BIO120 Fall 2024 Plant Ecophysiology Lecture Notes PDF

Summary

These lecture notes cover plant ecophysiology, focusing on plant adaptations to different environments. The lecture details various plant strategies for survival in different climates, from deserts to rainforests. Detailed discussion about photosynthesis, transpiration, and water conservation are presented.

Full Transcript

Lecture 16: Plant ecophysiology
Plants can’t evade stress by moving
But they can make their own food; they are
(mostly) autotrophs
Photosynthesis requires light, CO2, and water,
and also a reasonable temperature
Leaf, stem, and root traits reflect adaptation to
their environments, with examples of
adaptations in desert plants
Epiphytes in rainforests

1

© BIO120 Fall 2024
 Stigma
(receives
Anthers pollen)
(bear
pollen)

earth.com
2

© BIO120 Fall 2024
Like animals, plants are
extraordinarily diverse
in form and function

3

© BIO120 Fall 2024
Physiological ecology is different
for plants because they are:
Sessile, with little scope for behaviour; animals
can escape adverse conditions, but plants must
tolerate them
Autotrophic; they make their own food through
photosynthesis
All plants need the same few things to grow:
light, CO2, water, and soil nutrients (especially
nitrogen, phosphorus, and potassium, or NPK)

4

© BIO120 Fall 2024
Photosynthesis: a quick refresher
Photosynthesis
Light
CO2 + H2O Carbohydrate + O2
ATP energy
Respiration
Plants must bring together CO2, water, and light
in functioning photosynthetic tissues
Enzymes also require an OK temperature
For growth, plants have to acquire more carbon
through photosynthesis than they lose through
respiration; carbon balance is therefore key
5

© BIO120 Fall 2024
 Net primary productivity (NPP)
C gained via photosynthesis – C lost via respiration = NPP

6

© BIO120 Fall 2024
Photosynthetic structures embody
adaptation to environmental stresses
Photosynthetic
(green) structures
are usually leaves
(but can be stems)
Plants take in CO2
through stomata

evolution.berkeley.edu
But plants also
transpire; they
lose water through
stomata (singular
stoma)
7
© BIO120 Fall 2024
Photosynthetic structures embody
adaptation to environmental stresses
Leaf size and shape: SA:V ratios important
again
Benefits of large leaf surface area: good for
harvesting light, CO2
Costs of large leaf surface area: bad for
overheating, water loss by transpiration
through stomata

8

© BIO120 Fall 2024
How do plants cope with
overheating/water loss?
Most plants fix carbon by C3 photosynthesis
Rubisco is the enzyme that accepts CO2
But at high temperatures, Rubisco often captures
O2 instead of CO2, which is bad for plants
(“photorespiration”)
Some plants have evolved:
C4 photosynthesis: the enzyme PEP carboxylase
first accepts CO2, reducing photorespiration
CAM photosynthesis: plants close stomata during
the day to reduce water loss, open stomata at
night to let in CO2; photosynthesis still needs
light, so they store CO2 as malate until daytime

9

© BIO120 Fall 2024
 Plants with large leaves also
combat overheating by:
Growing in shady habitats
Evaporative cooling by opening stomata
www.isv.cnrs-gif.fr/jg/images/stomata.jpg

10
© BIO120 Fall 2024
 Evaporative cooling needs plentiful water—
not always available. Plants with large leaves
combat water loss by:
Closing stomata…
…but that shuts off all gas exchange, including
CO2 input, so photosynthesis shuts down. Plant
stops growing…
…and risks overheating & tissue damage
Therefore, fundamental trade-off between water
conservation and rapid growth
Consequences most obvious in desert plants

11
© BIO120 Fall 2024
Keeping cool while conserving water:
Sonoran Desert, Arizona
As little as ~75mm a year of rain
Summer temperatures often over 40 ° C and can reach 48 °C

A cactus doesn’t live in the desert because it likes the
desert; it lives there because the desert hasn’t killed it yet.
Any plant that you find growing in the desert will grow a lot
better if you take it out of the desert. The desert is like a lot
of lousy neighborhoods: nobody living there can afford to
move. Too little water, too much light, temperature too high:
the desert has all of these inconveniences ratcheted up to
their extremes. Biologists don’t much study the desert, since
plants represent three things to human society: food,
medicine, and wood. You’ll never get any of those things
from the desert. Thus a desert botanist is a rare scientist
indeed …” -- Hope Jahren, Lab Girl 12
© BIO120 Fall 2024
Palo Verde (Parkinsonia sp.)

13
© BIO120 Fall 2024
Palo Verde = “green stick”
Photosynthetic bark on trunks & branches; can grow without
incurring heat load & water loss through leaves

14
© BIO120 Fall 2024
Microphylly in Palo Verde

15
© BIO120 Fall 2024
 Leaves in tropical rainforests vs deserts

Tropical rainforests: Deserts:
warm and wet hot and dry
(leaves so big they (tiny leaves)
can be used as
umbrellas)
louandadventure.wordpress.com

16

© BIO120 Fall 2024
 17

© BIO120 Fall 2024
Getting rid of leaves entirely: cacti

Microphylly taken to extremes: no leaves!
Santa Rita prickly pear (Opuntia santa-rita)
18
© BIO120 Fall 2024
Episodic patterns of H2O availability in Sonoran
desert: Rillito River, Tucson, Arizona

19
© BIO120 Fall 2024
Saguaro cactus (Carnegiea gigantea)
Restricted to Sonoran desert, adapted to episodic rains

Grows to 15 m,
200 yr, 5+ tonnes
CAM photosynthesis
Extensive, shallow roots
Accordion-pleated trunk
allows expansion
Can absorb 800 L of water
from one storm, use it
gradually for growth
Mnemonic digression for
water storage: David
Grundman (d. 1982)

20
© BIO120 Fall 2024
Cacti: extensive but shallow roots

21
© BIO120 Fall 2024
 Tropical trees: also extensive but
shallow roots (for a different reason)
Tropical rainforests have a shallow layer of nutrient-rich soil
Extensive, shallow roots are an adaptation to acquire scarce
nutrients (phosphorus, nitrogen, etc.)
Photo: Marisa Ishimatsu

22

© BIO120 Fall 2024
 Root “foraging”
Legume species
(Medicago
truncatula)

Split-root
experiment

Rebecca Low N High N
Doyle
23

© BIO120 Fall 2024
Legumes also
“search” for “Bad”
nitrogen-fixing bacteria “Good”
bacteria in soil bacteria
24

© BIO120 Fall 2024
Roots “forage” for both nitrogen and symbionts

Rebecca
Adapted from Batstone et al. (2017, New Phytol.)
Batstone
25

© BIO120 Fall 2024
 Animals can evade stress through
behaviour: what about plants?
Do plants have behaviour?
Deciduous habit: dropping leaves during dry or cold
seasons reduces water stress and tissue damage
Tropical Dry season Rainy season
dry forest,
Guanacaste,
Costa Rica
Photo: www.gdfcf.org

26
© BIO120 Fall 2024
Leaf shape also influences gas exchange through
laminar vs. turbulent air flow over surfaces
More laminar flow
Vehicles are
designed to
minimize
turbulence

More turbulent flow
But for cooling
leaves, more
turbulence is
better!

27
© BIO120 Fall 2024
 Morphological plasticity: sun and shade
leaves from one red oak tree
More laminar flow, More turbulence,
less cooling better cooling
Photo: Lucy Hutyra

Shade leaf Sun leaf
28
© BIO120 Fall 2024
 Monstera deliciosa, sun and shade leaves:
dissected outlines cause turbulent airflow

Wikimedia
brittanica

29
© BIO120 Fall 2024
 Recursive digression: Convective
cooling aided by turbulence

Cool!

www.pestproducts.com
Art Wolfe

Lepus arcticus Lepus californicus
30
© BIO120 Fall 2024
Contemporary art meets convergent
evolution: many of these are not cacti!

Martin Creed: Work No. 960, 2008. Cactus plants. 13 parts, dimensions
variable. Courtesy of the artist and Gavin Brown’s enterprise, New York.
Installation view, Martin Creed Plays Chicago, MCA Chicago, 2012. Photo:
Nathan Keay, © MCA Chicago. 31

© BIO120 Fall 2024
 Cactaceae Asteraceae Asclepiadaceae Euphorbiaceae
Cactus family Daisy family Milkweed family Spurge family

32

© BIO120 Fall 2024
Can plants in rainforests be water
stressed? Yes, if they’re epiphytes

Bromeliad “tank” epiphytes,
National Geographic 33
© BIO120 Fall 2024
 Epiphytes grow on trees,
so they aren’t able to put
their roots into the soil,
leading to water stress
and nutrient shortages
34

© BIO120 Fall 2024
 35

© BIO120 Fall 2024
Epiphytic Rhipsalis cactus, Brazil: cacti are “pre-adapted” to epiphytic
36 life
© BIO120 Fall 2024
 Lecture 16– Key things to know

Topics & concepts – photosynthesis,
transpiration, net primary productivity, trade-off
between water conservation and growth, stomata,
how different environments select on leaf size and
shape, microphylly, root foraging, deciduousness,
convergent evolution, epiphyte

37

© BIO120 Fall 2024