
cells and some protists.
In mature plant cells, the vacuole can occupy up to 90% of the cell's
volume and is surrounded by a membrane called the tonoplast.
Vacuoles help maintain plant cell shape by making the cell turgid,
which provides rigidity, especially in non-woody plants.
Vacuoles also serve as storage for excess materials like calcium ions
and pigments such as anthocyanins, which contribute to plant
coloration.
Waste products and malformed proteins may enter the vacuole for
disassembly or accumulate as crystals visible under a microscope.
THE STRUCTURE OF PLANT CELLS

Plant cells have a rigid cell wall outside the plasma membrane
for support and protection, allowing the passage of water and
dissolved materials.
The combined strength of cell walls enables plants, like trees,
to stand tall without collapsing.
While animal cells lack cell walls, many organisms like
prokaryotes, algae, and fungi have cell walls, differing in
composition from plant cell walls.
Plant cell walls are mostly made of cellulose, a polysaccharide
composed of linked glucose molecules, produced inside the
cell and transported via Golgi apparatus vesicles.
THE STRUCTURE OF PLANT CELLS

Cellulose fibers in the plant cell wall are held together by
other polysaccharides like pectin, which helps cement cells
together.
Growing plant cells secrete a primary cell wall that stretches
as the cell grows, and upon maturation, secondary walls rich
in lignin may form for additional strength.
Plant cells communicate through plasmodesmata, tiny
channels that connect adjacent cells and allow the passage of
molecules and ions between them.
PLANT CELLS AND ANIMAL
CELLS ARE MORE ALIKE
THAN DIFFERENT
Both plant and animal cells are eukaryotic, sharing
many fundamental structures.
Both types of cells have plasma membranes,
nuclei, mitochondria, ribosomes, ER, the Golgi
apparatus, and a cytoskeleton.
Plant cells differ from animal cells by possessing
cell walls, plastids, and large vacuoles.
Animal cells have centrioles, which aid in cell
division, and lysosomes, which are involved in
digestion.
Plant cells lack centrioles and lysosomes, while
animal cells lack cell walls, plastids, and prominent
vacuoles.
BIOLOGICAL MEMBRANES
The fluid mosaic model describes the
structure of cell membranes, depicting them
as a bilayer of lipid molecules.
Proteins are embedded within this lipid
bilayer, resembling a mosaic pattern.
The membrane is fluid, allowing lipids and
proteins to move laterally within the layer.
Membrane lipids, especially phospholipids,
have a polar, hydrophilic "head" that is
water-attracted and a nonpolar, hydrophobic
"tail" that is water-repellent.
Phospholipids spontaneously form a bilayer,
with hydrophilic heads facing the watery
inside and outside of the cell and
hydrophobic tails facing inward, away from
water.
BIOLOGICAL MEMBRANES
Cell membranes perform several essential
functions beyond merely acting as barriers.
Selective Permeability: Membranes regulate
the passage of materials, allowing some
substances to enter or exit while blocking
others. For instance, the lipid bilayer prevents
ions and polar molecules like Na⁺ and Cl⁻
from passing through unaided. This regulation
helps maintain homeostasis, ensuring a stable
internal environment by controlling the influx
of nutrients and gases such as oxygen and
carbon dioxide.
BIOLOGICAL MEMBRANES
Cell membranes perform several essential
functions beyond merely acting as barriers.
Communication and Signal Reception:
Membranes play a role in cell communication
by receiving signals from the external
environment. Chemical messengers, like
hormones, bind to receptors on the
membrane and trigger responses within the
cell, allowing it to adapt to its surroundings.
Energy and Enzymatic Activity: Membranes
support crucial processes like energy
production. In mitochondria, membranes are
necessary for ATP synthesis, while in
chloroplasts, thylakoid membranes are vital
for capturing solar energy. Additionally,
membranes in organelles like the ER provide
sites for enzymatic reaction
BIOLOGICAL MEMBRANES

Simple Diffusion: During simple diffusion,
atoms and molecules move from areas of
higher concentration to areas of lower
concentration along a concentration gradient.
Membrane Structure: The cell membrane
consists of a fluid bilayer of phospholipids
with embedded membrane proteins. The
hydrophilic heads face outward toward the
watery surroundings, while the hydrophobic
tails point inward, avoiding water.
BIOLOGICAL MEMBRANES

Random Motion: Diffusion occurs due to the
constant random motion of atoms and
molecules, which collide and rebound in
different directions, eventually becoming
uniformly distributed.
Importance of Diffusion: Diffusion is crucial for
cellular functions, enabling the movement of
essential materials like oxygen, carbon
dioxide, and water in and out of cells.
However, larger or more polar molecules
cannot pass through the membrane by
diffusion alone.
BIOLOGICAL MEMBRANES

Osmosis: Osmosis is a type of diffusion specifically
involving the movement of water through a
selectively permeable membrane. It occurs from an
area with a higher concentration of water (lower
solute concentration) to an area with a lower
concentration of water (higher solute concentration).
Solute and Solvent: In biological systems, the solutes
are substances dissolved in water, and water itself is
referred to as the solvent.
BIOLOGICAL MEMBRANES

Isotonic Solutions: When a cell is placed in an isotonic
solution, the solute concentration inside and outside the
cell is equal. Water moves in both directions across the
plasma membrane at the same rate, maintaining
equilibrium.
Hypertonic Solutions: In a hypertonic solution, where the
solute concentration outside the cell is higher than
inside, water moves out of the cell. This causes the cell
to shrink as the cytoplasm loses water. An example
would be placing a cell in a concentrated sugar solution.
Hypotonic Solutions: A hypotonic solution has a lower
solute concentration outside the cell than inside. Water
moves into the cell, causing it to swell. For instance,
BIOLOGICAL MEMBRANES

Plant Roots: Roots are typically exposed to soil water,
which is hypotonic compared to the cytoplasm of the
root cells. This allows water to move into the plant,
supporting its hydration and nutrient uptake.
As water moves into root cells, their cell walls provide
structural support, enabling them to withstand the
pressure caused by the incoming water. This pressure is
referred to as turgor pressure.
Turgor pressure is the internal force of water pushing
against the cell wall. As the turgor pressure builds, an
equilibrium is eventually reached. At this point, the
turgor pressure forces water molecules out of the cell at
the same rate that water molecules enter through
SOME SUBSTANCES CROSS MEMBRANES BY
FACILITATED DIFFUSION OR ACTIVE TRANSPORT

Facilitated diffusion: Materials move from
high to low concentration through carrier
proteins in the membrane. This enhances
the diffusion of certain substances, such as
ions, but only in the direction of the
concentration gradient (high to low).
Facilitated diffusion does not require
energy.
Active transport: Materials move from a
lower concentration to a higher
concentration (against the concentration
gradient) with the assistance of carrier
proteins. This process requires energy,
usually supplied by ATP.
SOME SUBSTANCES CROSS MEMBRANES BY
FACILITATED DIFFUSION OR ACTIVE TRANSPORT

Active transport allows cells to
accumulate certain substances, like
potassium ions (K+), which are required
in higher concentrations within the cell.
Substances such as Na+ and H+ ions,
found in higher concentrations outside
the cell, can enter via diffusion or
facilitated diffusion but are expelled from
the cell through active transport to
maintain balance.