Text section where you can find more information ENERGY FOR LIFE begins as Electromagnetic energy in SUNLIGHT 10.2 drives begins with 10.1 10.2 PHOTOSYNTHESIS (in chloroplasts) • Light excites electrons in pigment molecules Antenna complex enters H 2 O • “Splits” water to yield electrons • Electron transport chain pumps H + Photosystem II 10.3 10.3 • Electron transport chain ends with ferrodoxin Photosystem I donates energy from excited electrons to donates energy from excited electrons to donates high- energy electrons to • H + gradient drives ATP synthase Chemiosmosis releases yields O 2 ATP 9.1 NADPH used in CO 2 • Series of enzyme-catalyzed reactions Calvin cycle 10.4 fixed by rubisco to start yields substrate for synthesis of stored as broken down to yield Glycogen, starch 5.2 5.1 GLUCOSE processed by 9.3 • 10 enzyme-catalyzed reactions Glycolysis (in cytosol) CELLULAR RESPIRATION (in mitochondria) allows continued when electron acceptor available, yields pyruvate for 9.2 • Regenerates NAD + • Substrates and waste products vary among species Fermentation 9.7 when no electron acceptor available, donates electrons to begins with CO 2 H 2 O O 2 NADH ATP • Catalyzed by pyruvate dehydrogenase Pyruvate processing 9.4 yields acetyl CoA for 9.5 • 8 enzyme-catalyzed reactions • Completes oxidation of glucose Citric acid cycle yields yields CO 2 FADH 2 donates high energy electrons to used in • Raises potential energy Phosphorylation of enzymes and substrates 9.1 drives • Uses energy released during redox reactions to transport H + • Ends with final electron acceptor (usually O 2 ) Electron transport chain 9.6 • H + gradient drives ATP synthase Chemiosmosis yields some yields lots of 9.1 • Reactions that were endergonic with unphosphorylated enzymes/substrates become exergonic with phosphorylated enzymes/subtrates Energetic coupling enables Cells use energy to do work • pump ions • synthesize molecules • move cargo • send and receive signals
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Text section where you can find more information ENERGY FOR LIFE begins as Electromagnetic energy in SUNLIGHT 10.2 drives begins with 10.1 10.2 PHOTOSYNTHESIS.
processed by enzyme-catalyzed reactions Glycolysis (in cytosol) CELLULAR RESPIRATION (in mitochondria) allows continued when electron acceptor available, yields pyruvate for 9.2 Regenerates NAD + Substrates and waste products vary among species Fermentation 9.7 when no electron acceptor available, donates electrons to begins with CO 2 H2OH2O O2O2 NADH ATP Catalyzed by pyruvate dehydrogenase Pyruvate processing 9.4 yields acetyl CoA for enzyme-catalyzed reactions Completes oxidation of glucose Citric acid cycle yields CO 2 FADH 2 donates high energy electrons to Uses energy released during redox reactions to transport H + Ends with final electron acceptor (usually O 2 ) Electron transport chain 9.6 H + gradient drives ATP synthase Chemiosmosis yields some yields lots of
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Text section whereyou can find moreinformation
ENERGY FOR LIFE
begins as
Electromagnetic energy inSUNLIGHT
10.2
drives
begins with
10.1
10.2
PHOTOSYNTHESIS(in chloroplasts)
• Light excites electrons in pigment molecules
Antenna complex
enters
H2O
• “Splits” water to yield electrons• Electron transport chain pumps H+
Photosystem II
10.3
10.3
• Electron transport chain ends with ferrodoxin
Photosystem I
donatesenergyfrom excitedelectrons to
donatesenergyfrom excitedelectrons to
donateshigh-energyelectrons to
• H+ gradient drives ATP synthase
Chemiosmosis
releases yields
O2 ATP 9.1 NADPH
used in
CO2 • Series of enzyme-catalyzed reactions
Calvin cycle
10.4fixed byrubiscoto start
yields substratefor synthesis of
stored as
broken downto yield
Glycogen, starch 5.2 5.1GLUCOSE
processed by
9.3
• 10 enzyme-catalyzed reactions
Glycolysis (in cytosol)
CELLULAR RESPIRATION(in mitochondria)
allows continued
when electron acceptoravailable, yields pyruvate for
9.2• Regenerates NAD+
• Substrates and waste products vary among species
Fermentation
9.7
when no electronacceptor available, donates electrons to
begins with
CO2
H2OO2
NADH
ATP
• Catalyzed by pyruvate dehydrogenase
Pyruvate processing
9.4
yields acetyl CoA for
9.5
• 8 enzyme-catalyzed reactions• Completes oxidation of glucose
Citric acid cycle
yields yields
CO2
FADH2
donateshigh energyelectrons to
used in
• Raises potential energy
Phosphorylation of enzymesand substrates
9.1
drives
• Uses energy released during redox reactions to transport H+
• Ends with final electron acceptor (usually O2)
Electron transport chain
9.6
• H+ gradient drives ATP synthase
Chemiosmosis
yields someyields lots of
9.1
• Reactions that were endergonic with unphosphorylated enzymes/substrates become exergonic with phosphorylated enzymes/subtrates
Energetic coupling
enables
Cells use energy to do work• pump ions• synthesize molecules• move cargo• send and receive signals
Text section whereyou can find moreinformation
ENERGY FOR LIFE
begins as
Electromagnetic energy inSUNLIGHT
10.2
drives
begins with
10.1
10.2
PHOTOSYNTHESIS(in chloroplasts)
• Light excites electrons in pigment molecules
Antenna complex
enters
H2O
• “Splits” water to yield electrons• Electron transport chain pumps H+
Photosystem II
10.310.3
• Electron transport chain ends with ferrodoxin
Photosystem I
donatesenergyfrom excitedelectrons to
donatesenergyfrom excitedelectrons to
donateshigh-energyelectrons to
• H+ gradient drives ATP synthaseChemiosmosis
releases yields
O2 ATP 9.1 NADPH
used in
CO2 • Series of enzyme-catalyzed reactions
Calvin cycle
10.4fixed byrubiscoto start
yields substratefor synthesis of
stored as
broken downto yield
Glycogen, starch 5.2 5.1GLUCOSE
processed by
9.3
• 10 enzyme-catalyzed reactionsGlycolysis (in cytosol)
CELLULAR RESPIRATION(in mitochondria)
allows continued
when electron acceptoravailable, yields pyruvate for
9.2• Regenerates NAD+
• Substrates and waste products vary among species
Fermentation
9.7
when no electronacceptor available, donates electrons to
begins with
CO2
H2OO2
NADH
ATP
• Catalyzed by pyruvate dehydrogenase
Pyruvate processing
9.4
yields acetyl CoA for
9.5
• 8 enzyme-catalyzed reactions• Completes oxidation of glucose
Citric acid cycle
yields yields
CO2
FADH2
donateshigh energyelectrons to
• Uses energy released during redox reactions to transport H+
• Ends with final electron acceptor (usually O2)
Electron transport chain
9.6
• H+ gradient drives ATP synthaseChemiosmosis
yields someyields lots of
used in
• Raises potential energy
Phosphorylation of enzymesand substrates
9.1
drives
9.1
• Reactions that were endergonic with unphosphorylated enzymes/substrates become exergonic with phosphorylated enzymes/subtrates
Energetic coupling
enables
Cells use energy to do work• pump ions• synthesize molecules• move cargo• send and receive signals
ATP 9.1
consists offunctional units called
is archived inbase sequences of
DNA 4.2
GENETIC INFORMATION
Genes
EXPRESSED
15.1
15.217.1–418.1–4
Text sectionwhere youcan find moreinformation
13.2Genotype
is packaged withproteins to form
have differentversions called
make up
can be
may regulatewhether genes
if firstTRANSCRIBED by
RNA polymerase
16.1
4.3
to form
RNA
may beprocessed by may function
directly incell as
16.2
• Splicing• Addition of 5 cap• Addition of poly(A) tail
to form
16.4
16.5
• tRNA (transfer RNA)• rRNA (ribosomal RNA)
mRNA(messenger of RNA)
16.2is then
TRANSLATED byaffect
Ribosomes 16.5
to form
Proteins
3.216.5
changed by
produce13.1Phenotype • Folding
• Glycosylation• Phosphorylation• Degradation
3.45.39.1
18.4
Chromatin 18.2
COPIED 14.3
13.2Alleles
are
by
DNA polymerase
14.3occasionallymake errors,
causing
MUTATION 15.4
Chromosomes11.118.2
andcan be
can be
may change due to
causing
• Breakage• Duplication or deletion due to errors in meiosis• Damage by radiation or other agents
14.515.4
12.4
15.4Mutationcan be
to somaticcells by to germ cells by
12.1, 13.1–4
TRANSMITTED 11.1
11.1MITOSIS 12.1MEIOSISincludes
12.2 13.3–4
• Independent assortment• Recombination
starts with starts withParent cell
2n 2n
Parent cell
ends with ends with
2n 2n
Two daughter cellswith the same geneticinformation as theparent cell (unlessmutation has occurred).
Four daughter cellswith half the geneticinformation as theparent cell.
n
n
n
n
occursduring
occursduring
GROWTH and ASEXUALREPRODUCTION
SEXUALREPRODUCTION
11.0 12.3
result in results in
Low genetic diversity High genetic diversity
is archived inbase sequences of
DNA
GENETIC INFORMATION
Genes
EXPRESSED
Text sectionwhere youcan find moreinformation consists of
functional units called
13.2Genotypemake up
can be
may regulatewhether genes
if firstTRANSCRIBED by
RNA polymerase
16.1
4.3
to form
RNA
4.2
15.1
15.217.1–418.1–4
4.3
RNA
may beprocessed by
may functiondirectly incell as
16.2
• Splicing• Addition of 5 cap• Addition of poly(A) tail
to form
16.4
16.5
• tRNA (transfer RNA)• rRNA (ribosomal RNA)
mRNA(messeger of RNA)
16.2is then
TRANSLATED byaffect
Ribosomes 16.5
to form
Proteins
3.216.5
changed by
produce13.1Phenotype • Folding
• Glycosylation• Phosphorylation• Degradation
3.45.39.1
18.4
Chromatin 18.2
COPIED 14.3
13.2Alleles
are
by
DNA polymerase
14.3occasionallymake errors,
causing
MUTATION 15.4
Chromosomes 11.118.2
andcan be
can be
may change due to
causing
• Breakage• Duplication or deletion due to errors in meiosis• Damage by radiation or other agents
14.515.4
12.4
15.4Mutationcan be
to somaticcells by to germ cells by
12.1, 13.1–4
TRANSMITTED 11.1
11.1MITOSIS 12.1MEIOSISincludes
12.2 13.3–4
• Independent assortment• Recombination
11.1MITOSIS 12.1MEIOSISincludes
12.2 13.3–4
• Independent assortment• Recombination
starts with starts with
Parent cell
2n 2n
Parent cell
ends with ends with
2n 2n
Two daughter cellswith the same geneticinformation as theparent cell (unlessmutation has occurred).
Four daughter cellswith half the geneticinformation as theparent cell.
n
n
n
n
occursduring
occursduring
GROWTH and ASEXUALREPRODUCTION
SEXUALREPRODUCTION
11.0 12.3
result in results in
Low genetic diversity High genetic diversity
25.1
EVOLUTION
isChange through time
is
isdue to due to
does not produce
Changes in allele frequencies
Descent with modification
due to
Inbreeding• Mating among relatives• Changes genotype frequencies, but not allele frequencies
Sexual selection
25.6 25.6
• Occurs when traits used in attracting mates vary, and individuals with certain traits attract the most mates
includes
includes includes
NATURAL SELECTION• Occurs when traits vary, and individuals with certain traits produce the most offspring
24.124.3–525.2
exposesdeleterious
alleles to
Non-random mating 25.6
Text section whereyou can find moreinformation
is the onlyevolutionarymechanism thatcan produce
Adaptation• Involves heritable traits only
24.3, 24.5
Fitness• Measured by number of offspring produced
24.3,24.5
25.1–6
usuallyreduces
due to
25.3
GENETIC DRIFT• Changes in allele frequencies due entirely to chance• Especially important in small populations
due to due to
MUTATION• Random changes in DNA• Creates new alleles• Occurs in every individual in every generation, at low frequency
15.4, 25.5
GENE FLOW• Occurs when individuals move between populations• Homogenizes allele frequencies between populations
Geneflow 25.4
due to lack ofproduces divergence required for
producesdivergencerequired for
produces divergence required for
26.2–4
SPECIATIONResults from:1. Genetic isolation, followed by2. Genetic divergence
creates new branches on
form smallest possible tips on
The TREE OF LIFE• Describes the evolutionary relationships among species
1.3, 27.1
“prune”
MASS EXTINCTIONS• 60% of species are lost in less than 1 million years• 5 events in the past 542 million years• Is analogous to genetic drift
Synamorphies• Traits that are unique to a single lineage (found in some species but not others)• Arise in a common ancestor
26.127.1
thatmaybe
Key innovations• Traits that allow species to exploit resources in a new way or use new habitats
27.4
mayresultin
ADAPTIVE RADIATIONS• Rapid and extensive speciation in a single lineage• Dramatic divergence in morphology or behavior (species use a wide array of resources/habitats)
27.3
25.1
EVOLUTION
isChange through time
is
isdue to due to
does not produce
Changes in allele frequencies
Descent with modification
due to
Inbreeding
• Mating among relatives• Changes genotype frequencies, but not allele frequencies
Sexual selection
25.6 25.6
• Occurs when traits used in attracting mates vary, and individuals with certain traits attract the most mates
includes
includes includes
NATURAL SELECTION• Occurs when traits vary, and individuals with certain traits produce the most offspring
24.124.3–525.2
exposesdeleterious
alleles to
Non-random mating 25.6
Text section whereyou can find moreinformation
is the onlyevolutionarymechanism thatcan produce
Adaptation
• Involves heritable traits only
24.3, 24.5
Fitness• Measured by number of offspring produced
24.3,24.5
25.1–6
usuallyreduces
due to
25.3
GENETIC DRIFT• Changes in allele frequencies due entirely to chance• Especially important in small populations
due to due to
MUTATION
• Random changes in DNA• Creates new alleles• Occurs in every individual in every generation, at low frequency
15.4, 25.5
GENE FLOW• Occurs when individuals move between populations• Homogenizes allele frequencies between populations
Geneflow 25.4
25.3
GENETIC DRIFT
• Changes in allele frequencies due entirely to chance• Especially important in small populations
MUTATION
• Random changes in DNA• Creates new alleles• Occurs in every individual in every generation, at low frequency
15.4, 25.5
GENE FLOW
• Occurs when individuals move between populations• Homogenizes allele frequencies between populations
Geneflow 25.4
due to lack ofproduces divergence required for
producesdivergencerequired for
produces divergence required for
26.2–4
SPECIATION
Results from:1. Genetic isolation, followed by2. Genetic divergence
creates new branches on
form smallest possible tips on
The TREE OF LIFE
• Describes the evolutionary relationships among species
1.3, 27.1
“prune”
MASS EXTINCTIONS
• 60% of species are lost in less than 1 million years• 5 events in the past 542 million years• Is analogous to genetic drift