3-Biological Molecules: The Carbon Compounds of Life Exam Review PDF

Summary

This document appears to be chapter notes on biological molecules, specifically carbon compounds. It covers topics such as the formation and modification of biological molecules, carbohydrates, lipids, proteins, and nucleic acids. It also includes learning objectives and key terms relating to the subject matter.

Full Transcript

3-BIOLOGICAL MOLECULES: THE CARBON COMPOUNDS\
OF LIFE

Chapter Outline
===============

3.1 FORMATION AND MODIFICATION OF BIOLOGICAL MOLECULES

Carbon chains and rings form the backbones of all biological molecules.

Functional groups confer specific properties to biological molecules.

Isomers have the same chemical formula but different molecular
structures.

A water molecule is added or removed in many reactions involving
functional groups.

Many carbohydrates, proteins, and nucleic acids are macromolecules.

3.2 CARBOHYDRATES

Monosaccharides, Disaccharides, Polysaccharides are the structural units
of carbohydrates.

General Formula

Glycosidic bonds

3.3 LIPIDS

Neutral lipids are familiar as fats and oils.

Phospholipids provide the framework of biological membranes.

A boundary phospholipid membrane around organic molecules was key to the
formation of cells and the origin of life.

Steroids contribute to membrane structure and work as hormones.

3.4 PROTEINS

Cells assemble 20 kinds of amino acids into proteins by forming peptide
bonds.

Proteins have as many as four levels of structure.

Primary structure is the fundamental determinant of protein form and
function.

Coils and folds of the amino acid chain form the secondary structure of
a protein.

The alpha helix and The beta strand.

The tertiary structure of a protein is its overall three-dimensional
conformation.

Multiple polypeptide chains form quaternary structure.

Combinations of secondary, tertiary, and quaternary structure form
functional domains in many proteins.

Proteins combine with units derived from other classes of biological
molecules.

Some proteins and protein regions have disordered structures.

3.5 NUCLEOTIDES AND NUCLEIC ACIDS

Nucleotides consist of a nitrogenous base, a five-carbon sugar, and one
or more phosphate groups.

DNA and RNA consist of chains of nucleotides and are the informational
molecules in cells.

DNA molecules in cells consist of two polynucleotide chains wound
together.

RNA molecules are usually single nucleotide chains.

Learning Objectives
===================

1\. Summarize the properties of carbon that have made it important for
the evolution of a wide diversity of organisms.

2\. Know and describe how functional groups are important for the
functions of biological molecules.

3\. Define isomer and state the relevance of isomers to biochemical
reactions.

4\. Define a dehydration synthesis reaction and hydrolysis.

5\. Differentiate between monosaccharides, disaccharides, and
polysaccharides, the different forms of carbohydrate molecules.

6\. Describe the structure and properties of lipids.

7\. List major protein functions in living organisms.

8\. Discuss the structure of amino acids, the formation of polypeptides,
and the four levels of protein structure.

9\. Describe the structure of nucleotides and how they link together to
form DNA and RNA.

10\. The structure of DNA and how it differs from RNA.

Key Terms
=========

organic molecules

inorganic molecules

hydrocarbons

functional groups

chemical evolution

hydroxyl group

carbonyl group

carboxyl group

amino group

phosphate group

sulfhydryl group

isomers

stereoisomers

structural isomers

dehydration synthesis reaction

condensation reaction

hydrolysis

polymer

polymerization

macromolecule

starch

glycogen

cellulose

monosaccharides

disaccharide

polysaccharides

glycosidic bonds

lipids

neutral lipids

oils

fats

triglyceride

fatty acid

ester linkage

saturated

unsaturated

monounsaturated

polyunsaturated

waxes

phospholipids

steroids

sterols

cholesterol

phytosterols

enzymes

amino acid

peptide bond

N-terminal end

C-terminal end

polypeptide

primary structure

secondary structure

tertiary structure

quaternary structure

alpha helix

beta sheet

conformation

denaturation

renaturation

chaperone proteins

chaperonins

conformational changes

domains

deoxyribonucleic acid (DNA)

ribonucleic acid (RNA)

nucleotide

nitrogenous base

pyrimidines

purines

deoxyribose

ribose

deoxyribonucleotides

ribonucleotides

nucleoside

phosphodiester bond

double helix

template

4-CELLS

Chapter Outline
===============

4.1 BASIC FEATURES OF CELL STRUCTURE AND FUNCTION

Cells are visualized using a microscope.

Evolutionary adaptations circumvent cell size limits

Cells are subdivided into compartments.

Cells occur in prokaryotic and eukaryotic forms, each with distinctive
structures and organization.

4.2 PROKARYOTIC CELLS

Structure and organization of prokaryotic cells.

Evolutionary divergence of bacteria and archaea.

4.3 EUKARYOTIC CELLS

Eukaryotic cells have a true nucleus and cytoplasmic organelles enclosed
within a plasma membrane.

Eukaryotic DNA is enclosed in a membrane-bound nucleus.

Eukaryotic ribosomes are either free in the cytosol or attached to
membranes.

An endomembrane system divides the cytoplasm into functional and
structural compartments.

*Endoplasmic reticulum*

*Golgi complex*

*Lysosomes*

Mitochondria are the organelles in which some reactions of cellular
respiration occur.

*Mitochondrial function*

*Mitochondrial structure*

*Evolutionary origin of mitochondria*

The cytoskeleton supports and moves cell structures.

Flagella propel cells, and cilia move materials over the cell surface.

4.4 SPECIALIZED STRUCTURES OF PLANT CELLS

Chloroplasts are biochemical factories powered by sunlight.

Central vacuoles have diverse roles in storage, structural support, and
cell growth.

Cell walls support and protect plant cells.

The extracellular matrix organizes the cell exterior.

4.5 THE ANIMAL CELL SURFACE

Cell adhesion molecules organize animal cells into tissues and organs.

Cell junctions reinforce cell adhesions and provide avenues of
communication.

The extracellular matrix organizes the cell exterior.

Learning Objectives
===================

1\. Identify the relative sizes of different types of cells and
structures within cells.

2\. Analyze the advantages and disadvantages of different forms of
microscopy.

3\. Explain how compartments are formed within cells and the advantages
of compartmentalization.

4\. Compare the organization of prokaryotic and eukaryotic cells.

5\. Describe the structure and function of each eukaryotic organelle.

6\. Distinguish which organelles are present in animal cells, in plant
cells, or in both.

7\. Explain how the endomembrane system transports proteins and membrane
to their appropriate destinations.

8\. Describe how cytoskeletal filaments work together to determine cell
shape and generate forces within cells.

9\. Identify what structures attach animal cells together to form
tissues.

Key Terms
=========

cell theory

microscopy

microscope

light microscope

electron microscopes

magnification

resolution

plasma membrane

cytoplasm

organelles

cytosol

cytoskeleton

prokaryotes

nucleoid

eukaryotes

nucleus

prokaryotic chromosome

ribosomes

cell wall

glycocalyx

slime layer

capsule

flagella

bacterial flagellum

pili

nuclear envelope

nuclear pore complex

nucleoporins

nuclear pore

nuclear localization signal

nucleoplasm

chromatin

eukaryotic chromosome

nucleoli

endomembrane system

vesicles

endoplasmic reticulum

cisternae

ER lumen

rough ER

smooth ER

Golgi complex

secretory vesicles

exocytosis

endocytosis

endocytic vesicle

lysosomes

phagocytosis

mitochondria

outer mitochondrial membrane

inner mitochondrial membrane

cristae

mitochondrial matrix

microbodies

peroxisomes

microtubules

cell center

centrosome

centrioles

intermediate filaments

microfilaments

basal body

chloroplasts

plastids

amyloplasts

chromoplasts

outer boundary membrane

inner boundary membrane

thylakoids

grana

central vacuoles

tonoplast

primary cell wall

secondary cell wall

middle lamella

plasmodesmata

cell adhesion molecules

cell junctions

extracellular matrix

anchoring junctions

desmosomes

adherens junctions

tight junctions

gap junctions

collagen

proteoglycans