BIOL 241 Reproduction Lecture Slides PDF

Summary

These lecture slides for BIOL 241 cover the topic of reproduction in organisms, examining life history strategies and energy allocation. They discuss trade-offs between different aspects of reproduction. The slides include diagrams and references, related to a possible research study on how organisms adapt to their environment.

Full Transcript

Instructor: Dr. Sam Yeaman

My research aims to understand how organisms adapt to their environment. Is evolution flexible? Do different
species respond similarly/differently to the same challenge?

Office hours: Wednesdays 4-5pm BI 394
[email protected] (subject: BIOL 241)
Instructor: Dr. Sam Yeaman

100
80
We use computer simulations, genome sequence data, and statistical modelling

H.annuus
60
40
20
0
100
80

H.argophyllus
60
40
Top candidate index (log10)
20
0
100
80

H.pet.fallax
60
40
20
0
Focal = H.annuus

100
Distance along chromosome (Mbp) Focal = other
H.argophyllus
H.pet.fallax

80
H.pet.petiolaris

H.pet.petiolaris
60
Office hours: Wednesdays 4-5pm BI 394

40
20
[email protected] (subject: BIOL 241)

0
 Upcoming this week and next

Lecture Assignment 4
– Next Wednesday November 27
– Topic 10: Reproduction
– Bring a response form!
– D2L Content -> Lecture Assignments
Overview of Biology 241

Biology 241 deals with energy flow in biological systems:
Unit 1: Molecular Energy Transformations
Unit 2: Cellular Energy Transformations
Unit 3: Energy Allocation in Organisms
A. Energy Budgets
B. Thermoregulation
C. Locomotion
D. Reproduction
Unit 4: Energy Flow in Ecosystems

Chapter 26, sections 26.1 to 26.4, 26.7b
 Learning Objectives:
1. Explain why energy is needed for growth (e.g., synthesis of new tissues, repair and
reproduction)
2. Define “life history”; explain how and why life history strategies vary among species
and even within populations. Recognize how life history traits co-vary across species,
often along a continuum associated with r and K selection strategies
3. Be able to interpret life tables and survivorship curves; describe the three types of
survivorship curves and provide an example of an organism exhibiting each type of
curve
4. Explain what is meant by a life-history tradeoff: interpret data in terms of
costs/benefits and tradeoffs between current reproduction and other uses of energy.
Recognize that the optimal resolution of these tradeoffs determine life history traits
such as: when to start breeding, how often to breed, how much to invest in each
offspring, and how long to live
 Eproduction
The ideal: unlimited resources
to support maximal growth, long life
continuous production of offspring (with high survival)
Most organisms do not live under these conditions

Energy must be spent to find food, avoid predators, etc.

– Ultimate goal of managing an energy budget properly is to have energy remaining
to allocate to reproduction
Natural selection has resulted in numerous strategies
(called life history traits ) to maximize lifetime reproductive success
(FITNESS)
 Life History Theory
Every species has a pattern of growth and development, reproduction,
and death shaped by natural selection
success in the past shapes the life history traits of a species

The environment affects life history traits by influencing energy budgets:
amount of light, food sources, shelter, wind, precipitation, etc.

Maximizing reproductive success involves trade-offs due to
fixed energy budgets and selective pressures (environment)
 Trade-offs arise from limits in energy budgets
If 2 life-history traits compete for a share of limited resources, then it's impossible
to maximize both traits simultaneously
– any gains by one trait will result in a loss by the other
Example: seed size vs seed number

Number of seeds
Fitness
Fitness

Number of seeds Seed size Seed size
 Growth
Indeterminate Growth
Growth of the organism continues throughout the lifespan
(example: ectotherms - reptiles, fish, plants, etc)

Determinate Growth
 Growth
Indeterminate Growth
Growth of the organism continues throughout the lifespan
(example: ectotherms - reptiles, fish, plants, etc)

Determinate Growth
Growth of the organism ceases when “adult” state is reached
(example: endotherms - birds, mammals)
 Reproduction
Asexual reproduction produces clones (“exact” copy)
– Prokaryotes replicate their genome and then divide by binary fission

– Some eukaryotes replicate their genomes and divide by mitosis
(protists, fungi, some plants)
Sexual reproduction produces recombinants
–

–
 Reproduction
Asexual reproduction produces clones (“exact” copy)
– Prokaryotes replicate their genome and then divide by binary fission

– Some eukaryotes replicate their genomes and divide by mitosis
(protists, fungi, some plants)
Sexual reproduction produces recombinants (combined genomes)
– Replicated genomes are halved into gametes (sperm or eggs) and combined
with other gametes to produce a zygote
– Only in eukaryotes
 Life History Traits

Life history traits are variable:
– Growth rate
– Parental investment
– Number of offspring (fecundity)
– Frequency of reproduction (parity)
– Size/age at sexual maturity
– Size of offspring
– Longevity/life expectancy (mortality rate)
Tradeoff Between Growth Rate and Reproduction
en.wikipedia.org/wiki/File:Blue-
headed_wrasse_det.jpg

Blue-headed wrasse
(Thalassoma bifasciatum)

-Warner (1984; Evolution 38:148)
 Growth & reproduction in white suckers

Indeterminate growth
Growth slows at maturity 3-5 y
3-5 y Data from Ontario lakes

Beamish, R.J. 1973. J. Fish. Res. Board Can. 30:607-616
How Much Parental Investment Should a Parent Provide Each Offspring?
How Many Offspring Should Be Produced?
Passive care = pre “birth” energy investment (seed development, gestation, etc.)
Active care = post “birth” energy investment (raising offspring)
Orchid seeds Mice

Coco-de-mer seed Elephants

All images Wikimedia Commons
How Much Parental Investment Should a Parent Provide Each Offspring?
How Many Offspring Should Be Produced?
Passive care = pre “birth” energy investment (seed development, gestation, etc.)
Active care = post “birth” energy investment (raising offspring)
Orchid seeds Mice
little passive care
no active care
lots of seeds, some survive

Coco-de-mer seed Elephants

lots of passive care
no active care
one large seed
(high energy store to increase survival)
All images Wikimedia Commons
How Much Parental Investment Should a Parent Provide Each Offspring?
How Many Offspring Should Be Produced?
Passive care = pre “birth” energy investment (seed development, gestation, etc.)
Active care = post “birth” energy investment (raising offspring)
Orchid seeds Mice
little passive care some passive care (few weeks)
no active care some active care
lots of seeds, some survive multiple offspring, some live

Coco-de-mer seed Elephants

lots of passive care high passive care (18 mos)
no active care high active care (4 years)
one large seed few offspring
(high energy store to increase survival)
All images Wikimedia Commons
Each point on the following graphs relates the average number of
eggs in a reproductive season to the average number of reproductive
seasons. Each point is a species.
Which graph describes a trade-off between egg number and number
of reproductive seasons?

A B C

Egg number
Egg number

Egg number

Reproductive Seasons Reproductive Seasons Reproductive Seasons
 A Trade-off Between Parental Care and Survival of Offspring

European Magpie (Pica pica) average ~7 eggs per clutch
results in 3-4 fledged (ready to fly)
Wikimedia Commons
always some lost to disease/predation
(same with lower clutch size)

less energy to go around (parents couldn’t feed them all)

9 eggs a total loss (very little energy)

-Hogstedt (1980; Science 4474:1148)
 A Tradeoff Between Reproduction and Survival of Parent
Not enough energy for both
high fecundity and
high survivorship

Wikimedia Commons

species with low fecundity
and low survivorship go extinct
n = 118 species
Ghalambor & Martin. 2001. Science 292:494- 497
Recap of Monday’s lecture:
The critical factor we discussed was that energy budgets are limited. Organisms can only take in so
much food/light, and with that limited supply, they must "decide" how to spend it.

If they spend more energy on laying lots of eggs, they will have less energy left over to run away from
predators, and may suffer mortality.

On the other hand, if they spend less energy on laying eggs and only run around and avoid getting
caught, they'll live a long life but leave few descendents.

Natural selection favours whatever strategy leaves the most descendents.

Thus: over time, it favours whatever particular combination of traits is best suited to the environment.

Because species live in different environments, they tend to differ in their life history strategies and
combinations of life history traits that work best.
 A Tradeoff Between Reproduction and Survival of Parent

Mortality rates of female red deer (Cervus elaphus)
= with fawns

= no fawns

Wikimedia Commons

=female

No offspring = energy to sustain self (until old age)
Reproduction is costly in the young (not done developing) and old (can’t maintain self)

-Clutton-Brock et al. (1982; Red deer: Behavior & ecology of two sexes; pg. 77)
Based on this figure:
A. Reproductive females are protected from disease
B. Non-reproductive females don’t die
C. Reproduction in red deer increases mortality rate
D. Bambi’s mom wasn’t going to make it anyway
 How Often Should an Individual Reproduce?

west/britishcolumbia-south/britishcolumbia-south.html
Parity = how often an individual reproduces

www.salmonatlas.com/pacific-salmon/canada-
Semelparity
Individuals of the same species can breed only
once in its lifetime
e.g., a Pacific salmon: long trip from ocean to
spawning stream - breed and die

Iteroparity:

www.salmonatlas.com/atlanticsalmon/canada-
Individuals of the same species can breed more than
once in its lifetime
e.g., Atlantic salmon: short trip from ocean to

east/labrador/labrador.html
spawning stream - return to ocean after breeding
 Does Evolution Favour Larger Organisms?

Drosophila melanogaster

Fecundity (ability to make many
offspring) increases with body size
Large female - advantage to delaying sexual
maturity until larger

Small female

Roff (1981; American Naturalist 118:405)
A Tradeoff Between Mating and Lifespan
Female Fruit Flies (Drosophila)
A = normal & mated
B = no ovaries (no eggs)
C = virgins
D = mated, but sterilized

Females that laid eggs
had shorter lifespans

Maynard Smith (1958; Journal of Experimental Biology 35:832-842)
A Tradeoff Between Mating and Lifespan
Male Fruit Flies (Drosophila)
housed Inseminated ♀ won't
with mate with males
♀

males housed with virgin
females reproduce and have
shorter lifespans

housed Also larger males live longer
♂

with
♀

-Partridge & Farquhar (1981; Nature 294:580)
 Predation affects life history traits
Example of an environment affecting life history traits:
Trinidadian guppies and predation
Guppies Predator – pike cichlids

http://animaldiversity.org
higher pond elevation
fewer predators
larger guppy size at
reproduction
http://labs.eeb.utoronto.ca/rodd/images/patternvariation.jpg

lower pond elevation
more predators
smaller guppy size at
reproduction
 Predation affects life history traits
Example of an environment affecting life history traits:
Trinidadian guppies and predation

Size at reproduction (mm)

High Med. Low High Med. Low

Predation Level
 Nematode (C. elegans)
How Long to Live?

commons.wikimedia.org/wiki/File:Caenorhabditis_elegans.jpg
-Kenyon et al. (1993; Nature 366:461)
 Why not live forever?
In the same environment, introduce nematodes (half wild type, half daf-2 mutants).
Follow the frequency of daf-2 allele over time (generations)

-Jenkins et al. (2004; Proceedings of the Royal Society B 271:2523)
A human, Bob, has 3 children over the course of 6 years. Bob’s
sister, Jane, only has one child. Based on this information Jane
would be considered:

A. Semelparous
B. Iteroparous
C. Heterolithoparous
D. Lonely
 Life History Strategies Form a Continuum

r-Selected K-Selected
(r-Strategists) (K-Strategists)

K-Selected Species
r-Selected Species
Small offspring/adult size Large offspring/adult size
Early sexual maturity Late sexual maturity
Semelparous Iteroparous
High fecundity (lots of offspring) Low fecundity (few offspring)
Low parental investment High parental investment
Low juvenile survivorship High juvenile survivorship
Short lifespan Long lifespan
Evolved to reproduce quickly Evolved to compete
 Life History Tables - How do we know if r or K?
Summarize information on age structure, size, life-history
(reproductive) stage, and survivorship of a population
Used to predict how a population will change over time
Useful in managing:
Crops and livestock (farming planning)

Conservation efforts (captive breeding programs)

Pest/weed control

etc…
 Age Structure Pyramids
Snapshot of a particular point in time

F 29.23a
Age Structure Pyramids: Example
 Life History Tables
Follow a particular cohort through time
x (years) nx sx lx mx lx mx
0 72 0.375 1.0 0 0
1 27 0.667 0.375 1.8 0.675
2 18 0.278 0.250 2.1 0.525
3 5 0.800 0.069 1.8 0.124
4 4 0.750 0.056 5 0.280
5 3 0.667 0.042 4 0.168
6 2 0 0.028 0 0
7 0 - 0 0 0
R0 1.772
Data from: Smith (1988; in Lifetime Reproductive Success; Clutton-Brock (ed.))
x – age
nx – # of females at each age (x) in your cohort
sx – survival rate from one age to the next
lx – survivorship (fraction of original cohort still alive)
mx – fecundity (avg. # female offspring each living female produces) (values will be provided)
R0 – net reproductive rate (avg. # female offspring per female in cohort over the cohort’s lifespan)
 Life History Tables l x = nx
Follow a particular cohort through time n0
x (years) nx sx lx mx lx mx
l1 = 27/72
0 72 0.375 1.0 0 0
1 27 0.667 0.375 1.8 0.675
= 0.375
2 18 0.278 0.250 2.1 0.525
3 5 0.800 0.069 1.8 0.124
l4 = 4/72
4 4 0.750 0.056 5 0.280 = 0.056
5 3 0.667 0.042 4 0.168
6 2 0 0.028 0 0
7 0 - 0 0 0
R0 1.772
Data from: Smith (1988; in Lifetime Reproductive Success; Clutton-Brock (ed.))
x – age
nx – # of females at each age (x) in your cohort
sx – survival rate from one age to the next
lx – survivorship (fraction of original cohort still alive)
mx – fecundity (avg. # female offspring each living female produces) (values will be provided)
R0 – net reproductive rate (avg. # female offspring per female in cohort over the cohort’s lifespan)
 Life History Tables l x = nx
Follow a particular cohort through time n0
x (years) nx sx lx mx lx mx
l1 = 27/72
0 72 0.375 1.0 0 0
1 27 0.667 0.375 1.8 0.675
= 0.375
2 18 0.278 0.250 2.1 0.525
3 5 0.800 0.069 1.8 0.124
l4 = 4/72
4 4 0.750 0.056 5 0.280 = 0.056
5 3 0.667 0.042 4 0.168
6 2 0 0.028 0 0
7 0 - 0 0 0
R0 1.772
Data from: Smith (1988; in Lifetime Reproductive Success; Clutton-Brock (ed.))
x – age
nx – # of females at each age (x) in your cohort
sx – survival rate from one age to the next
lx – survivorship (fraction of original cohort still alive)
mx – fecundity (avg. # female offspring each living female produces) (values will be provided)
R0 – net reproductive rate (avg. # female offspring per female in cohort over the cohort’s lifespan)
 sx = nx+1 Life History Tables l x = nx
nx Follow a particular cohort through time n0
x (years) nx sx lx mx lx mx
s0 = 27/72 l1 = 27/72
0 72 0.375 1.0 0 0
= 0.375 1 27 0.667 0.375 1.8 0.675
= 0.375
2 18 0.278 0.250 2.1 0.525
s1 = 18/27 3 5 0.800 0.069 1.8 0.124
l4 = 4/72
= 0.667 4 4 0.750 0.056 5 0.280 = 0.056
5 3 0.667 0.042 4 0.168
6 2 0 0.028 0 0
7 0 - 0 0 0
R0 1.772
Data from: Smith (1988; in Lifetime Reproductive Success; Clutton-Brock (ed.))
x – age
nx – # of females at each age (x) in your cohort
sx – survival rate from one age to the next
lx – survivorship (fraction of original cohort still alive)
mx – fecundity (avg. # female offspring each living female produces) (values will be provided)
R0 – net reproductive rate (avg. # female offspring per female in cohort over the cohort’s lifespan)
 sx = nx+1 Life History Tables l x = nx
nx Follow a particular cohort through time n0
x (years) nx sx lx mx lx mx
s0 = 27/72 l1 = 27/72
0 72 0.375 1.0 0 0
= 0.375 1 27 0.667 0.375 1.8 0.675
= 0.375
2 18 0.278 0.250 2.1 0.525
s1 = 18/27 3 5 0.800 0.069 1.8 0.124
l4 = 4/72
= 0.667 4 4 0.750 0.056 5 0.280 = 0.056
5 3 0.667 0.042 4 0.168
6 2 0 0.028 0 0
7 0 - 0 0 0
R0 1.772
Data from: Smith (1988; in Lifetime Reproductive Success; Clutton-Brock (ed.))
x – age
nx – # of females at each age (x) in your cohort
sx – survival rate from one age to the next
lx – survivorship (fraction of original cohort still alive)
mx – fecundity (avg. # female offspring each living female produces) (values will be provided)
R0 – net reproductive rate (avg. # female offspring per female in cohort over the cohort’s lifespan)
 sx = nx+1 Life History Tables l x = nx
nx Follow a particular cohort through time n0
x (years) nx sx lx mx lx mx
s0 = 27/72 l1 = 27/72
0 72 0.375 1.0 0 0
= 0.375 1 27 0.667 0.375 1.8 0.675
= 0.375
2 18 0.278 0.250 2.1 0.525
s1 = 18/27 3 5 0.800 0.069 1.8 0.124
l4 = 4/72
= 0.667 4 4 0.750 0.056 5 0.280 = 0.056
5 3 0.667 0.042 4 0.168
6 2 0 0.028 0 0
7 0 - 0 0 0
R0 1.772
Data from: Smith (1988; in Lifetime Reproductive Success; Clutton-Brock (ed.))
x – age
nx – # of females at each age (x) in your cohort
sx – survival rate from one age to the next R 0 = Σ(l x *mx )
lx – survivorship (fraction of original cohort still alive)
mx – fecundity (avg. # female offspring each living female produces) (values will be provided)
R0 – net reproductive rate (avg. # female offspring per female in cohort over the cohort’s lifespan)
 sx = nx+1 Life History Tables l x = nx
nx Follow a particular cohort through time n0
x (years) nx sx lx mx lx mx
s0 = 27/72 l1 = 27/72
0 72 0.375 1.0 0 0
= 0.375 1 27 0.667 0.375 1.8 0.675
= 0.375
2 18 0.278 0.250 2.1 0.525
s1 = 18/27 3 5 0.800 0.069 1.8 0.124
l4 = 4/72
= 0.667 4 4 0.750 0.056 5 0.280 = 0.056
5 3 0.667 0.042 4 0.168
6 2 0 0.028 0 0
7 0 - 0 0 0
R0 1.772
Data from: Smith (1988; in Lifetime Reproductive Success; Clutton-Brock (ed.))
x – age
nx – # of females at each age (x) in your cohort
sx – survival rate from one age to the next R 0 = Σ(l x *mx )
lx – survivorship (fraction of original cohort still alive)
mx – fecundity (avg. # female offspring each living female produces) (values will be provided)
R0 – net reproductive rate (avg. # female offspring per female in cohort over the cohort’s lifespan)
If R0 < 1, population is decreasing; if R0 > 1, pop is increasing; if R0 = 1, stable
What is the survival rate (sx) at year 1 (s1)?

A. 100% (1.0) x (years) nx
0 20
B. 75% (0.75)
1 15
2 5
C. 67% (0.67) 3 0

D. 33% (0.33)
E. 25% (0.25)
 The population size for this species is:

x (months) nx sx lx mx lx mx
0 1187 0.55 1.00 0 0.00
1 653 0.40 0.55 0 0.00
2 261 0.18 0.22 2.2 0.484
3 47 0.00 0.04 13 0.52
4 0 - 0.00 0 0.00
R0 1.004

A. Increasing (getting larger)
B. Remaining relatively stable (staying ~ the same size)
C. Decreasing (getting smaller)
D. Extinct
 This population is:
x (months) nx sx lx mx lx mx
0 1187 0.55 1.00 0 0.00
1 653 0.40 0.55 0 0.00
2 261 0.18 0.22 2.2 0.484
3 47 0.00 0.04 13 0.52
4 0 - 0.00 0 0.00
R0 1.004

A. Increasing (getting larger)
B. Remaining relatively stable (staying ~ the same size)
C. Decreasing (getting smaller)
D. Extinct
 Life History Tables

Survival rate Survivorship
(sx) (lx)

Table 26.1
 Survivorship Curves (made from life history tables)

LOG
scale
F 29.7

Type I Type II Type III
Low mortality until end of life
large animals, few young
high parental care, high
juvenile survivorship
K-selected
 Survivorship Curves (made from life history tables)

LOG
scale
F 29.7

Type I Type II Type III
Low mortality until end of life Constant rate of
large animals, few young mortality throughout the
high parental care, high lifespan
juvenile survivorship mix of r & K traits
K-selected
 Survivorship Curves (made from life history tables)

LOG
scale
F 29.7

Type I Type II Type III
Low mortality until end of life Constant rate of low juvenile surviorship
large animals, few young mortality throughout the Mortality rate decreases
high parental care, high lifespan with age
juvenile survivorship mix of r & K traits r-selected
K-selected
 How to Detect Constant Mortality
(Type 2 survivorship)

% Surviving
5%

Log
25%

50%

On linear scale, constant mortality looks like a Type 3 curve…
On log (ln) scale, constant mortality looks like it should (Type 2)

50% = 50, 25, 12.5, 6.25
25% = 75, 56, 42
5% = 95, 90, 86
 Patterns of Survivorship
(from sparrow life history table)
80

"Melospiza melodia 01450t" by Walter Siegmund
Number of individuals alive (nx)
60

40 Log (nx)

20

Age (y)
0
0 2 4 6

Age (years)

Linear scale Log scale
The mortality rate of organisms following a Type III
Survivorship Curve is:

A. Fairly constant throughout life
B. Higher in post-reproductive years
C. Lower as the organisms become older
D. Unrelated to age
 Learning Objectives:
1. Explain why energy is needed for growth (e.g., synthesis of new tissues, repair and
reproduction)
2. Define “life history”; explain how and why life history strategies vary among species
and even within populations. Recognize how life history traits co-vary across species,
often along a continuum associated with r and K selection strategies
3. Be able to interpret life tables and survivorship curves; describe the three types of
survivorship curves and provide an example of an organism exhibiting each type of
curve
4. Explain what is meant by a life-history tradeoff: interpret data in terms of
costs/benefits and tradeoffs between current reproduction and other uses of energy.
Recognize that the optimal resolution of these tradeoffs determine life history traits
such as: when to start breeding, how often to breed, how much to invest in each
offspring, and how long to live