General Biology 1 Review - WVSU College of Medicine - PDF

Summary

This document is an outline for a General Biology 1 course, covering main characteristics, cell theory, cell structure, cell modification, and prokaryotic vs. eukaryotic cells in detail. The document references different authors and types of cells.

Full Transcript

General Biology 1 Quarter 1
By: 11-STEM 1

OUTLINE 2. Cell is a basic unit of life
I. Main Characteristics of an Organism 3. All cells came from pre-existing cells
II. The Cell Theory Omnis cellula e cellula Expanded version of
III. Cell Structure and Functions
the cell theory
A. Cell Membrane
B. Cytoplasm 4. Cells carry genetic material passed to daughter
C. Nucleus cells during cellular division
IV. Prokaryotic vs. Eukaryotic Cells 5. All cells are essentially the same in chemical
V. Cell Types composition
A. Plant Tissue 6. Energy flows (metabolism and biochemistry
B. Animal Tissue
occurs within cells)
VI. Cell Modifications

I. MAIN CHARACTERISTICS OF AN ENDOSYMBIOTIC THEORY
ORGANISM Lynn Margulis – American Biologist
 It is made of cell  Provided evidence that some organelles within the
 Requires energy cells were at one-time free-living cells themselves
 Able to reproduce  Organelles with their own DNA
 Maintains homeostasis  Chloroplasts and Mitochondria
 They are organized
 Grow and develop III. CELL STRUCTURE AND
 Exchanges materials with the surroundings
FUNCTIONS
 Needs of water
 A cell has is divided into three structures: Plasma
 Definite lifespan
Membrane, Cytoplasm, and Nucleus
 Has genes and heredity

II. THE CELL THEORY
PEOPLE BEYOND THE CELL THEORY
Robert Hooke
 Published the “micrographia” on 1665
 Observed a box-shaped structure which he called
“cells” as they reminded of him of the cells or room
in monasteries
Antonie van Leeuwenhoek
 On 1670s, he discovered bacteria and protozoa
Matthias Shleiden – German Botanist
Figure 1. This generalized cell shows the major organelles
 He concluded that all plants are made of cells contained in cells. However, no single cell contains all of these
Theodore Schwann – German Zoologist organelle types. Furthermore, one kinde of cell may contain
 He concluded that all animals are made of cells many organelles of one type, whereas another kind of cell may
Rudolph Virchow contain very few.
 Observed under a microscope the cells are dividing A. PLASMA MEMBRANE
 He reasoned that all cells came form pre-existing Plasma Membrane/Cell Membrane
cells by cell division  Outermost component of the cell
PORTIONS OF THE CELL THEORY  Substances outside the cell are called extracellular
Modern Cell Theory substances

1. All life is composed of one or more cells

WVSU COLLEGE OF MEDICINE | Trans Group # - Surname1, Surname2, Surname3, Surname4, Surname5 1 | 13
  While substances inside the cell are called B. NUCLEUS
intracellular substances
The Central Organelle – Nucleus
 Acts a selective barrier that determines what moves
 Largest organelle
into and out of the cell
 Nucleus is bounded by nuclear envelope
 Major molecule that makes up the cell membrane
 The nuclei of human cells have 23 pairs of
are phospholipids and proteins
chromosomes, which consists of DNA and proteins
 The polar, phosphate-containing ends of the
 Controls the normal activities of the cell
phospholipids are hydrophilic (water-loving) and
 Contains the DNA and chromosome
therefore face the extracellular and intracellular fluid
Nuclear envelope
of the cell
 Double membrane surrounding the nucleus
 The nonpolar, fatty acid ends of the phospholipid are
 also called nuclear membrane
hydrophobic (water-fearing) and therefore face away
 connected to the rough endoplasmic reticulum
from the fluid on either side of the membrane
Inside the Nucleus
 where the genetic materials is found
 DNA is spread out and appears as chromatin in non-
dividing cells
 DNA is condensed and wrapped around proteins
forming as chromosomes in dividing cells
What does DNA do?
 It is the hereditary material of the cell
 Genes that make up the DNA molecule code for
different proteins
 Composed of proteins and phospholipid bilayer Nucleolus
Figure 2. cell membrane
 Located inside the nucleus
Phospholipids Bilayer
 Cell may have one to three nucleoli
 Heads
 Disappears when cell divides
 Contains glycerol and phosphate
 Makes ribosomes that makes protein
 hydrophilic
 Found within the nucleus
 Tails
 Subunits of ribosomes are formed within the
 are made of fatty acids
nucleolus
 hydrophobic
 proteins produced in the cytoplasm move through
Cell Membrane Proteins
the nuclear pores into the nucleus, and into the
 helps more large molecules
nucleolus
 aids in cell recognition
C. CYTOPLASM
 Peripheral proteins
 Attached on the surface  Cytoskeleton
 Integral proteins  Consists of proteins that support the cell, hold
 Embedded completely through the membrane organelles in place, and enables the cell to
 Glycoproteins change shape
 have carbohydrate tails to act as markers for cell  Helps maintain the cell shape
recognition  Helps organelles move around
Cell Wall  Microtubules, microfilaments, and intermediate
 non living organism filaments
 made of cellulose in plants  Microfilaments are thread-like
made up of Actin
 made of peptidoglycan in bacteria
  microtubules are tube-like
made of chitin in fungi
made up of Tubulin
 supports and protects cell
Centrioles
 found outside the plasma membrane

Y2 B9 M1 L2 | Lecture Title 2 | 13
  is a specialized zone of cytoplasm close to the  lacks of ribosomes on its surface
nucleus, where microtubules formation occurs  attached to the end of rough E.R.
 only found in animal cells  makes the cell products that are used inside the
 paired structure around nucleus cell
 made of bundles of microtubules  males membrsne lipids (streroid)
 appear during cell division farming mitotic spindle  regulates calcium (muscle cells)
 help to pull chromosome pairs apart to opposite  destroy toxic substances (liver)
ends of the cell Ribosomes
Mitochondria  are the organelles where proteins are produced
 singular = mitochondrion  ribosomes may be attached to other organelles such
 are small organelles with inner and outer as the RER
membranes separated by space.  ribosomes that are not attached to any organelle are
 The outer membrane has smooth contour called free ribosomes
 The inner membrane has numerous folds, called  protein functions for cell
cristae  joins amino acids to make protein
 generate cellular energy (ATP)  process called protein synthesis
 Adenosine Triphosphate) Golgi Body
 Carry out aerobic respiration, a series of chemical  consists of closely packed stacks of curved,
reaction that require
2 to break down food membrane-bound sacs
molecules to produce ATP  collects, modifies, packages, and distribute proteins
 Mitochondria came from cytoplasm in the egg cell and lipids manufactured by the rough ER
during fertilization  have trans face and cis face
 You inherit your mitochondria from your mother Lysosome
 membrane-bound vesicles formed from the Gogi
Body
 contains variety of enzymes that function as
intracellular digestive systems
 break down food, bacteria, and warm out cell parts
 programmed for all cell death (autolysis)
 Lyse (break open) and release enzymes to break
down and recycle cell parts
 Lysosome Digestion
 Cells take in food by phagocytosis
Figure 3. mitochondrion Lysosome digest the food and get rid of the
Endoplasmic Reticulum waste
 Is a series of membrane forming sacs and tubules Cilia and Flagella
that extends from the outer nuclear membrane into  Cilia
the cytoplasm  Singular; cilium
 Hollow membrane tubules  Project from the surface of thecell
 Connects to nuclear membrane and plasma  Cilia are cylindrical strucutres that extend from
membrane the cell
 Functions in synthesis of cell products and transport  Cilia are composed of microtubules, organixed in
 Rough E.R. a pattern similar to that of centrioles, which are
 has ribosomes on its surface enclosed by the cell membrane
 makes membrane protein and protein for exports  Flagella
out of cell  Singular; flagellum
 protein are made by ribosomes on rough E.R.  Have a similar structure to that Cilia but are
 hreaded to the interior of rough E.R. much longer, and they usually occure only one
 smooth E.R. per cell

Y2 B9 M1 L2 | Lecture Title 3 | 13
  Sprerm cells each have one flagellum, whic
propels the sperm cell
 Made of microtubules
 9+2 arrangement – (microtubules)
 Function in moving cells, in moving fluids, or in small
particles across the cell surface
Cilia Flagella
shorter Longer
Numerous on cells Fewer (usually 1-3) on
cells
Vacuoles Figure 4. Prokaryotic cell
 Fluid filled sacs of storage Prokaryotes
 Small or absent in animal cells  The first cells
 No vacuoles in bacterial cells  Cells that lack nucleus and membrane-bound
 In plant, they store cell sap organelles
 Includes storage of sugars, proteins, minerals, lipids,  Simplest type of cells
wastes, salts, water, and enzymes  Single, cellular chromosome
Contractile Vacuole  Includes bacteria
 Found in unicellular protist like paramecia  Nucleoid regions (center) contains the DNA
 Regulate water intake by pumping out excess  Surrounded by a cell membrane and cell wall
 (homeostasis) (peptidoglycan)
 Keeps the cell from lysing (bursting)  Contains ribosomes (no membrane) in their
Chloroplast cytoplasm to make proteins
 Found only in producers (organisms containing
chlorophyll)
 Use energy from sunlight to make our food
 (glucose)
 Stored in chemical bonds of sugar
 Double membrane
 Inner membrane modified into sacs called thylakoids
 Thylakoids in stacks called Grana and
interconnected
 Stroma – gel like material surrounding thylakoids Figure 5. An animal cell and a plant cell
 Contains its own DNA
Contains pigment for photosynthesis B. EUKARYOTIC CELLS
 Photosynthesis – food making process
Eukaryotes
 Cells that have a nucleus and membrane-bound
IV. PROKARYOTIC VS. EUKARYOTIC organelles
CELLS  Includes protists, fungi, plants, and animals
A. PROKARYOTIC CELLS  Makes complex cell types of cells
 Contains three basic structures:
 Plasma membrane or cell membrane
 Nucleus
 Cytoplasm
 Two main types of eukaryotic cells:
 Animal cell
 Plant cell

Y2 B9 M1 L2 | Lecture Title 4 | 13
 V. CELL TYPES  Help to increase the length of the internode
Tissue – group of cells having a similar structure  Part of the apical meristem and adds to the height of
and functions the plant
A. PLANT TISSUE  Usually seen in monocotyledonous plants
Lateral Meristematic Tissue

 Lateral side of the stem and root of a plant
 Help in increasing the girth or thickness of the plants
 These divide preclinically or radially and give rise to
secondary permanent tissues.

PERMANENT TISSUE

 Permanent tissue cells do not usually divide any
further
 The tissues that are completely grown and have lost
Figure 6. Plant tissue concept map the ability to divide
Plant tissue  Meristematic tissues divide and differentiate to form
 do not move/static the permanent tissue
 growth of plants takes place on a particular region  Three types:
 types of plant tissue  Simple
 meristematic tissue – group cells that have the  Complex
ability to divide  Secretory
 permanent tissue – consisting of cells that are Simple Permanent Tissue
no longer actively dividing  Also known as homogenous tissue
MERISTAMATIC TISSUE  They are made up of a single cell type, usually with
 type of tissue found in lants the same origin, structure, and function
 consists of undifferentiated cells capable of cell  Has a thick layer of walls and is full of protoplasm.
division  It is one of the most abundant and common tissues
 meristem classification: that can be found easily in the plant body
 apical meristem  Three types:
 lateral meristem  Parenchyma
 intercalary meristem  Collenchyma
Apical Meristematic Tissue  Sclerenchyma

 present at the tips of the roots and shoots
 helps in the growth and increase of the height of the
plants
 various cell divisions facilitate the growth of the cells
in the roots and shoots and help in cellular
enlargement
 divided into:
 promeristem zone – contains actively dividing
cells
 meristematic zone – contains protoderm, Figure 7. Three types of simple permanent tissue
procambium, and ground meristem. Parenchyma
Intercalary Meristematic Tissue  Parenchyma is composed of hemicellulose or
 located at the base of the leaves and internodes at cellulose and has several small vacuoles
the intercalary position.  In the older parenchyma, smaller vacuoles merge to
become a large central vacuole, which may

Y2 B9 M1 L2 | Lecture Title 5 | 13
 accumulate anthocyanin or tannins, a large central baking. It is also sometimes used to make medicine.
vacuole. Pectin binds substances in the intestine and adds up
 Parenchyma tissue is a type of simple plant tissue bulk to the stools
composed of living cells with thin cell walls  types of Collenchyma:
 Its primary function is to perform various metabolic  Angular Collenchyma
activities such as photosynthesis, storage of It is the most common type of collenchyma
nutrients, and providing structural support to organs. Thickening of walls only occurs at the
 Type of Parenchyma: corners
 Chlorenchyna Intercellular spaces are absent and they
Cells which have chloroplasts and perform have a circular lumen.
photosynthesis  Lacunar Collenchyma
 Xylem parenchyma Has intercellular spaces
It stores food materials like starch, fats and Thickening is more at the places adjacent to
other substances such as tannins and intercellular spaces
crystals.  Lamellar Collenchyma
Storage Parenchyma – these store various They are also called plate collenchyma
substances like water, starch, proteins, etc. They have thickened tangential walls and
They act as a food and water reservoir are arranged into ordered rows
 Prosenchyma  Annular Collencyma
These are fiber-like elongated cells, which The ells are uniformly thickened
are thick-walled and provide rigidity and
strength to the plant.
 Arenchyma
They contain very large intercellular spaces
These are present in aquatic plants

Figure 9. Types of collenchyma
Sclerenchyma
 Sclerenchyma cells have thick, lignified secondary
walls, lack of cell contents at maturity, and occur
throughout all plant tissues
 These features make sclerenchyma tissues hard,
rigid, and somewhat brittle
 Sclerenchyma cells can occurs as aggregates within
Figure 8. Types of parenchyma ground tissues (sclereids or stone cells or as
Collenchyma elongated fibers)
 Helps in the formation of plant tissue  Sclerenchyma provides mechanical strength to
 It helps the plant by giving rigidity, flexibility, and stems (fibers in hemp and flax) and reproductive
elasticity structures (the texture in pear flesh, the stony shells
 it is made up of thick and strong strands of cellulose of nuts and cherry pits
that are twisted with each other Complex Permanent Tissue
 cells of collenchyma generally grow constantly that
 The complex permanent tissues are made up of
is why it is easily found on stems, leaves, shoots of
more that one type of cells
the plants
 They coordinate together to perform the same
 collenchyma cells may or may not contain a few
specialized functions in the plant body.
chloroplasts, and may perform photosynthesis and
 Two types
store food
 Xylem
 pectin – is a soluble fiber (polysaccharide) found in
 Phloeom
fruits. It us used as a thickener in cooking and
Xylem

Y2 B9 M1 L2 | Lecture Title 6 | 13
  The xylem tissue is responsible for the conduction of Permanent ground tissue
that will form the bulk of a
water and minerals from the roots to the leaves and
plant.
stem Phloem Fiber Stores compound such as
 Xylem is an important plant tissue as it is part of the starch.
sclerenchyma cells, which
plumbing of a plant. are non-living cells in the
 It also provides support to the plants phloem, providing structural
support to the
 The water-transporting cells of mature xylem are
dead, therefore the transport of water is mostly a
passive process with a very small active root
B. ANIMAL TISSUE
pressure
 Four elements: Animal tissue
Tracheid tubular cells in the xylem  It moves
of vascular plants that  Needs more energy
play a role in mineral and  Four types of animal tissue:
water transport from the  Epithelial tissue
roots to the leaves.  Connective tissue
Vessels vessels are elongated  Muscle tissue
dead cells with punctured  Nervous tissue
cell walls through which Tissue Cells ECM Functions
water flows. Epitthelial Aggregated Small Lining of
Xylem Parenchyma responsible for storing the polyhedral amount surface or
prepared food and assists cells body cavities;
in the conduction of glandular
water. secretion
Xylem Fibers protect and provide Connective Several Abundant Support and
mechanical support to the types of amount protection of
xylem's major water-carrying
tissues. fixed and tissues/organs
Water is transported through wandering
xylem fibers. cells
Table 1. Four elements of Xylem
Muscle Elongated Moderate Strong
contractile amount contrations;
Phloem
cells body
 helps in the translocation of food that is prepared by
movements
photosynthesis in the leaves to various parts of the
Nervous Elongated Very small Transmission
plant.
contractile amount of nerve
 transport system for soluble organic compounds
wit impulses
within vascular plants.
extremely
 The phloem is made up of living tissue, which uses
fine
turgor pressure and energy in the form of ATP to
processes
actively transport sugars to the plant organs
 Four elements:
EPITHELIAL TISSUE
Sieve Tubes Transport sugars, amino
acids and nutrients up  Shapes and dimensions of epithelial cells are quite
and down the plants in variable, ranging from tall columnar to cuboidal to
sieve cells. low squamous cells
Companion Cells Controls the activity of the  Columnar cells
sieve tube.
 Have elongated nuclei
Responsible for transporting
assimilates into and out of  Squamous cells
the sieve tubes.  Flattened nuclei
Phloem Parenchyma Provides mechanical
strength to the plant.  Cuboidal (pyramidal)

Y2 B9 M1 L2 | Lecture Title 7 | 13
  Have more spherical nuclei and thickness are roughly similar) , or columnar
 The connective tissue that underlies the epithelia (cells taller than they are wide)
lining organs of the digestive, respiratory, and  Stratified Epithelia
urinary systems, is called the lamina propria  Contains two or more layers
 Forms the outer layer of the body and also lines  Stratified squamous keratinized epithelium is
many of the bodies cavities where it has a protective found mainly in the epidermis of skin, where it
function. helps prevent dehydration
 Epithelial tissue usually consists of a single layer of  Types of Epithelial Tissues
cells, however in certain cases there may be more Figure 10. types of epithelial tissue
than one layer.
 All epithelial tissues are free surfaces attached to the CONNECTIVE TISSUE
underlying layers of a basement membrane.  Connective tissues provides a matrix that supports
 Functions: and physically connects other tissues and cells
 Provides a barrier between the external together to form the organs of the body
environment and the organ it covers.  Its major constituent is the extracellular matrix (ECM)
 Specialized to function in secretion and  All connective tissues originate form embryonic
absorption. mesenchyme, a tissue developing mainly from the
 Protects organisms from microorganisms, injury, middle layer of the embryo, the mesoderm.
and fluid loss.  Mesenchymal cells are undifferentiated and have
 Excretes waste products such as sweat from the large nuclei, with prominent nucleoli and fine
skin. chromatin
Types of Epithelia
 All connective tissue is made up of cells, fibers (such
 Epithelia can be divided into main groups: Covering as collagen) and extracellular matrix.
(lining) Epithelia and Secretory (glandular) Epithelia  ECM 3 major components
Covering (lining) Epithelia  Protein fibers
 are organized into one or more layers that cover the  Ground substances – consisting of nonfibrous
surface or line the cavities of an organ protein and other molecules
 epithelia are classified according to the number of  Fluid
cell layers and cell morphology in the outer layer.  Three types of protein fibers
 Simple Epithelia  Collagen fibers
 Contain one cell layer  Reticular fibers
 Simple Epithelia are futher classified as  Elastic fibers
squamous (thin cells), cuboidal (cell wideth Functions of Connective Tissue

 Enclosing and separating other tissues
 Connecting tissues to one another
 Supporting and moving parts of the body
 Storing compounds
 Cushioning and insulating
 Transporting
 Protecting

MUSCLE TISSUE

 The main characteristics of a muscle tissue is its
ability to contract, or shorten, making movement
possible
 Sometimes called muscle fibers because they often
resemble tiny threads
 Three types of muscle tissue:

Y2 B9 M1 L2 | Lecture Title 8 | 13
  Skeletal  Cell body
 Cardiac  Densrites
 Smooth  Axons
Skeletal muscle
 Is what we normally think as a “muscle”
 It is the meat of the animals and constitutes about
40% of a person’s body weight
 Skeletal muscle attached to the skeleton and
enables body to move
 Voluntary (under conscious control) Figure 11. nervous tissue
 Tend to be long and cylindrical, with several nuclei  Three types of neurons:
per cell  Interneurons
 Skeletal muscles cells are striated  Motor neurons
Cardiac muscle  Sensory neurons
 Is the muscle of the heard Sensory Nerves
 It is responsible for pumping blood  The sensory nerves or sensory neurons are
 Involuntary (unconscious) control responsible to generate impulses or signals in the
 Cylindrical but shorter than skeletal muscle cell contrasting directions from another type of nerves
 Usually, one nucleus per cell known as the motor neurons
Smooth Muscle Motor Neurons
 Forms the walls of hollow organs (except heart)  Motor neurons or motor nerves are responsible to
 Found in eyes and skin send signals or impulses all the way from the spinal
 Smooth muscle om controlled involuntarily cord and brain to all the muscles of the body. The
 Single nucleus and striated impulse enables humans to carry out basic activities
Autonomic Nerves
NERVOUS TISSUE  The autonomic nervous system controls the actions
of the muscles of the heart, such smooth muscles
 Forms the brain, spinal cord, and the nerves
located in the stomach and in the interlining of
 It is responsible for coordinating and controlling
glands and other organs.
many bodies activities
 Three components:
CARTILAGE AND BONE
 Neurons
These are the structural and functional units Cartilage
of the nervous system. It comprises an axon,  Is a tough, durable form of supporting connective
cell body and dendrites. tissue characterized by an ECM with high
 Neorolgia concentrations and proteoglycans, interacting with
These are special cells found in the brain collagen and elastic fibers
and spinal cord. They provide support to the Bone
neurons and fibers.  Provides solid support for the body, protects vital
 Neurosecretory cells organs such as those I cranial and thoracic cavities
These function as endocrine organs. They  Bone (or osseous) tissue serves as the reservoir for
release chemicals from the axons directly calcium, phosphate, and other ions
into blood  Bone is a specialized connective tissue composed of
 Many of these functions depend on the ability of calcified ECM, the bone matrix, and the following
nervous tissue cells to communicate with one three major cell types:
another and with the cells if other tissues by means  Osteocytes
of electrical signals called action potentials (Gr. Osteon, bone + kytos, cells)
 Nervous tissue consists of neurons and support cells Which are found in cavities (lacunae)
 It is composed of three parts: between bone matrix layers (lamellae), with

Y2 B9 M1 L2 | Lecture Title 9 | 13
 cytoplasmic processes in small canaliculi  Are minute fragments of cells, each consisting of a
that extend to the matrix small amount of cytoplasm surrounded by the cell
 Osteoblasts membrane
(osteon + Gr. Blastos, germ)  Thrombocytes – scientific name
Growing cells with synthesizes and secrete
the organic components of the matrix
VI. CELL MODIFICATION
 Osteoclasts
A. MERISTEMATIC TISSUE
(osteon + Gr. klastos, broken)
Giant, multinucleated cells involved in Cell specialization, modification, differentiation
removing calcified bone matrix and  specialized or re-acquired by the cell after cell
remodeling bone tissues division that helps different beneficial ways.
 process that occurs after cell division where the
BLOOD newly formed cells are structurally modified so that
they can perform their function efficiently and
 Blood is regarded as a specialized form of
effectively
connective tissue because it originates in the bones
 features or structure of the cell that makes it different
and has some fibers.
from another type of cell and at the same time
 Blood is composed of red blood cells, white blood
enables it to carry out unusual function
cells and platelets.
Why does it occur?
 These components are suspended in a yellow fluid
 Plant and animal cells are specialized to be able to
known as plasma.
carry out their tasks efficiently
Blood helps maintain homeostasis in several ways:
 They have particular adaptation to their structure to
 Transport of gases, nutrients, and waste productions
suit its function.
 Transport processed molecules Types of Cell Modification
 Transport regulatory molecules  Apical Modification
 Regulations of pH and osmosis  Basal Modfication
 Maintenance of body temperature
 Protection against foreign substances
 Clot formation
Red Blood Cells

 About 95% of the volume of the formed elements
consists of red blood cells (RBCs), erythrocytes
(erythro-red + kytos, cells)
 The remaining % are composed of White Blood
Cells and Platlets
 120 days – lifepsan
 Carries hemoglobin; a protein which carries oxygen
White Blood Cells  Lateral Modification
Figure 12. cell modification concept map
 Are spherical cells that lacks hemoglobin
APICAL MODIFICATION
 Buffy coat – a thin, white layer of cells between
plasma and red blood cells  Apical modification occurs in the apical surface.
 Each have nucleus  found in the apical surface of the cell
Cilia and Flagella
 Protects the body from pathogens
 Leucocytes – scientific name  usually short, hair-like structure that moves in waves
 Lymphocytes  flagella are long whiplike structures
 Are the smallest white blood cells  formed from microtubule
Platelets Villi and Microvilli

Vili

Y2 B9 M1 L2 | Lecture Title 10 | 13
  Fingerlike projections rise from epithelial layer Basal Infoldings
 Helps increase surface area allowing for faster and
 Oten found in epithelium that are known to transport
more efficient absorption
fluid (kidney)
Microvilli
 Will often see mitochondria in the basal infoldings
 Small projections that arise from cells surface that
 Suggests that active transport is occuring
also increase surface area allowing faster and more
efficient absorption.
Stereocilia

 Stereocilia are non-motile apical modifications of the
cell, which are distinct from cilia and microvilli, but
closely related to the latter.
 Long microvilli that function in increasing absorption
 Found in sensory cells in ear and male reproductive
tract
 Does not have the true characteristic of true cilia or
flagella  Very important in epithelial polarization and stability
 Stereocilia are the mechanoenzyme organelles of  Support the epithelium and also functions as a
hair cells, which respond to fluid motion in numerous passive molecular sieve or ultra filter
types of animals for various functions, including
hearing and balance. LATERAL MODIFICATION
Pseudopods/Pseudopodium
 A type of cell modification that is found in the lateral
 Temporary, irregular lobes formed by amoebas and surface of the cell
some other eukaryotic cells Tight Junction
 Bulge outward to move the cell and engulf prey
 Act as a barrier that regulate the movement of water
 Used in movement and as a tool to capture prey and solutes between epithelial layers
Extracellular Matrix
 Prevent leakage of extracellular fluid
 Compound secreted by the cell on its apical surface Adhering Junction
 Cell wall  It anchors junction on the lateral surface of the cell
 Is the extracellular structure in plant cells that
 It is similar to the anchoring junction of the basal
distinguishes them from animal cells
surface of the cell
 Glycoprotein
 Fasten cells to one another
 Is the main ingredient of ECM in animal cell
Gap Junction

BASAL MODIFICATION  communicating junctions
 closeable channels that connect the cytoplasm of
 Found in the basal surface of the cell
adjoining animal cells
Desmosomes/Hemidesmosomes
 presence of connexon that allow direct exchange of
 Anchoring junction on the basal surface of the cell chemicals between the cytoplasm of two cells
 Rivet-like links between cytoskeleton and
extracellular matrix components such as the basal VII.CELL CYCLE
lamina that underline epithelia Two stages
 Primarily composed of keratin, integrins, and  Interphase
cadherins  Mitotic phase
 Desmosomes are junctions involved in intercellular INTERPHASE
adhesion of epithelial cells and hemidesmosomes
are junction involved in adhesion of epithelia to  The stage in the development of a cell between two
basement membrane successive divisions
 Interphase is the longest phase of a cell cycle

Y2 B9 M1 L2 | Lecture Title 11 | 13
  During this phase the cell grows to its maximum size, around the daughter chromosomes that have
performs its normal cellular functions, replicates its gathered at each of the poles.
DNA, and prepares for cell division Figure 14. Mitosis
 Three stages: Cytokinesis
 G1  The cytoplasm then divides during a process called
First intermediate gap stage in which the cell
cytokinesis.
grows and prepares for DNA replication
 Cytokinesis is not a stage of mitosis but the process
 S phase
of the cytoplasm splitting into two. In an animal cell
Synthesis stage in which DNA is replicated.
the cell membrane constricts.
 G2
Second intermediate gap stage in which the
cell finishes growing and prepares for cell
division. REVIEW
 G0 1. Question
G0 is not a stage of the cell cycle. Some A. Choice
cells no longer need to divide and exit the B. Choice
cell cycle. These cells may exit the cell cycle C. Choice
permanently. D. Choice
2. Question
Figure 13. Phases of cell cycle A. Choice
MITOTIC PHASE B. Choice
C. Chioice
 The period of the cell cycle in which the cell and D. Choice
contents divide to create two genetically identical
daughter cells Answer key
 2 processes:
TRANS COMM
 Mitosis
Why did cell stay in bed?
Prophase
 It lacks of mitochondria!
Metaphase
What did one cell said to another cell that stepped
Anaphase
on her toe?
Telophase
 My toe sis
 Cytokiness
What do you call a cell that does not share its
Mitotis
reviewer?
Prophase  Cell-fish
 The chromatin material shortens and thickens into Anong cell ang maihrap pegelan?
individual chromosomes which are visible under the  Cell-los
light microscope.
 Each chromosome consists of two strands or GOODLUCK SA MIDTERMS GUYS! KAYA TA NI!!
chromatids joined by a centromere.
Metaphase
 During metaphase, chromosomes line up on the
equator of the cell.
REFERENCES
 The chromosomes appear in a straight line across (Tana, General Biology 1, 2023)
the middle of the cell. (VanPutte, Regan, & Russo)
Anaphase
 During anaphase the chromatids are pulled to opposite
poles of the cell by the shortening of the spindle fibers.
Telophase
 During telophase, a nuclear membrane reforms

Y2 B9 M1 L2 | Lecture Title 12 | 13
Y2 B9 M1 L2 | Lecture Title 13 | 13