Biology Exam #2 Study Notes PDF

Summary

These study notes cover the four major classes of macromolecules: carbohydrates, lipids, proteins, and nucleic acids. The notes include details on monomers, polymers, dehydration synthesis, hydrolysis, and related enzymes. The document also discusses different types of carbohydrates, lipids, and their functions.

Full Transcript

Four major classes of macromolecules
1. Carbohydrates
2. Lipids
3. Proteins
4. Nucleic acids
Organic molecules
all contain carbon (may also contain hydrogen, oxygen, nitrogen, and some other
minor elements)
Monomers
Individual subunits of macromolecules
Polymers
Monomers are linked together via covalent bonds into polymers
Dehydration synthesis
Two molecules of glucose are linked to form the disaccharide maltose

A water molecule is formed as the two monosaccharides are linked by a covalent
bond
Hydrolysis
Process of breaking polymers down into individual monomers, AKA dehydration
reaction
Water serves as a reactant; one monomer receives a H+ and the other monomer
receives an OH-
Enzymes
Are biological molecules that catalyze or “speed up” reactions
Chemical reactions involving macromolecules are catalyzed by enzymes
Enzymes speed up hydrolysis and dehydration reactions
Dehydration reactions form new bonds/require energy
Hydrolysis reactions break bonds/release energy
Specific enzymes exist for each macromolecule class
Carbohydrates- broken down by amylase, sucrose, lactase, maltase
 Lipids - broken down by lipases
Proteins - broken down by pepsin and peptidase

Carbohydrates
Found in grains, fruits, and vegetables
Provide energy to body in form of glucose
Represented by the general formula (CH2O)n
Ratio of Carbon: Hydrogen: Oxygen is 1:2:1
Has 2 main subtypes:
1. Monosaccharides
2. Disaccharides
3. Polysaccharides
Monosaccharides
Usually have 3-7 carbons
End with the suffix -ose
Contains a carbonyl group C=O
Aldoses: carbonyl group at the end of the carbon chain
Ketoses: carbonyl group in the middle of the carbon chain
Trioses: three carbons
Pentoses: five carbons
Hexoses: six carbons
Three structural isomers of a hexose monosaccharide
Structural isomers/formula (C6H12O6)
1. Glucose - important source of energy
2. Galactose - part of lactose/milk sugar
3. Fructose - part of sucrose/fruit
Monosaccharides exist as linear chain or ring-shaped molecules
 o Five- and six-carbon monosaccharides exist in equilibrium between linear
and ring forms
o Ring forms and the side chains closes and is locked into an alpha or beta
position
o Fructose and ribose also form rings
o They form five-member end rings as opposed to the six-membered ring of
glucose
Disaccharides
Form when two monosaccharides are linked in a dehydration reaction
Example:
o Glucose + Fructose = sucrose (disaccharide)
o Two monomers are joined by glycosidic bond
o Water is also released
o Carbon atoms in a monosaccharide are numbered from the terminal
carbon closest to the carbonyl group
o Glycosidic linkage is formed between carbon 1 in glucose and carbon 2 in
fructose
o Results in 1,2 glycosidic linkages

Other common disaccharides
Maltose (grain sugar)
Lactose (milk sugar)
Sucrose (table sugar)
All are created via formation of covalent glycosidic linkages
Polysaccharides
Long chain of monosaccharides joined by glycosidic linkages
May be branched or unbranched
May consist of multiple layers of monosaccharides
Molecular weight could be >10,000 Daltons
Polysaccharides can be distinguished by their glycosidic linkages
Starch is composed of Amylose and Amylopectin
The monomers are joined in two linkage types:
 1. α 1-4 glycosidic bonds
2. α 1-6 glycosidic bonds
Amylose = unbranched glucose monomers in α 1-4 glycosidic bonds
Amylopectin = branched glucose monomers in α 1-4 and α 1-6 glycosidic bonds
Cellulose
A polysaccharide found in the cell wall of plants
Glucose monomers are linked in unbranched chained by β 1-4 glycosidic linkages
Every glucose monomer is flipped relative to the next one resulting in a linear,
fibrous structure
Chitin
The hard exoskeleton of arthropods is composed of the polysaccharide chitin
Contains nitrogen

Lipids
Are a diverse group of non-polar hydrocarbons
Non-polar hydrocarbons are hydrophobic

Function of Lipids
Long-term energy stores
Provides insulation from environment for plants and animals
Serve as building blocks for some hormones
Important component of cellular membranes

Types of Lipids
Fats
Oils
Waxes
Phospholipids
Steroids

Fats and oils
Fats – contain two main components
1. Glycerol
2. Fatty Acids
Triacylglycerol – formed by joining three fatty acids to a glycerol backbone
The glycerol molecules are attached to the fatty acids via an ester linkage
Three molecules of water are released in this reaction

Saturated and Unsaturated Fatty Acids
Stearic acid is a common saturated fatty acid
This means it contains no carbon-carbon double bonds in the carbon backbone
Pack tighly and exist as solids at room temperature (butter, fats in meats, etc)
May be associated with cardiovascular disease – should be limited in your diet
Oleic acid is a common unsaturated fatty acid
Contains at least one carbon-carbon double bond in carbon chain backbone
▫ Monounsaturated fat = one double bond
▫ Polyunsaturated fat = more than one double bond
Most unsaturated fats are lipids at room temperature – referred to as oils

What’s the deal with Trans-Fats?
Each double bond of an unsaturated fat may be in one of two positions
▫ Cis configuration – hydrogens are on the same side of the chain
▫ Trans configuration – hydrogens are on the opposite side of the chain
Cis-acids have a kink in the chain
▫ They cannot be packed tightly
▫ Liquid at room temperature
Trans-acids – no kink
 ▫ Can be created through processing
▫ Foods with trans-fat may increase LDL cholesterol in humans (bad for the
heart)

Essential Fatty Acids
Required but not synthesized by the body – must be part of diet
▫ Omega-3 fatty acid (found in salmon, trout, tuna)
▫ Omega-6 fatty acid
These fats are heart healthy
▫ Reduce risk of heart attack, reduce triglycerides in blood, lower blood
pressure

Waxes
Long fatty acid chains esterified to long chain alcohols
Hydrophobic and prevent water from sticking to surface
Found on the feathers of some aquatic birds and on the surface of leaves from
certain plants

Phospholipids
Molecule with two fatty acids and a modified phosphate group attached to a
glycerol backbone
The phosphate may be modified by the addition of charged or polar chemical
groups
Two common chemical groups that attach to phosphate are choline and serine

Phospholipids are major constituents of the plasma membrane
The hydrophilic head groups of the phospholipids face the aqueous solution
The hydrophobic tails are sequestered in the middle of the bilayer
Phospholipids contribute to the dynamic nature of plasma membrane

Steroids
Have a closed ring structure
▫ Four linked carbon rings
▫ Many have a short tail
Structure is different from that of other lipids
They are hydrophobic
They are insoluble in water
Cholesterol is the most common steroid
▫ Synthesized in liver
▫ Precursor to other hormones such as testosterone and estradiol
▫ Precursor to vitamin D
▫ Precursor to bile salts
09/26/24
Lecture 9: Macromolecules II
Proteins
Most abundant organic molecule
Has a diverse range of functions
o Regulatory functions
o Structural functions
o Protective functions
o Transport
o Enzymes
o Toxins

Enzymes
catalysts in biochemical reactions
Specific enzyme for specific substrate
Types of enzymes
Catabolic - breakdown substrate
Anabolic - build more complex molecules
Catalytic - affect the rate of reaction

Types of proteins
Digestive enzyme
 Example: amylase, lipase, pepsin, trypsin
 Function: helps in digestion of food by catabolizing nutrients into
monomer if units
Transport
 Examples: hemoglobin, albumin
 Function: carries substances in the blood or lymph throughout the
body
Structural
 Examples: actin, tubulin, keratin
 Function: construct different structures, like the cytoskeleton
Hormones
 Examples: insulin, thyroxine
 Function: coordinate the activity of different body systems
Defense
 Example: immunoglobulins
 Function: protect the body from foreign pathogens
Contractile
 Examples: actin, myosin
 Function: effect muscle contraction
Storage
 Examples: legume storage proteins, egg white (albumin)
 Function: provides nourishment in early development of the embryo
and the seedling

Amino Acids
Are the monomers that make up proteins
Fundamental structure:
Central carbon atom (α-carbon)
 Amino group (-NH2)
Carboxyl group (-COOH)
Hydrogen
Side chain (R-group)

Amino acids have Diverse Chemical Properties
20 common amino acids commonly found in proteins
Each amino acid has a different R group (variant group)
R-groups determine the chemical nature of each amino acid
o Non-polar aliphatic
o Polar
o Positively charged
o Negatively charged
o Non-polar aromatic

More on Amino Acids
Amino acids are represented by a single upper-case letter or three letters
o Valine = V or Val
o Aspartic Acid = D or Asp

Essential amino acids
the following must be supplied in diet for humans
o Isoleucine
o Leucine
o Cysteine

The sequence and number of amino acids determine the proteins shape, size and
function

Peptide Bond Formation
Amino acid monomers are linked via a peptide bond formation (dehydration
synthesis reaction)
Carboxyl group of one amino acid is linked to the amino group of the incoming
amino acid
A molecule of after is released as a part of the reaction

What’s the Difference between Polypeptides and Proteins?
Polypeptide - a chain of amino acids joined together in peptide linkages
Protein - a polypeptide or multiple polypeptides
o Often combined with non-peptide prosthetic groups
o Has a unique structure and function
o Many proteins are modified following translation (process of creating a
new protein)

The Shape of Proteins is Crucial to their Function
Protein shape is based upon four levels of structure
1. Primary structure
2. Secondary structure
3. Tertiary structure
4. Quatenary structure

Primary Protein Structure
The unique sequence of amino acids in a polypeptide
Protein function could be compromised if alterations in the order of amino acids
was to be made
Amino acid sequence is based upon gene encoding that protein
A change in the nucleotide sequence of DNA could lead to a change in amino
acid
This could lead to a change in protein structure and function

Sickle cell anemia - How a Change in One Amino Acid can Impact Human Health
Normal hemoglobin - amino acids at position seven is glutamic acid
Sickle cell hemoglobin - glutamic acid is replaced by a valine

The result of a single amino acid changes out of 600 amino acids that code for
human hemoglobin
Sickle cells are crescent shaped, while normal cells are disc-shaped

Secondary Protein Structure
Local folding of the polypeptide
1. α- helix – formed by hydrogen bonding between oxygen in carbonyl group
and an amino acid 4 positions down the chain
2. β-pleated sheet - hydrogen bonding between atoms on the backbone of
the polypeptide chain
Certain amino acids tend to form an α- helix
Others favor formation of β-pleated sheet

Tertiary Structure
The unique three-dimensional structure of a polypeptide
Due to chemical interactions between R-groups on amino acids
Ex. 1 – R-groups with like charges are repelled from one another
Ex. 2 – R-groups that are hydrophobic will cluster in interior of protein
Ex. 3 – cysteine side chains form disulfide bridges
Examples of Tertiary Structures
Hydrophobic interactions
Ionic bonding
Hydrogen bonding
Disulfide linkages

Quaternary Protein Structure
Interactions between several polypeptides that make up a protein
Weak interactions between subunits help stabilize the structure

Denaturation and Protein Folding
Protein structure and shape can be chnaged if chemical interactions are broken
Protein structure/shape can change with altering primary structure due to:
o Changes in pH
o Changes in temperature
Denaturation – changes in protein structure that leads to changes in the function
Example: heating an egg to extreme temperatures can lead to irreversible
denaturation of egg protein (albumin in egg goes from liquid to solid)

Nucleic Acids
Constitute the genetic material of livig organisms
Two types of nucleic acid:
1. Deoxyribonucleic acid (DNA)
2. Ribonucleic acid (RNA)
Location of nucleic acids
Nucleus of eukaryotic cells
Mitochondria
Chloroplasts
Prokaryotic cells (not membrane enclosed)

Role of DNA in the Cell
DNA codes for the genome of cell – entire genetic content
Chromatin – complex of DNA and histone proteins
Chromosomes – threadlike structures containing tightly wound and packed
chromatin
DNA codes for thousands of genes
Genes contain instructions for prodcuing proteins or various forms of RNA
 DNA controls all cellular activities by turning genes on or off

Role of RNA in the Cell
RNA is primarily involved in protein synthesis
Types of RNA
1. Messenger RNA (mRNA) - intermediary nucleic acid that leaves the nuclues
and contains blueprint for protein synthesis
2. Transfer RNA (tRNA) - serves as a bridge between nucleotides and amino
acids (translation)
3. Ribosomal RNA (rRNA) - assists in protein synthesis

Monomers of Nucleic Acids
DNA and RNA consist of monomers know as nucleotides
Nucleotides consist of three parts:
1. Nitrogenous base
2. Pentose sugar
3. One or more phosphate groups
Types of Nitrogenous Bases
Pyrimidine – cytosine, thymine, uracil
Purines – adenine, guanine
Types of Pentose Sugars
Deoxyribose (found in DNA)
Ribose (found in RNA)

DNA exhibits a Double Helix Structure
The sugar and phosphate lie on the outside of the helix
Nitrogenous bases are stacked in the interior
The strands of the helix run in opposite directions (antiparallel orientation)
Each base from one strand interacts via hydrogen bonding with a base from the
opposing strand
Base-pairing in DNA
The two strands run antiparallel to one another
One strand runs 5’ to 3’
The other 3’ to 5’
Adenine forms hydrogen bonds with thymine (A-T)
Guanine base pair with cytosine (G-C)

The DNA Code can be Written (Transcribed) into RNA
DNA can express a particular gene by synthesizing RNA via the process of
transcription
RNA base sequence is complementary to DNA sequence but in RNA the base
uracil is used in place of thymine
Example of transcription: if DNA sequence is AATTGCGC then mRNA complement
is UUAACGCG

RNA and the Production of Proteins
Various forms of RNA play important roles in protein translation
Ribosomes are made up of proteins and rRNA – the
mRNA transcript binds with ribosomes and the rRNA has catalytic activity
The bases of the mRNA are read in sets of three bases
(codons)
The tRNA base pairs with the codon and delivers the
correct amino acid
Peptide linkages are made at the ribosome—polypeptide continues to
grow

Protein Translation Overview
Ribosome has two parts: a large subunit and a small subunit
1. The mRNA sits in between the two subunits
2. A tRNA molecule recognizes a codon on the mRNA
3. binds to it by complementary base pairing
 4. adds the correct amino acid to the growing peptide chain

Lecture 10: Cells

Cells
Are the building blocks of all organisms
In a single-celled organism, the cell is everything
Size varies, most are too small to be seen by the naked eye
Microscopes make small cells easier to see

Multicellular Organisms are Organized in a Hierarchy
Cells are the basic unit
Tissues are composed of interconnected cells with a common function
Several tissues combine to form an organ
Organs working together make up an organ system
Multiple systems that function together form the entire organism

The Two Parameters Most Important in Microscopy
Magnification and Resolving Power

Magnification
The process of enlarging an object in appearance

Resolution
The ability of a microscope is to distinguish two adjacent structures as separate:
The higher the resolution, the better the clarity and detail of the image

Microscopes with Different Optical Systems Produce Images for Different Studies
 Compound light microscopes bend visible light to provide magnification
Transparent objects (like cells) must be treated with chemical stains to
distinguish different parts

Electron Microscopes
Achieve higher magnification and resolution using beams of electrons
Transmission electron microscopes can show fine detail within cells
Scanning electron microscopes provide 3-D exterior views

Cell Theory
An underlying principle of biology
Cells are basic units of life
All living organisms are made of cells
All cells come from preexisting cells

Cells have 4 Common Components
1. An enclosing plasma membrane which separates the cell’s interior from
the environment
2. Cytoplasm made of cytoskeleton in which other components of the cell are
found
3. DNA - the genetic material of the cell
4. Ribosomes which synthesize proteins

Characteristics of Prokaryotes
Lack membrane-enclosed internal compartments (e.g. nucleus)
Most have a cell wall containing peptidoglycan
Are believed to be much like the first cells
Organisms in the domains Archaea and Bacteria are Prokaryotes

Generalized Structure of a Prokaryotic Cell
Chromosomal DNA is localized in a nucleoid
Ribosomes are in the cytoplasm
The cell membrane is surrounded by a cell wall

Prokaryotic Cells are Smaller than Eukaryotic Cells
Reasons for small side of prokaryotic cells:
Surface area to volume ratio is more favorable for moving material in and out of
the cell
They lack modifications found in eukaryotes that aid internal transport

Factors Limiting Cell Size
Surface area -to- volume ratio
As cells get bigger, volume increases faster than surface area

10/10/24
Lecture 11: The Eukaryotic Cell

Eukaryotic Plasma Membrane
Phospholipid bilayer with embedded proteins

Cytoplasm
Region between the plasma membrane and the nuclear envelope
This consist of organelles suspended in gel-like cytoskeleton plus the
cytoskeleton
70-80%of the cytoplasm is water but it has semi-solid consistency due to
proteins within it
Nucleus
Usually only one per cell
Usually the largest organelle
Bigger itself than most prokaryotic cells

Nuclear Envelope
This is a double membrane
Separates DNA from cytoplasm
Separates transcription from translation
Nuclear pores perforate this membrane
Connect nucleoplasm to cytoplasm
Regulate flow of molecules back and forth
Large molecules require nuclear localization signal (NLS) to pass

Nucleolus
This is a region inside the nucleus where ribosomes are assembled from RNA and
proteins

Ribosomes
Made of two different-sized subunits
Slightly larger in eukaryotes
Made of special RNA (rRNA) and proteins
During protein synthesis, ribosomes assemble amino acids into proteins

Mitochondrion
Site for conversion of stored energy (macromolecule molecular bonds) to more
useful form (ATP)
Inner membrane is folded
Folds are called cristae
Area enclosed is the mitochondrial matrix

Peroxisomes
Reactions that break down fatty acids and amino acids occur here
May detoxify poisons

Contrasting Animal and Plant Cells
Both have microtubule organizing centers (MTOCs), but animal cells also have
centrioles associated with the MTOC
This complex is called the centrosome
Animal cells each have a centrosome and lysosomes, but plant cells do not
Plant cells have a cell wall, chloroplasts and other specialized plastids and a large
central vacuole - animal cells do not

Animal Cells Include:
Intermediate filament, ribosomes, rough endoplasmic reticulum, nucleus,
nucleolus, chromatin, Golgi apparatus, Golgi vesicle, cytoplasm, vacuole,
peroxisome, secretory vesicle, smooth endoplasmic reticulum, lysosomes,
microfilament, centrosomes, microtubule, plasma membrane, mitochondria

Plant Cell Include:
Plasmodesmata, cell wall, plasma membrane, cytoplasm, central vacuole,
cytoskeleton, chloroplast, plastid, peroxisome, Golgi apparatus, mitochondria,
ribosomes, nucleus, rough and smooth endoplasmic reticulum

Centrosome
Consist of two centrioles that lie at right angles to each other
Each centriole is a cylinder made up of nine triplets of microtubules
Nontubulin proteins hold the microtubule triplets together

Plant Cell Walls
Is a rigid protective structure external to the plasma membrane
Plant cell walls differ from prokaryotes because they are made up of cellulose
rather than peptidoglycan

Chloroplasts
Are double-membrane organelles; have their own ribosomes and DNA like
mitochondria
The inner membrane encloses an aqueous fluid (stroma) that contains a set of
interconnected and stacked fluid-filled membrane sacs called thylakoids
Each stack of thylakoids is a granular (plural = grana)

The Central Vacuole
Plant cells have a large vacuole that occupies most of the area of the cell
This central vacuole helps regulate water concentration under changing
environmental conditions, and contributes to cell expansion

The Endomembrane System
Consists of internal membranes and organelles in eukaryotic cells that work
together to modify, package, and transport lipids and proteins
Includes: nuclear envelope, lysosomes, vesicles, endoplasmic reticulum, Golgi
apparatus and the plasma membrane.

Lysosomes
In animal cells
Contain digestive enzymes
These breakdown large biomolecules and even out organelles

Endoplasmic Reticulum (ER)
Interconnected membranous sacs and tubules
Modifies proteins (Rough ER) and synthesizes lipids (Smooth ER)

Rough Endoplasmic Reticulum
Ribosomes attached to the cytoplasmic surface manufacture proteins
New proteins are modified (by folding or obtaining side chains) in the lumen of
the RER
Makes phospholipids for cellular membranes
Phospholipids or modified proteins are not destined to stay in the RER, they
reach their destinations via transport vesicles

Smooth Endoplasmic Reticulum
Is continuous
Has few or no ribosomes on its surface

Functions of SER
Synthesis of carbohydrates, lipids, and steroid hormones
Detoxification of medications and poisons
Storage of Ca++

Golgi Apparatus
Lipids and proteins get sorted, packaged and tagged, while within transport
vesicles, to get to the right place
The receiving side of the apparatus is called the CIS face; the opposite side is the
TRANS face
Transport vesicles from the ER fuse with the CIS face and empty their contents
into the lumen of the golgi apparatus
As the proteins and lipids travel through the Golgi, they are further modified so
they can be sorted (this involved adding short chaining of sugar molecules)

Cytoskeleton
A network of protein fibers
Has serval functions:
Helps maintain the shape of the cell
Hold some organelles in specific positions
Allows movement of cytoplasm and vesicles within the cell

Three Components of Cytoskeleton
Microfilaments
Intermediate filaments
Microtubules
Each are different sizes and have different functions

Microfilament
Narrowest of the three types (movement and structure)
Involved in movement (has no role in cell movement, just structure)
Determine and stabilizes shape (movement and structure)
Made from actin monomers

Microtubules
Widest component of the three
Provide framework for moto proteins to move structures within a cell
Made of tubulin dimers

Cilia and Flagella
Cilia is shorter and more numerous than Flagella

Extracellular Structures
Plant cell wall:
Support
Barrier to infection
Plasmodesmata connected cells
Extracellular matrix in animals (3 components):
Collagens and fibrous proteins
Glycoproteins
Linking proteins

Intercellular Junctions
Provide direct channels of communication between cells
Plants and animals do this differently

Plasmodesmata
Channels that pass between cell walls in plants to connect cytoplasm and allow
materials to move from cell to cell

Gap Junctions Connect Animal Cells
Form channels that allow ions, nutrients, and other materials to move between
cells
Develop when 6 proteins form an elongated doughnut-like structure in the
plasma membrane

Lecture 12: Membranes and Transport

Plasma Membrane Functions
Defining the outer border of all cells and organelles
Managing what enters and exits the cell
Receiving eternal signals and initiating cellular responses

Fluid Mosaic Model
A mosaic of components (phospholipids, cholesterol, proteins, and
carbohydrates) that give the membrane a fluid character

Phospholipids
2 fatty acid chains (non-polar)– hydrophobic tails
A glycerol molecule, a phosphate group (polar) - hydrophilic head
Each fatty acid can either be saturated or unsaturated:
Carbons are saturated (maximum amount of hydrogen) with H- all single C-C
bonds
Unsaturated is when at least one double C=C bond occurs

Phospholipid Bilayer
Arrange themselves in a bilayer
Polar head face outward
Hydrophobic tails face inward
Proteins
The second major component of membrane
Functions as transporters, receptors, enzymes, or in binding and adhesion
Integral proteins – integrated completely into the bilayer
Peripheral proteins – occur only on the surfaces

Integral Proteins
Has one or more regions that are hydrophobic and others that are hydrophilic
The location and number of regions determine how they arrange within the
bilayer

Carbohydrates
Located on the exterior surface of the plasma membrane, bound to either
proteins (forming glycoproteins (sugar + protein)) or to lipids (forming
glycolipids (sugar + lipid))

Receptor Proteins
Our immune systems T cells have CD4 receptor glycoproteins that recognize HIV
as “self”

Membrane Fluidity
The membrane needs to be flexible but not so fluid that it cannot maintain its
structure
Fluidity is affected by:
Phospholipid type - phospholipids with saturated fatty acids can pack together
more closely than theses with unsaturated fatty acids (therefore, more SFA, more
rigid, less fluidity)
Temperature - cold temperatures compress molecules making membranes more
rigid
Cholesterol - acts as a fluidity buffer, keeping membranes fluid when cold and
from not getting too fluid when hot.

Plasma Membranes
Are asymmetric
The inner surface differs from the outer surface
For example:
Interior proteins anchor fibers of the cytoskeleton to the membrane
Exterior proteins bind to the extracellular matrix (outside of the cell)
glycoproteins bind to substances the cell needs to import

Transport
The plasma membrane is selectively permeable (allows some molecules to pass
through, but not others)
This allows cytosol solutions (inside the cell) to differ from extracellular fluids
Transport acrross a membrane can be either:
Passive - requiring no energy
Active - requiring energy (ATP)

Passive Transport
The simplest type of passive transport is diffusion
Diffusion: occurs when a substance from an area of high concentration moves
down its concentration gradient
Only small non-polar molecules (O2, CO2, lipid hormones) can diffuse through
biological membranes

Factors That Affect Diffusion Rates
Concentration gradients - greater difference, faster diffusion
Mass of the molecules - smaller molecules diffuse more quickly
Temperature - molecules move faster (more fluid) when temperatures are higher
Solvent density - dehydration increases density of cytoplasm which reduces
diffusion rates
Solubility - more non-polar (lipid-soluble) materials, diffuse faster
Surface area - increase surface area speeds up diffusion rates
Distance traveled - the greater the distance, the slower the rates; important
factor of affecting upper limit of cell size
Pressure - in some cells (i.e. kidney cells) blood pressure forces solutions through
membranes speeding up diffusion rates

Facilitated Passive Transport
Facilitated transport, a.k.a. facilitated diffusion, moves substances down their
concentration gradient through transmembrane, integral membrane proteins
Two types of facilitated transport proteins:
Channel proteins
Carrier proteins

Channel Proteins
The top, bottom, and inner core are composed of hydrophilic amino acids -
attract ions &/or polar molecules
Some are open all the time
Others are gated, only opening when a signal is received
Important examples:
Aquaporins - specific to H2O
Muscle cells have gated ion channels allowing muscle contraction when opened

Carrier Proteins
Are specific to a single substance
They bind to that substance, change shape, and “carry it” to the other side
Many allow movement in either direction, as concentration gradients change

Osmosis
The diffusion of water across the membrane
Water always moves from an are of higher water concentration to lower water
concentration
Differences in water concentration occur when a solute cannot pass through the
selectively permeable membrane

Osmolarity
Describes the total solute concentration (salt, sugar, etc)
Low osmolarity - less solute, more water
Hypotonic: extracellular fluid has lower osmolarity (less solute, more water
outside the cell) then the cytosol - water enters the cell
Isotonic: extracellular fluid has the same osmolarity (equal solute and water in
and outside of the cell) than the cytosol - water does not move
Hypertonic: extracellular fluid has higher osmolarity (high solute, less water
outside the cell) than the cytosol - water leaves the cell

Active transport
Used anytime an ion or molecule (like glucose) is transported through a
membrane protein
Against its concentration gradient (from low to high concentration) or against its
electrochemical gradient
Energy is always required for active transport
Two types of active transport
Primary - where ATP provides the energy
Secondary - where an electrochemical gradient provides the energy

Occurs through transmembrane, integral carrier proteins called pumps
There are 3 types of pumps:
Uniporter: carries one molecule or ion
Symporter: carries two different molecules or ions, in the same direction
Antiporter: carries two different molecules or ions, in different directions

Electrochemical Gradient
Arise from the combined effects concentration gradients and electrical gradients

Primary Active Transport
Moves an ion or molecule up its concentration gradient, using energy from ATP
hydrolysis

Secondary Active Transport
Uses an electro chemical gradient, created by primary active transport to move a
different substance against its concentration gradient

Bulk Transport
Sometimes cells need to import or export molecules/particles that are too large
to pass through a transport protein
Is a type of active transport
Energy is required
Importing by bulk transport is called endocytosis (into the cell)
Exporting is called exocytosis (outside of the cell)
There are two types of endocytosis:
Phagocytosis - (cellular eating), the cell membrane surrounds a particle and
engulfs it
Pinocytosis - (cellular drinking), the cell membrane invaginates, surrounds a
small volume of fluid, and pinches off
Exocytosis
Vesicles containing substances fuse with the plasma membrane
The contents are then released to the exterior of the cell