BIOCHEM REVIEWER.docx

Transcript

**THE STRUCTURE AND FUNCTION OF LARGE BIOLOGICAL MOLECULES**

- All living things are made up of four classes of large biological
molecules:

**carbohydrates, lipids, proteins, and nucleic acids.**

- Within cells, small organic molecules are joined together to form
larger molecules.

- **Macromolecules** are large molecules composed of thousands of
covalently connected atoms.

- Molecular structure and function are **inseparable**

**MACROMOLECULES ARE POLYMERS, BUILT FROM MONOMERS**

- A **polymer** is a *long chain-like* molecule consisting of many
similar building blocks.

- These small building-block molecules are called **monomers.**

- Three of the four classes of life's organic molecules are
**polymers**:

-- Carbohydrates

-- Proteins

-- Nucleic acid

**THE SYNTHESIS AND BREAKDOWN OF POLYMERS**

A **condensation reaction** or more specifically a **dehydration
reaction** occurs when two monomers bond together through the loss of a
water molecule: *dehydration synthesis = build by removing HOH.*

- **Enzymes** are ***organic catalyst*s** = macromolecules that
***speed up*** chemical reactions.

- **Polymers** are disassembled to monomers by ***hydrolysis: breaking
down by adding HOH***

**THE DIVERSITY OF POLYMERS**

- Each cell has thousands of different kinds of macromolecules.

- Macromolecules vary among cells of an organism, vary more within a
species, and vary even more between species.

- *An immense variety of polymers can be built from a small set of
monomers.*

**CARBOHYDRATES SERVE AS FUEL AND BUILDING MATERIAL**

- Carbohydrates include sugars and the polymers of sugars.

- The simplest carbohydrates are monosaccharides, or single sugars.

- Carbohydrate macromolecules are polysaccharides, polymers composed
of many sugar building blocks.

- **Monosaccharides** have molecular formulas that are usually
multiples of ***CH2O***

- **Glucose** *(C6H12O6)* is the ***most common monosaccharide.***

- Monosaccharides are classified by

- Though often drawn as linear skeletons, in aqueous solutions many
sugars form rings.

- **Monosaccharides** serve as a major ***fuel*** for cells and as raw
material for building molecules.

A **disaccharide** is formed when a dehydration reaction joins **two
monosaccharides** by *removing* HOH to form a **covalent bond**.

This covalent bond is called a **glycosidic linkage.**

The condensation or dehydration synthesis reaction**: C6H12O6 +
C6H12O6** = **C12H22O11**

*(figure3)*

**POLYSACCHARIDES**

- **Polysaccharides**, the **polymers of sugars**, have *storage* and
structural roles.

- The structure and function of polysaccharides are **determined by
their sugar monomers** and **the positions of the glycosidic
linkages.**

**STORAGE POLYSACCHARIDES**

- **Starch** is a **plant storage** polysaccharide.

- Starch is made of **glucose monomers**.

- Plants store surplus starch as granules within **chloroplasts** and
other **plastids**.

- **Glycogen** is an **animal storage** polysaccharide.

- Glycogen is found in the **liver and muscles**.

*(figure4)*

**STRUCTURAL POLYSACCHARIDES**

- The **polysaccharide cellulose** is a major component of **plant
cell walls.**

- Like starch, cellulose is a polymer of glucose, but the glycosidic
linkages differ.

- The difference is based on two ring forms for glucose: **alpha ( )**
and **beta ( )**

- Polymers **with alpha glucose** are ***helical.***

- Polymers **with beta glucose** are ***straight.***

- In straight structures, H atoms on one strand can bond with OH
groups on other strands.

- Parallel cellulose molecules held together this way are grouped into
microfibrils, which form strong building materials for plants.

- Enzymes that digest starch by hydrolyzing alpha linkages can't
hydrolyze beta linkages in cellulose.

- **Cellulose** in human food passes through the digestive tract as
**insoluble fiber.**

- Some microbes use enzymes to digest cellulose.

- Many **herbivores,** from cows to termites, have **symbiotic
relationships** with these **microbes**.

- **Chitin**, another **structural polysaccharide**, is found in the
*exoskeleton of arthropods.*

- Chitin also provides structural support for the **cell walls of
*fungi.***

- Unlike starch and glycogen, chitin is a polysaccharide **with
nitrogen ( N ) in each sugar monomer.**

**LIPIDS ARE A DIVERSE GROUP OF HYDROPHOBIC MOLECULES**

- **Lipids** are the one class of **large biological molecules that do
*not* form polymers.**

- The unifying feature of lipids is having little or no affinity for
water.

- Lipids are **hydrophobic** because they consist mostly of
hydrocarbons, which form nonpolar covalent bonds.

- The most biologically important lipids are **fats, phospholipids,
and steroids.**

**FATS**

- **Fats** are constructed from two types of smaller molecules:
**glycerol** and **fatty acids.**

- Glycerol is a three-carbon alcohol with a hydroxyl group attached to
each carbon.

- A **fatty acid** consists of a **carboxyl group** attached to a
**long hydrocarbon chain.**

- This **fatty acid hydrocarbon** can be either ***saturated*** or
***unsaturated.***

*(figure8)*

- Fats **separate from water** because water molecules form hydrogen
bonds with each other and exclude the fats.

- In a fat**, three fatty acids** are joined to **glycerol** by an
**ester linkage** (covalent bond), creating a **triacylglycerol**,
or **triglyceride.**

- Fatty acids vary in length (number of carbons) and in the number and
locations of double bonds.

- **Saturated fatty acids** have the maximum number of hydrogen atoms
possible and no double bonds**. All C - C bonds are single.**

- **Unsaturated fatty acids** have one or more **double bonds C = C**

*(figure9)*

- Fats made from **saturated** fatty acids are called saturated fats,
and are **solid at room temperature.**

- **Most animal fats** are **saturated.**

- Fats made from **unsaturated** fatty acids are called unsaturated
fats or oils, and are **liquid at room temperature.**

- **Plant fats** and **fish fats** are usually **unsaturated.**

- A diet rich in saturated fats may contribute to cardiovascular
disease through plaque deposits.

- **Hydrogenation** is the process of converting **unsaturated fats**
to **saturated fats** by *adding hydrogen*.

- **Hydrogenating** *vegetable oils* also creates **unsaturated fats**
with **trans double bonds** = **trans fats.**

- **These trans fats may contribute more than saturated fats to
cardiovascular disease.**

- The major function of **fats** is **energy storage.**

- Humans and other mammals store their fat in **adipose** cells.

- Adipose tissue also **cushions** vital organs and **insulates** the
body.

**PHOSPHOLIPIDS \-- MEMBRANES**

- In a **phospholipid**, two fatty acids and a phosphate group are
attached to glycerol.

- The two fatty acid tails are **hydrophobic**, but the phosphate
group and its attachments form a **hydrophilic** head.

- A phospholipid is an **amphipathic** molecule: hydrophillic head and
hydrophobic tails.

*(figure10)*

- When **phospholipids** are added to water, they self-assemble into a
bilayer, with the hydrophobic tails pointing toward the interior.

- The **amphipathic** structure of phospholipids results in a
**bilayer arrangement** found in cell **membranes.**

- **Phospholipids** are the major component of **all cell membranes.**

*(figure11)*

**STEROIDS = LIPIDS WITH 4 FUSED RINGS...**

- **Steroids** are **lipids** characterized by a carbon skeleton
consisting of **four fused rings.**

- **Cholesterol**, an important steroid, is a component in animal cell
membranes.

- Although cholesterol is essential in animals, high levels in the
blood may contribute to cardiovascular disease.

*(figure12)*

**PROTEINS HAVE MANY STRUCTURES, RESULTING IN A WIDE RANGE OF
FUNCTIONS**

- **Proteins** account for **more than 50% of the dry mass of most
cells.**

- Protein **functions** include structural **support, storage,
transport, cellular communications, movement, defense** against
foreign substances, and organic catalysts (enzymes).

- Proteins are **polymers** called **polypeptides.**

- **Amino acids** are the **monomers** used to build proteins.

Type of Proteins

1. **Enzymatic proteins**

**Function:** Selective acceleration of chemical reaction

**Examples:** Digestive Enzymes

2. **Structural proteins**

**Function:** Support

**Examples:** Silk fibers; collagen and elastin in animal connective
tissues; keratin in hair, horns, feathers, and other skin appendages

3. **Storage proteins**

**Function:** storage of amino acid

**Examples:** ovalbumin in white egg; casein, the protein milk; storage
proteins in plant seed

4. **Transport proteins**

**Function:** Transport of other substances

**Examples:** Hemoglobin, transport proteins

5. **Hormonal proteins**

**Function:** coordination of an organism\'s activities

**Examples:** Insulin, a hormone secreted by the pancreas

6. **Receptor proteins**

**Function:** response of cell to chemical stimuli

**Examples:** receptors in nerve cell membranes

7. **Contractile and motor proteins**

**Function:** Movement

**Examples:** actin and myocin in muscles, proteins in cilia and
flagella

8. **Defensive proteins**

**Function:** protection against disease

**Examples:** antibodies combat bacteria and viruses

- **Enzymes** are LARGE proteins that act as **catalysts** to **speed
up** the rate of chemical reactions in cells.

- Enzymes are **specific**. They must have a **shape-match** with
molecules in the chemical reaction.

- Enzymes can perform their functions repeatedly, working constantly
to carry out the processes of life.

*(figure13)*

**PROTEINS = POLYPEPTIDES**

- **Polypeptides** are **polymers** built from a set of **20** **amino
acids (monomers).**

- The **sequence of amino acids determines** a protein's **3D**
three-dimensional **structure.**

- A protein's structure determines its function.

- A wide **variety** of proteins can be made from a few monomers by
varying the **amino acid sequence.**

**PROTEINS - AMINO ACID MONOMERS**

- **Amino acids** are organic molecules with **carboxyl** and **amino
groups** *attached* to a **central carbon.**

- Amino acids differ in their properties due to **variable side
chains**, called **R groups**. The R group is also ***attached to
the central carbon.***

- There are **20 different amino acids** because there are **20
different side chains.**

*(figure14&15)*

**AMINO ACID POLYMERS**

- **Amino acids are linked** by covalent bonds called **peptide bonds
C - N**

- A **polypeptide** is **a polymer of amino acids.**

- Polypeptides range in length from a few to more than a thousand
monomers.

- Each polypeptide has a unique linear sequence of amino acids.

*(figuure16)*

- The **sequence of amino acids** determines a protein's
three-dimensional structure.

- **A protein's structure determines its function.**

- A **functional protein** consists of one or more polypeptides
twisted, folded, and coiled into a **unique shape.**

*(figure17 & 18)*

**FOUR LEVELS OF PROTEIN STRUCTURE \-- BECOMING**

*(figure19)*

Functional Proteins:

- The **primary** structure of a protein is its **unique** sequence of
amino acids in a **polypeptide chain.**

- **Primary structure** is the **sequence of amino acids** in **a
polypeptide chain** (protein). This is like the order of letters in
a long word.

- Primary structure is determined by **inherited genetic information**
**(DNA).**

*(figure20)*

- **Secondary** structure consists of **regular *coils*** and
***folds*** in the polypeptide **backbone** made by **hydrogen
bonds**.

- The coils and folds of **secondary structure** result from
**hydrogen bonds** between repeating constituents of the
**polypeptide backbone.**

- These regular bonds often make **fibrous proteins.**

- Typical secondary structures are a **coil called an alpha helix**
and **a folded structure called a beta pleated sheet.**

***(**figure21 & 22)*

- **Tertiary** structure is determined by interactions among various
side chains **R groups.**

- **Tertiary structure** is determined by interactions between **R
groups**, rather than interactions between backbone constituents.

- These **R group interactions** fold the polypeptide into a
**globular shape.**

- These **interactions** between R groups include **hydrogen bonds,
ionic bonds, hydrophobic interactions, and van der Waals
interactions.** Strong covalent bonds called **disulfide bridges**
may reinforce the protein's structure.

- **Quaternary** structure results when a protein consists of
**multiple** polypeptide **chains.**

- **Quaternary structur**e results **when two or more polypeptide
chains** form one macromolecule.

- **Collagen** is a **fibrous protein** consisting of three
**polypeptides coiled like a rope.**

- **Hemoglobin** is a **globular protein** consisting of four
polypeptides: two alpha and two beta chains each with an iron
**heme** group.

*(figure24)*

**SICKLE-CELL DISEASE: A CHANGE IN DNA AND PRIMARY STRUCTURE**

- A slight change in a proteins DNA can change its primary structure
(amino acid sequence). This can affect a protein's structure and
ability to function.

- Sickle-cell disease, an inherited blood disorder, results from a
single amino acid substitution in the protein hemoglobin.

*(figure25 &26)*

I. CARBOHYDRATE DEFICIT DISORDERS

Disorders **resulting from insufficient carbohydrate intake or
metabolism**, leading to energy deficiencies and metabolic
complications.

**DISORDERS**

1. **Hypoglycemia**

**Symptoms:** Weakness, sweating, confusion, irritability.

**Causes:** Excessive insulin, prolonged fasting, inadequate
carbohydrate intake.

2. **Ketoacidosis**

**Symptoms:** Nausea, vomiting, abdominal pain, fruity breath.

**Causes:** Lack of carbohydrates in diabetics, leading to fat breakdown
and ketone production.

3. **Glycogen Storage Disease (GSD)**

**Types:** Several types based on enzyme deficiencies (e.g., GSD type
I).

**Symptoms:** Hypoglycemia, enlarged liver, growth delay.

4. **Starvation**

**Symptoms:** Extreme weight loss, muscle wasting, fatigue.

**Causes:** Prolonged lack of food intake.

5. **Muscle Wasting**

**Symptoms:** Decreased muscle mass and strength.

**Causes:** Inadequate carbohydrate intake leading to protein breakdown
for energy.

6. **Ketosis**

**Symptoms:** Fatigue, bad breath (fruity odor), nausea.

**Causes:** Low carbohydrate availability, leading to fat utilization
for energy.

7. **Marasmus**

**Symptoms:** Severe weight loss, stunted growth.

**Causes**: Deficiency in carbohydrates and proteins.

8. **Lactic Acidosis**

**Symptoms:** Muscle pain, fatigue, rapid breathing.

**Causes:** Accumulation of lactic acid due to impaired glucose
metabolism.

9. **Hypoglycemic Shock**

**Symptoms:** Confusion, seizures, loss of consciousness.

**Causes:** Severe drop in blood sugar levels.

10. **Fatigue and Weakness**

**Symptoms:** Persistent tiredness, low energy.

**Causes:** Inadequate glucose supply for energy.

**DIAGNOSIS AND TREATMENT**

**Diagnosis:** Blood tests for glucose levels, metabolic panels, genetic
testing for GSD.

**Treatment:** Dietary management (increased carbohydrates), glucose
supplementation, enzyme replacement therapy (for GSD).

II\. LIPID DISORDERS

Disorders characterized **by abnormal lipid levels in the blood**,
leading to **cardiovascular** and **metabolic complications**.

**DISORDERS**

1. **Hyperlipidemia**

**Symptoms**: Often asymptomatic but may lead to cardiovascular disease.

**Causes:** Diet high in saturated fats, genetic factors, sedentary
lifestyle.

2. **Atherosclerosis**

**Symptoms:** Chest pain (angina), shortness of breath, fatigue.

**Causes:** Buildup of lipids and plaque in arterial walls.

3. **Familial Hypercholesterolemia**

**Symptoms:** Early onset heart disease, xanthomas (cholesterol deposits
in skin).

**Causes:** Genetic mutation affecting LDL receptor function.

4. **Obesity**

**Symptoms:** Excess body fat, increased body mass index (BMI).

**Causes:** Excessive caloric intake, particularly from lipids, combined
with low physical activity.

5. **Lipid Storage Disease**

**Types:** Includes disorders like Gaucher and Tay-Sachs disease.

**Symptoms:** Vary widely depending on the specific disorder; often
involves organ dysfunction.

**Causes**: Genetic mutations leading to defective lipid metabolism.

**DIAGNOSIS AND TREATMENT**

**Diagnosis:** Lipid panels to measure cholesterol and triglyceride
levels, imaging tests for atherosclerosis.

**Treatment:** Dietary modifications (lowering saturated fats),
medications (statins, fibrates), lifestyle changes (exercise).







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