Cell Biology: The Cell PDF

Summary

This document provides an overview of cell biology, specifically detailing the cell theory, features, types, functions, and various organelles. Topics include prokaryotic and eukaryotic cells.

Full Transcript

CELL BIOLOGY: THE CELL

I. The Cell Theory
a. Cells are the basic unit of life.
b. Every organism is made up of cells (Schwann & Schleiden).
c. Every cell comes from pre-existing cells (Virchow).

II. What are the Basic Features of all Cells?
a. Plasma Membrane
b. Cytoplasm
c. Genetic Material
d. Basic Replicating and Protein-making machineries

III. What are the Two Types of Cells?
a. Prokaryotic Cells – cells that do not contain a nucleus do not have membrane-
bound organelles, small in size. Examples are bacteria and archaea
b. Eukaryotic Cells – cells that contain a nucleus, have membrane-bound
organelles, mostly larger than prokaryotes. Examples are plants, animals, fungi
and protists

IV. What do Cells do?
a. Cells acquire and synthesize energy-laden molecules
b. Cells synthesize proteins
c. A cell makes more copies of itself

V. The Prokaryotes
a. The first cell type in the world that arose 3.5 billion years ago
b. Basic Components of a Prokaryotic Cell:
1. Fimbriae – for attachment
2. Pilus – for conjugation (gene transfer between bacteria)
3. Flagella – for movement
4. Glycocalyx
i. Capsule – jelly-like outer coating outside the plasma membrane
ii. Slime Layer – unorganized slimy and sticky covering
5. Cell Wall – rigid structure made of carbohydrates and lipids
6. Plasma Membrane
7. Cytoplasm
8. Nucleoid – a region in the cytoplasm where bacterial DNA is concentrated
9. DNA & Plasmid – Plasmid is a circular DNA molecule in a prokaryotic cell
10. Endospore – formed when bacteria are exposed to harsh conditions
c. There are only two kinds: Bacteria (Kingdom Eubacteria) and Archaebacteria
(Kingdom Archaebacteria)

VI. Basic Morphology of Bacteria
a. Coccus (cocci) – spherical or oval shape
b. Bacillus (bacilli) – rod, elongated cylindrical shape
c. Spiral – curve, spiral (spirilla), or twisted spring (spirochete)
d. Vibrio – comma-shaped e.g. Vibrio cholera
e. Pleomorphic – no exact shape at a given time

VII. What are the Prefixes Used to Describe the Arrangement of Eubacteria?
a. Diplo: two
b. Staphylo: cluster
c. Strepto: chain
d. Tetrad: four
 e. Sarcina: 8 to 64 (3-D)

VIII. The Origin of the Eukaryotes
Endosymbiosis (Endosymbiont Theory) states that eukaryotic cells result from
endosymbiosis of a prokaryote and aerobic bacteria (becomes mitochondrion), and
later a cyanobacteria-photosynthetic prokaryote (becomes chloroplast).
a. Nucleus and the ER: Invagination of the plasma membrane produced the nuclear
envelope and the ER
b. Mitochondria: Engulfing of an aerobic prokaryote resulted to a symbiotic
relationship
c. Chloroplasts: Engulfing a photosynthetic prokaryote (cyanobacteria) led to a
symbiotic relationship

IX. What are the Basic Structures of a Eukaryotic Cell?
a. Cell Membrane – controls what gets in and out of the cell
b. Cytoplasm – where organelles float & chemical reaction occur
c. Nucleus – control center of the cell
1. DNA – deoxyribonucleic acid; the genetic code; packaged into chromosomes
i. Chromatin – the tangled spread-out form of DNA
ii. Chromosomes – condensed form of chromatin
2. Nucleolus – spherical body inside the nucleus which assembles ribosomes
3. Nuclear envelope – also known as the nuclear membrane; covers the
nucleus
4. Nuclear pores – holes on the nuclear envelope that regulate entry of
materials
d. Other organelles – structures that act like specialized organs

X. Organelles that Build Proteins – because proteins carry out so many of the
essential functions of living things, a big part of the cell is devoted to their production
and distribution
a. Ribosomes – the protein factories of the cell
1. Synthesize protein by reading the instructions to build proteins from DNA
2. Some are free in cytoplasm
3. Some are attached to Endoplasmic Reticulum (ER)
4. Structure: composed of large and small subunit

b. ER is primarily composed of network of membranes, with parts known as
cisternae (tubes) and lumen (inside)
i. Works on membrane proteins, makes membranes, passageway for
transporting materials through transport vesicles
ii. Regions of the ER:
- Rough ER – ribosomes are attached to it; primarily works on
proteins
- Smooth ER – without ribosomes; makes lipids (sterols), makes
new membranes, storage of calcium ions
c. Golgi bodies – receiving, sorting and shipping of cell materials
i. Finishes, sorts, labels and ships proteins like a logistic service
ii. Ships proteins in vesicles
iii. “logistic trucks” of the cell
iv. Structure: Membranous flat sacs
- Cis face receives from ER
- Trans face ships products
XI. Organelles that Store, Clean-up & Support
a. Vacuoles – storage tanks of the cell (storage materials like water, salts, proteins
and carbohydrates)
i. Central vacuole – large vacuole found in plants
 ii. Food vacuole – small vacuole found in animals
iii. Contractile vacuole – found in protest for maintaining a suitable
concentration of ions and molecules inside the cell
b. Vesicles – smaller than a vacuole, carries and transports substances
- Buds off from the ER, the Golgi bodies, or from the cell membrane
c. Lysosomes – suicidal bags/ recycle bins of the cell
1. Carries out intracellular digestion: phagocytosis
2. Breaks down damaged organelles: autophagy
3. Structure: membranous sac of hydrolytic enzymes that many eukaryotic cells
use to digest (hydrolyze) macromolecules
d. Cytoskeleton – the skeletal system of the cell
1. Functions: mechanical support, anchor organelles, help move substance and
the cell
2. Made of filaments and fibers:
i. Microfilaments (actin) – also called actin filaments because they are
built from molecules of actin
- The amoebic cell crawls along a surface by extending cellular
extensions called pseudopodia by contractions of actins
- Cytoplasmic streaming, a circular flow of cytoplasm within plant
cells, is accomplished through contractions of actin.
ii. Intermediate filaments (keratin) – only found in the cells of some
animals, including vertebrates
iii. Microtubules (tubulin) – hollow rods constructed from a globular
protein called tubulin structures derived from microtubules are the
following:
- Centrosome and Centrioles: Organizers of Cell Division
Help coordinate cell division, common in animal cells
Structure:
✓ Centrosome is a region that contains the
centrioles
✓ Centrioles are made of nine sets of triplet
microtubules arranged in a ring
- Cilia – group of short hair-like extensions used to move
substances outside human cells; in humans, cilia can be
found in the lining of trachea and the oviduct
- Flagella – whip-like extensions; in humans, flagellum is
found among sperm cells

XII. Organelles That Capture & Release Energy
a. Mitochondria – powerhouse of the cell; “power plant”
1. make ATP energy by cellular respiration; fuels the work of life
2. Structure: Double membrane
i. Cristae – infoldings of the inner membrane
ii. Matrix – inner space
iii. Intermembrane space – space between the inner and outer
membrane
b. Plastids – specialized pigment-containing organelles
1. Chromoplast – red, orange, and yellow-colored plastids that contain
pigments called carotenoids.
2. Leucoplast – colorless plastids
c. Chloroplasts – convert solar energy into chemical energy; found only in
autotrophs; “solar plant”
1. derived from photosynthetic bacteria; solar energy-capturing organelle
2. Structure: Double membrane
i. Thylakoid – coin-like structure
 ii. Grana – stacks of thylakoid
iii. Stroma – spaces between grana

XIII. Cellular Boundaries
a. Cell Membrane (Plasma Membrane) – regulates the entrance and exit of
substances
1. Structure primarily made of:
i. Phospholipid molecules
Nature and Structure of Phospholipids
- A phospholipid is an amphipathic molecule that has
a polar phosphate head that can interact with water molecules
nonpolar two fatty acid tails that cannot interact with water
ii. Proteins
- Integral proteins – penetrate the hydrophobic interior of the lipid
bilayer
- Peripheral proteins – not embedded in the lipid bilayer at all; they
are appendages loosely bound to the surface of the membrane
iii. Glycoproteins – carbohydrates + protein
iv. Glycolipids – carbohydrates + phospholipids
v. Cholesterol

2. What is The Fluid Mosaic Model? – a model that shows the structure and
arrangement of the plasma membrane
3. What is the characteristic of the plasma membrane?
i. The membrane is semi-permeable.
ii. The membrane is fluid.
iii. The membrane is structurally and functionally a mosaic of lipids, proteins
and carbohydrates.
b. Cell Wall – shapes, supports and protects the cell against force and pressure;
provides much of the strength needed for plants to stand against the force of
gravity

Cell Walls differ in composition in every kingdom:
i. In plants it is made of cellulose, pectin, and some with lignin.
ii. In fungi it is made of chitin and glucans.
iii. In bacterial it is made of peptidoglycan.

XIV. Cell Junctions – structures that connect cells; neighboring cells often adhere,
interact, and communicate via sites of direct physical contact
a. Plasmodesmata – channels in cell walls that connect plant cells
b. Cell junctions in animal cells:
1. Tight junctions – cells are very tightly pressed against each other, bound
together by specific proteins e.g. tight junctions between skin cells make us
watertight.
2. Desmosomes – made of intermediate filaments made of sturdy keratin
proteins anchor desmosomes in the cytoplasm; Desmosomes attach muscle
cells to each other in a muscle
3. Gap junctions – similar to Plasmodesmata in plants; they are channels
between neighboring cells that allow for the transport of ions, water, and
other substances