Kategoriak: All - eukaryotes - monomers - transcription

arabera Marck Martinez 9 days ago

165

56

Gene regulation in eukaryotic cells involves multiple processes to regulate and control the transcription of genes. This regulation is essential for conserving energy and resources within the cell.

56

Activated GPCR

Once the signal attaches to GPCR then it gets activated and the GDP attaches.

Prokaryotic: Gene Regulation

An operon is a transcription unit of genes whose products are required under identical circumstances. it facilitates the coordinated expression of multiple genes.


The DNA sequence of an operon comprises three different components.

Structural Genes

The three genes can be transcribed together as polygenic mRNA.

Lac A
Transacetylase

Protein is essential to lactose metabolism.

Lac Y
Permease

Protein is essential to lactose metabolism.

Permease forms pores in the bacterial cell membrane

Lac Z
Beta - Galactosidase

Protein is essential to lactose metabolism.

This enzyme breaks down lactose to simple sugar residues that can then be used

Operator

The operator is a part of the DNA where a repressor can bind to, controlling access to the promoter

If a repressor is bound to the operator, blocks RNA polymerase and no mRNA can be made.

Lactose Present?
Lactose Absent

In the absence of lactose, a repressor protein is bound to the lac operator. This binding prevents transcription of the downstream lac genes.

Lac I

The repressor protein is encoded by the regulatory gene Lac I. Lac I is located upstream.

Repressor bound to operator

Operon is OFF (Basil expression)

Lactose Present

When lactose is present, lactose binds in the form of allolactose to the permanently expressed repressor protein. This binding inactivates the repressor, unblocking the operator. Now the RNA polymerase can bind to the promoter and read the genes.

Repressor Bound to Lactose

Glucose Present?

Glucose Present

In the presence of glucose, lactose degradation is possible but not essential for survival

Glucose presence inhibits cAMP production, reducing CAP binding and transcription.

Adenylyl Cyclase Inactive

cAMP levels Low

CAP inactive

Operon is OFF

Lac repressor protein binds tightly to the operator and prevents transcription of the lac genes by blocking RNA polymerase from binding to the promoter

Glucose Absent

Cell will use lactose as energy source, makes allolactose, binds to and inhibits to the repressor and triggers the expression of the lac gene.

Adenylyl Cyclase Active

cAMP levels High

cAMP then binds to CAP

CAP Active

cAMP and CAP complex forms a dimer that binds to the DNA close to the lac promoter and increases RNA polymerase activity

Operon is ON

Promoter

a promoter is a sequence of DNA where RNA polymerase can bind to initiate transcription

poly-a tail

many adenines at the 3' end of the mRNA that serve to help with transportation of the mRNA

g-cap

guanine at the 5' end of an mRNA serving to let the mRNA out of the nucleus and attach to a ribosome

Eukaryotic Gene regulation

Chromatin modification

Eukaryotic Gene Regulation tries to prevent the formation in transcription phase as it is attempting to conserve energy and save its resources

Transcription factors attach to the TATA box, they assist RNA polymerase 2 to initiate transcription. There are two typed, General and Specific.

Specific

Change the level of transcription.

Distal control elements

Enhancers

Activators/ Repressors bind specific transcription factors

Upstream or Downstream of the Gene

Activation of enhancers

Activator proteins

Bind to the distal control elements grouped as enhancers in DNA contains 3 binding sites

DNA bending protein

DNA bending protein bends the activator close to the promoter


Then General transcription factors, mediators and RNA polymerase are attracted.

Transcription Initiation complex

The activators bind to the mediator protein and general transcription factors and RNA synthesis occurs.

Repressors

If high levels of transcription, then they reduce levels.

Activators

increase levels of transcription.

General

Bring about Low levels of transcription

(Background/Basal)

Proximal control element

Sequences in DNA close to the promoter

Bind general transcription factors.

RNA processing

Transport to cytoplasm

Translation

Protein processing

Transport to cellular Respiration

Prokaryotic transcription

differences include lack of post-transcription modification and the things it brings with it (splicing, g-cap, poly-a tail), coupling of transcription and translation, and the setting of the process (cytoplasm for prokaryotes)

Eukaryotic transcription

Eukaryotic transcription uses DNA polymerase 2

it occurs in the nucleus and it has the addition of the 5 guanine cap and the Poly A tail. Its first product is also pre-mRNA.

Transcription

the process of DNA making an mRNA strand; takes place in the nucleus of a eukaryotic cell and the cytoplasm of a prokaryotic cell

terminator sequence

a DNA sequence that calls for the end of transcription and the separation of the DNA and RNA Polymerase II

pre-mRNA

the final product of transcription for eukaryotes

exons

pieces of the pre-mRNA that are kept and are actually used for translation in the specific cell

introns

pieces of the pre-mRNA that are removed if not used, depending on what gene needs to be translated

post-transcription modification

only happens in eukaryotes; the process after transcription that modifies the pre-mRNA

splicesome

a complex serving to remove introns from pre-mRNA

the final product of prokaryote transcription and post-transcription modification in eukaryotes; serves to code for a protein using a ribosome

Promoter Sequence

DNA sequence that dictates where RNA polymerase will bind and start transcription

RNA polymerase II

an enzyme that transcribes DNA and forms an mRNA by adding ribonucleotides to the 3' end of its strand

Transcription factors

proteins that regulate the rate of transcription by binding to DNA

Animal cells

eukaryotes are multicellular and are more complex organisms


ECM

Fibronectin, peptiglycan and collagen

provide structure for animal cells.

Microfilaments

Actin

maintains cell shape, cell motility and cell division

Vesicles walking on microtubes


Intermidiete filament

Proteins in the kreatin family

maintains cell shape , anchorage of the nucleus formation of lamina

FunFunctionsFunFunctions: maintain cell shape, anchorage of nucleus and certain other



organelles, and formation of nuclear lamina



Functions: maintain cell shape, anchorage of nucleus and certain other



organelles, and formation of nuclear lamina



ctions: maintain cell shape, anchorage of nucleus and certain other



organelles, and formation of nuclear lamina




Microtubules

alpha and beta Tubulin

Cell shape, cell motility, chromosome movements in cell division



Desmosomes

some things can pass between cell

Gap junctions

everything can pass between cell

Tight junction

Nothing can pass between cell

mitochondria

This doubble membrane structure is the site where cellular respiration occurs

Eukaryotic

Peroxisomes

Utilizes hydrogen peroxide as a biproduct

to break down molecules and creates water

Nucleus

All DNA is organized in this structure. Site of transcription

Nuclear envelope

A double membrane structure

regulates transport


ER

When a protein enters the endomembrane system, polypeptide synthesis resumes, with the polypeptide being inserted into the ER lumen.

Rough ER

Has bound ribosomes. site of synthesis fro glycoproteins.

Smooth Er

attached in the nucleus

synthesizes lipids

metabolizes carbs

and is used in detoxifying drugs/ poison

Vacules

Large membrane-bound organelles are used for storage of food, water, and ions.

Lysosomes

packed with enzymes needed to break covalent bonds

has low PH

breaks down molecules to smaller parts

Proteins that are destined to go to the lysosomes are tagged with specific tags, they then function

Golgi apartaus

The cis face of this structure takes in molecules from the ER to further fold and change molecules to the intended final structure that leaves from the trans face.

Plant cells

Central Vacule

Cite of storage

Cell wall

Plasmodesmata

Found in plant cells.

Allows water nad nutrients to travel from one cell to another.

Chloroplast

The double membrane structure holds the site of photosynthesis (thylakoid membrane)


Pili

attactchmnet to surfaces and bacteria mating

Passive transport

Does not require energy and goes down its concentration gradient.

Ion channels

Voltage gated

Open and close in response to membrane potential

Ligand gated

Open and close when a neurotransmitter binds to a channel

Stretch Gated

Open when membrane is mechanically deforemed

Facitated diffusion

Aided by proteins helps non polar or large molecules

Carrier protein

carrier proteins binds molecules and carries them out

Channel protein

Can easily flow through always open

Active transport

Requires energy, goes against its concentration gradient

Membrane potential

Action potential

Signal transmission

Undershoot

Both gates of Na close but the activation gates on some K+ channels are still open. Then returns to resting membrane potential

Falling phase

The inactivation gates on most Na+ channels close blocking the Na+ influx. The activation gates on most K+ channels opens permitting K+ efflux which again makes inside of the cell negative.

Rising phase

Depolarization opens the activation gates on most Na+ channels while the K+ channel's activation gates remain closed. Na + influx makes the inside of the membrane positive concerning the outside

Depolarization

A stimulus Opens the activation gates on some Na+ channels Na+. Na+ influx through those channels depolarizes the membrane. If it reaches the threshold. it triggers action potential.

Resting State

The activation gates on the Na+ and K+ channels are closed and the membrane resting potential is maintained.

Equillibrium potential

when two forces are balanced



Sodium potassium pump

uses ATP to power the transport

Proton pump

membrane fluidity

When the membrane is under hot temperatures, it becomes more fluid, this occurs with unsaturated fats.

Low permeability

Low permeability is when molecules have a difficult time passing through the membrane.

LARGE AND POLAR CANNOT PASS MEMBRANE

High permeability

High permeability is when they can easily pass through the plasma membrane.

This is when molecules are small and non polar

Cell Energy

This energy is primarily produced through cellular respiration, where glucose and oxygen are converted into ATP, the main energy currency of the cell.

types of energy

potential energy

Potential energy is the stored energy in a system.

chemical energy

Chemical energy refers to the energy stored in the bonds of molecules, such as glucose, which can be released during cellular processes like respiration.

kinetic energy

Kinetic energy is the energy of motion, which in biological systems is seen in processes like the movement of muscles or the flow of molecules across cell membranes.

fermentation

Fermentation is a metabolic process in which cells convert sugars into energy in the absence of oxygen

energy flow

consumers

Consumers are organisms that obtain energy by eating producers or other consumers

producers

Producers are organisms that can produce their own energy

decomposers

Decomposers are organisms that breakdown dead organic matter

Thermodynamics

Thermodynamics refers to the study of energy flow and transformations within living systems

Metabolism

Metabolism refers to the life sustaining chemical reactions in organisms that convert food into energy and build or breakdown molecules for growth, repair, and maintenance.

Photosynthesis

Photosynthesis harnesses light energy. There are two stages of photosynthesis. Stage one involves Light reactions and stage 2 involves the Calvin cycle. Photosynthesis is summarized as electrons are extracted from water and transferred to CO2. H2O is oxidized and CO2 is reduced.


photosynthesis is important to life on earth because it provides energy to plants that gives energy to those who eat them

Light independent reactions
Calvin Cycle

The calvin cycle is stage 2 of photosynthesis and occurs in the stroma of the chloroplast.

The Calvin cycle produces sugar from CO2 with the help of the NADPH and ATP produced by the light reactions.


Inputs of the calvin cycle are CO2, 6 NADPH, and 6 ATP

Outputs of the calvin cycle are 9 ADP, 6 NADP+, and 1 G3P

Carbon Fixation

Carbon Fixation is the first step of the calvin cycle.

It involves the addition of CO2 from atmosphere to Ribulose Bisphosphate (carbon acceptor) using the enzyme Rubisco (adds carbon from atmosphere.


This forms a 6 carbon unstable intermediate.

Immediately splits to form 2 molecules of 3 carbon ( also called 3 phosphoglycerate).


To form 1 molecule of glucose (6C) we need 6 CO2 to be fixed. 12 NADPH and 19 ATP.



G3P

The product of the calvin cycle is G3P (a sugar)

Stroma
Light Reactions

Light reactions occur in the thylakoid membrane in chloroplast.

Light reactions convert solar energy into chemical energy. H2O is split to provide electrons and protons.

Light energy excites the electrons to a higher energy level in Photosystem II which are then transferred to Photosystem I and in the process reduce NADP+ to NADPH for the Calvin cycle.


In the process of the noncyclic flow of electrons in the photosystems, ATP is made from the ETC.


Inputs of the light reaction cycle: H2O, ADP, NADP+ and Light

Outputs of the light reaction cycle: O2, ATP, and NADPH

Photosystem II

Reaction center chlorophyll a absorbs at 680nm hence called p680

Splits H2O, releasing O2 and generates some ATP

Photosystem I

reaction center chlorophyll a absorbs at 700nm hence called P700

reduces NADP+ to NADPH

NADPH

Local Signaling

Cells that releases signals are near the cells that receive the signals.

Synaptic signaling

Paracrine signaling

Long Distance

Uses a target Cell and usually flows through blood vessels

Hormonal signaling

Signal travels through bloodstream.

Physical Contact

Cell Communication

Receptors

Present in a target cell that receives the signal molecule.

Intracellular receptor

A non-polar signal can diffuse directly across the lipid bilayer.

Hormone (aldesterone)

Through the steroid hormone aldosterone passes through the plasma membrane

Hormone receptor complex

Aldosterone binds to a receptor protein in the cytoplasm activating it.

Enters the nucleus

The hormone receptor complex enters the nucleus and binds to specific genes.

Transcription Factor

The bound protein acts as a transcription factor, stimulating the transcription of the gene into mRNA

translated

the mRNA is translated into a specific protein.

rmembrane receptor

The signal molecule is hydrophilic, a receptor in the membrane.

G protein linked receptor

Response

Once the last kinase is activated in the cascade it enters the nucleus.

transcription factor

Then the transcription factor gets activated

DNA

Active transcription factor then binds the DNA and it stimulates transcription of a specific gene.

Transduction

Once the GDP attaches to the GPCR it then turns into GTP.

Activated Adenynly cyclase

The GTP then binds adenylyl cyclase and then it is activated. Then it releases a cellular response.

Second messengers

Adenenly cyclase turn AMP to Cyclic AMP which then bind to the first Kinase.

Phosphodiesterase turns Cyclic AMP to AMP

Phosphorylation Casade

The cyclic AMP activates the first kinase then it starts the casade, where each kinase activates a new one using the enzyme Kinases which transfers phosphate groups to activate. Then it gets unactivated when it removes a phosphate group with the enzyme phosphatase.

Reception

During reception, there is a signal molecule that attaches to the GPCR.

Cell Respiration

Electrons are transferred from NADH and FAD2 to oxygen, forming water.

Cellular respiration relies on the breakdown of glucose.

Equation:

C6H12O6 + 6O2 --> 6CO2 + 6H2O

Oxidative Phosphorylation

The last step of cellular respiration

H2O, 26~28 ATP

the overall products of oxidative phosphorylation

ATP Synthase

makes ATP from the energy of incoming protons

Chemiosomosis

Movement of protons across a selectively permeable membrane, down the electrochemical gradient. This utilizes the proton gradient created by the ETC to drive synthesis of ATP to ADP and phosphate. The protons flow back across the membrane through ATP synthase, providing the energy needed to make ADP into ATP.


Chemiosmosis in photosynthesis, the proton gradient across the thylakoid membrane generates a proton force so that the protons flow back into the stroma through ATP synthase, synthesizing ATP from ADP and phosphate.

Essential for ATP production.

ADP

the input of ATP synthase

ATP

the output of ATP synthase

In photosynthesis and more specifically the light reaction cycle, ATP is generated by adding a phosphate group to ADP in a process called photophosphorylation.

Complex 1

an electron carrier and proton pump that serves to make NAD+ through NADH

NADH

the input of complex one

NAD+

the output of complex one

Complex 2

an electron carrier and make FAD

FADH

the input of complex two

FAD

the output of complex two

Complex 4

an electron carrier as well as a proton pump and makes water from oxygen

O2

oxygen; the input of complex four

In photosynthesis and in the light reaction cycle o2 is released as a waste product.

H2O

water; the output of complex four

In photosynthesis, specifically the light reaction cycle H2O is split to ptovide electrons and Protons.

Proton Pump

pumps protons out of the matrix into the intermembranespace

Complex 3

an electron carrier

Electron transfer

The ETC generates a proton gradient across a membrane by pumping H+ from one side of the membrane to the other. Transport of electrons through reactions.

Essential for ATP production.

Inner Mitochondrial Membrane

The location of the Electron Transport Chain in cellular reparation is in the inner mitochondrial membrane.

Thylakoid Membrane

The location of the Electron Transport chain in Photosynthesis is in the thylakoid membrane of chloroplasts.

Citric Acid Cycle

the third step of cellular respiration

1 ATP, 1 FADH, 3 NADH

the overall products of the CAC

Step1:
Input: Acetyl CoA

acetyl coenzyme A; input for step one of the Citric Acid Cycle (CAC)

Output: Citrate

the product of acetyl CoA

Input: Isocitrate

the input of the third step of the CAC

Output: alpha-ketoglutarate

the output from isocitrate

Pyruvate Oxidation

The second step of cellular respiration

Input: 2 Pyruvate, 2 CoA

the inputs

Output: 2 Acetyl CoA, 2 NADH

the outputs

Glycolysis

The first step of cellular respiration

Fermentation

When there is no oxygen present, some cells go through fermentation where the only cellular respiration process done is glycolysis producing very few ATP

Outcome:
2 ATP, 2 NADH, 2 Pyruvate

the overall products of glycolysis

Step 3:
Input: fructose 6-phosphate

made by phosphoglucose isomerase

fructose 1,6 biphosphate

made from the enzyme phosphofructo kinase

Step 1:
Input: Glucose

a carbohydrate

Glucose 6-phosphate

the product of the enzyme Hexokinase

3' and 5' phosphodiester linkage

Nucleotide chains

Deoxyribose

lacks an OH group making it more stable

DNA

deoxyribonucleic acid

Chargaff's rule

Chargaff's rule states that DNA is paired with one purine and one pyrimidine. He also states that the number of A=T and G=C

Antiparallel

both strand are opposite one is 3'-5' while the other is 5'-3'

DNA Replication

This is separate from transcription and translation and requires the assistance of multiple enzymes to accomplish.

Eukaryotes

Eukaryotes have multiple origins of replication

Prokaryotes

Prokaryotes have one origin of replication

Hershey and Chase

Hershey and Chase discovered that DNA was the genetic material and not protein in their experiment with bacteriophage where they found that the DNA was entering the cell nd making copies of more bacteriophage.

Messelson and stahl

Messelson and Stahl discovered that DNA was replicated in a semiconservative manner after his experiment showed intermediate after the first replication and intermidiete and light in his second round of replication.

Griffith Experiment

Discovered that there was a genetic material but did not know what it was. This was found in his experiment with the rats where the heat killed s transformed the R to kill the rat.

Dispersive replication

This theory suggested a mixture of both parent and daughter strands. this was later disproved.

Conservative Replication

The theory suggests that DNA replicates with the assistance of a parent strand and then the parent strand reforms. This theory was later disproved.

Semiconservative replication

The Meselson and Stahl experiment Proved that DNA uses a parent strand to form the newly synthesized daughter strands. This was proven right after the experiment showed intermediate and light in their replication rounds.

Enzymes/Proteins

Primase

adds the RNA Primer, this is necessary so that DNA polymerase 3 knows where to go.

Ligase

Ligase glues the Okazaki fragments made in the lagging strand so that it makes a continuous strand.

Lagging strand

The lagging strand synthesizes away from the replication fork.

Okazaki fragments

since the lagging strand is going away from the replication fork it is made through Okazaki fragments, which are small segments of dna polymerase that are glued with ligase.

Leading strand

The leading strand synthesizes towards the replication for and it is continuous

DNA Polymerase 1

removes the RNA primer

DNA polymerase 3

DNA polymerase is responsible for adding DNA it needs The Rna primer and can only go from a 5 to 3 direction

Topoisomerase

Topoisomerase is responsible for relieving the tension from the coiled DNA strand.

SSB

The SSB is the protein that stabilizes the DNA so that it would wind again.

Helicase

Helicase is the first step it unzips the two strands of DNA it breaks the hydrogen bonds.


Origin of Replication

The origin of Replication is formed with the helicase making a bubble. The ORI then makes two replication for that are bidiretional.

Replication fork

The replication fork is bidirectional

Double Helix

There are hydrogen bonds in between the two strands of DNA

Ribose

has an OH group making it less stable

Robonucleotides

RNA

ribonucleic acid

Single stranded
rRNA

Nucleotides

Connected by phosphodiester linkage

phosphate group

Links nucleotides together with phosphodiester bonds

nitrogen containing base

has base paring A-T and G-C

The base paring for DNA is T, A, C, G

The base paring for RNA is U, A, C, G

purines

double ring structure

A G

Gunanine
adenine
pyrimidines

single ring structure

C U T

Uracil

present in RNA replaces T with U

thymine
cytosine

pentose sugar

forms the sugar-phosphate backbone of DNA and RNA

Beta-pleated sheets

Alpha-helix

Cytoplasm

Ribosomes

protein synthesis

In the end of the making the protein, the rest of the completed polypeptide leaves the ribosome.

Cytosol

Polypeptide synthesis begins on a free ribosome in the cytosol. The cytosol is the fluid part of the cytoplasm, found inside the cell but outside the organelles. It fills the space between the cell membrane and the organelles.

Signal-recognition particle

The function of the SRP is that it recognizes and binds to the signal sequence of a newly synthesized protein emerging from the ribosome. The SRP halts translation temporarily to stop the protein from being synthesized completely in the cytosol. The SRP guides the ribosome-protein complex to the ER membrane by binding the SRP receptor protein to the ER. Then the SRP leaves once at the ER.

Water

Denser as a liquid than solid

when it is solid it will float thus insulating the water underneath, this is crucial to maintain life.

Universal Solvent

Since water is polar it dissolves other polar and ionic compounds. It can also form a hydration shell around molecules such as NA and Cl. Water however cannot dissolve non polar molevcules.

Heat of VAp

The amount of heat required to change liquid water to vapor. Water has a high heat of vaporization.

Expansion upon freezing

When water freezes it expands as molecules are held together by a rigid state

High specific heat

High specific heta can help moderate temperature

Cohesion

Cohesion allows for water transport in plants and it can create high surface tension

Dehydration synthesis

Ester Links

Ester linkages connect the phospholipid by connecting the phosphate head with the two fatty acids. Triglyceride has ester links with glycerol and three fatty acids.

3 Fatty Acids

Saturated Fats

To identify a saturated fat from an unsaturated fat, look at the fatty acid chain where all the carbon bonds are single bonds (no double bonds present) which makes the carbon chain saturated with H atoms. Results in a straight, tightly packed, solid structure at room temperature.



Single Bonds
Butter

Solid at room temperature.

Unsaturated Fats

To determine if a fatty acid is unsaturated, look for a chain with at least one double bond between carbon atoms. Double bonds indicate an unsaturated fatty acid.



Double Bonds
Trans FA

Trans= opposite

Margarine

Cis FA

Cis=Same Side

Oil

A Glycerol Head

Archea

some archea live in extrem enviorments

extremophiles


Halophiles

live in high saline enviorments

Thermophiles

Thrive in very hot enviorments

translation

Translation is the process by which ribosomes use mRNA as a template to synthesize proteins. During translation tRNA molecules bring amino acids to the ribosome where they are linked together in the sequence specified by the mRNA codons forming a polypeptide chain that folds into a functional protein

prokaryotes

Translation occurs in the cytoplasm. The ribosomes directly bind to the mRNA aligning the start codon (AUG) for protein synthesis. Prokaryotic translation doesn’t involve mRNA processing or nuclear compartmentalization


Prokaryotes contain Formal MET

stages

termination

When a stop codon is reached, the ribosome releases the completed polypeptide, and the translation process ends.

elongation

The ribosome moves along the mRNA, and tRNA bring amino acid to the ribosome. The ribosome links the amino acids together to form growing polypeptide chain.

initiation

The ribosome assembles around the mRNA, and the first tRNA, carrying the starting amino acid, binds to the start codon on the mRNA.


For Eukaryotes the tRNA binds the 5 guanine cap and searches for the start codon

ribosomes

Ribosomes are cellular structures composed of RNA and proteins and they act as a side of protein synthesis


Prokaryotes have 60s ribosomes

Eukaryotes have a 70s Ribosome

tRNA

TNA is a type of RNA that helps translate genetic information from mRNA into the correct sequence of amino acids protein synthesis

mRNA

mRNA is a type of RNA that carries a genetic instructions from DNA in the cell nucleus to the ribosomes in the cytoplasm where it serves as a template for protein synthesis

eukaryotes

Translation is separated from transcription by the nuclear membrane, and mRNA undergoes modifications (capping, splicing, polyadenylation) before being translated in the cytoplasm or on the rough ER. Eukaryotic translation also involves larger ribosomes and more complex initiation mechanisms.

exons

Exons are left

Mature Mrna

Only contains exons

Introns

Intron are removed

Complex carbohydrates

Peptide bonds

Polypeptides

Formed by Dehydration synthesis

Quaternary Structure

Consists of more than one polypeptide chain, multiple chains come together to form a larger protein structure.

Tertiary Structure

Tertiary structure is the shape of the polypeptide chain and it includes secondary structures.



-Hydrophobic interactions occur between non-polar side chains

-When acidic and basic it is Ionic bonds

-Disulfide with S-S and S-H bonds (the only covalent bond)



Secondary Structure

Hydrogen bonds in between the backbones stabilize the alpha and beta sheets and helps with folding .

Primary Structure

There are covalent bonds present in the primary structure

can be a linear sequence.

Linear

Prokaryotic

Prokaryotes are single cell organisms

Flagella

helps with movement

Cell wall

gives bacteria shape and protection from lysisin dilute solutions

peptodiglycan

Capsule and slime layers

Resistance to phagocytosis adherance to surfaces

Endospore

Survival under harsh enviormental conditions

Gas vacule

Bouyancy for floating in aquatic enviorment

Plasma mebrane

selective permiable barrier

mechanical boundry of cell

nutrient and waste transport

Cell Structures and Functions

Biological Molecules

Nucleic Acids

Nucleic acids are polymers made up of small units called nucleotides.

There are two types of nucleic acids

Nucleoside

A nucleoside is a structural component of DNA and RNA comprising a 5 carbon sugar and nitrogenous base. Lacks a phosphate group


Carbohydrate

Simple Carbohydrates

Can be digested quickly.

sugars

Saccharides

Monosaccharide
Disaccharides

Polysaccharide

An entire polysaccharide is a polymer.

Cellulose

Glycogen

Starches

Amylopectin

A branched polysaccharide. Alpha (1,4) and alpha (1,6) linked.

Amylose

A linear polysaccharide linked by alpha (1,4).

Glucose

Proteins

Proteins are made of one or more polypeptide chains.

Proteins are made when the signal peptide is cleaved by signal peptidase in the receptor protein complex and the protein is now inside the ER lumen and folds into its final conformation.

Proteins are then directed to their final destination based on their sorting signals.

Secreation

Proteins that need to be secreted are packaged into secretory vesicles. The vesicles merge with the plasma membrane, releasing the protein outside the cell.

electron

A glycoprotein is a type of protein that has carbohydrate groups attached to the polypeptide chain. Glycoproteins help maintain structural integrity by stabilizing the cell membranes and supporting the ECM.

Monomers
Amino Acids

Amino Acids are linked by peptide bonds. There are 20 amino acids that humans use.

Hydrogen

Amino Group

Side Chain

The classification of an amino acid is determined by its R group which is the side chain. Certain aspects can classify an amino acid as basic, acidic, polar, or non-polar.

When the R groups are OH or NH they will be polar and hydrophilic.

Nonpolar

When the R groups end with CH or H they will be non-polar and are hydrophobic

Ionic

When the R groups are either + (Basic) or - (acidic) they will form Ionic bonds

Carboxyl Group

Lipids

Triglyceride
Sterols
Cholesterol

Cholesterol is found embedded within the cell membrane.


It also helps with membrane stability and fluidity. 

Low Density Cholesterol

High Density Cholesterol

4 fused rings

Phospholipids
Amphipathic Molecules
Lipid Bilayers

Lipid bilayers form the structure of the membrane. made of hydrophilic head and hydrophobic tail

A phosphate group

The phosphate group is hydrophilic

Two Fatty Acids
A Glycerol

held together by ester linkages

Plasma Membrane

Proteins that need to go to the plasma membrane are embedded into the vesicle membrane. The vesicle merges with the plasma membrane, integrating the protein into the cell surface.

Amphipathic

The membrane contains both hydrophilic and hydrophobic characteristics


Bulk transport

Endocytic

Cell membrane engulfs matrials

Pinocytosis

Takes in fluids

phagocytosis

takes in food

receptor mediated transport

takes in specific proteins

Exocytic

releases materials and they leave the plasma membrane

Chemical Bonds

Non-polar

equal sharing of electrons

Examples: C-H Cl-Cl

Hydrophobic interactions

These molecules tend to separate from water such as oil

Polar

Unequal sharing of electrons

Hydrophilic

Interacts with water.

Intermolecular Bonds

These bonds occur in between two molecules.

permanent dipole

Uneven distribution of electron clouds


Hydrogen Bonding

Hydrogen bonding occurs when an H molecule binds with F< O or N. They are typically strong.


Examples: H2O and NH3

Vanderwaals

Interactions of electrons of non-polar substances.

Intramolecular Bonds

These bonds occur within the molecule.

Ionic

Transfer of electrons, this is usually seen with salts.

NaCl

Covalent

Sharing of electrons some examples are C-H,N-H, S-H.

56