General Biology Unit 6: Interactions of Organisms and Environment PDF

Summary

This document is a unit from a general biology course on interactions of organisms and the environment. It covers topics such as environmental biology, ecosystem functions, interactions between organisms and the environment, along with human impacts and conservation. The course sections include environmental biology, ecosystem function, interactions among different groups of organisms, the effects of human activity, applied ecology and the concept of conservation biology.

Full Transcript

General Biology (2303107)
1/2024

Unit 6: Interactions
of organisms and
environment

Varanya Aranyavalai, PhD (sec 1)
[email protected]

Chawatat Thanoosing, PhD (sec 2)
[email protected]
Unit 6: Interactions of organisms and environment

6.1 Environmental Biology
6.2 Ecosystem function and energy in the ecosystem
6.3 Interaction within the same group of organisms
6.4 Interaction with others of different groups
6.5 Organisms in different levels interact with the environment as a whole
6.6 Effects of human on ecosystems
6.7 Applied ecology and conservation biology
6.1 Environmental Biology
Environmental Biology

Ecology + the study of
human impacts on the
environment,
conservation efforts, and
environmental policy

Harmonized green space in
Luxembourg City
 What is Ecology?
Ene
Ecology = Oikos + Logos

Ecology is the scientific study of
interactions between organisms
and the environment

These interactions determine the
M 180.
distribution of organisms and their
d egesabundance.

Observation and experimentation
 Levels of ecological organization

Biosphere -> Global ecology
Biome
Landscape -> Landscape ecology
Ecosystem -> Ecosystem ecology
Community -> Community ecology
Population-> Population ecology
Individual -> Organismal ecology
*

(including behavioral ecology)
https://ecologyproject10.weebly.com/uploads/2/8/7/9/28792783/486911175.gif?499
 Kangaroos/km2 Climate in northern Australia
is hot and wet, with seasonal
> 20 drought.
10–20
5–10

1–5
0.1–1
< 0.1
Red kangaroos
Limits of
occur in most
distribution
semiarid and arid
regions of the
interior, where
precipitation is
relatively low and
variable from
year to year.

Southeastern Australia
has a wet, cool climate.
Southern Australia has
cool, moist winters and
warm, dry summers.
Tasmania
 1 66578 M Mor ?)
Dispersal and distribution..

-18009agval8image sizens
Distribution Dispersal is the movement of
dispersal individuals or gametes away from the
the center of high population density
or from their area of origin
Dispersal contributes to the global
distribution of organisms. Kangaroos/km2

> 20
Climate in northern Australia
is hot and wet, with seasonal
drought.
10–20

Species distributions are the result of 5–10

1–5

ecological and evolutionary 0.1–1
< 0.1

interactions through time
Red kangaroos
Limits of
occur in most
distribution
semiarid and arid
regions of the
interior, where
precipitation is

Evolutionary time spans many generations
relatively low and
variable from
year to year.

and captures adaptation through natural
selection Brigid
Both biotic and abiotic factors influence Southeastern Australia

species distribution
has a wet, cool climate.
Southern Australia has
cool, moist winters and
warm, dry summers.
Tasmania
What is environment?

Living things & non-living things
Biotic factors & abiotic factors

Types of environment
69g
Regulators or conditions
(e.g. Temperature, pH, Salinity,
Predators, Parasites, etc.)
Resources
(e.g. Sunlight, oxygen, CO2,
nutrients)
Biotic factors
ge

All of the organisms in an area
or the living components of
the environment.

Biotic factors that affect the
distribution of organisms may
include: Predation, Herbivory,
Competition, Mutualism,
Parasitism
Abiotic factors
The environment’s nonliving
component, the physical and
chemical factors.
Abiotic factors affect the
distribution of organisms, for
example, Temperature, Water,
Oxygen, Salinity, Sunlight, Rocks,
and Soil.
Abiotic factors vary in space and
time.
https://library.88guru.com/wp-content/uploads/2022/11/Abiotic-factor.png
 Temperature
Temperature is an important
factor in the distribution of
organisms because of its effects
on biological processes
Cells may freeze and rupture
below 0°C, while most proteins
bette denature above 45°C
&ge
Mammals and birds expend
energy to regulate their internal
temperature (Endotherm)
d.88
 Figure 52.7 Current range and predicted ranges for the American beech
under two climate-change scenarios
Distribution and
phenological patterns of
organisms can be changed
due to climate change.

Species that have difficulty
dispersing may have smaller
ranges or could become
extinct.
(a) Current range (b) 4.5C warming (c) 6.5C warming
over next century over next century

© 2014 Pearson Education, Inc.
Sunlight
Light intensity and quality
(wavelength) affect photosynthesis.
Shading by leaves makes competition
for light intense on the forest floor.
Water absorbs light; as a result, in
aquatic environments, most
photosynthesis occurs near the
surface.
In deserts, high light levels increase
temperature and can stress plants
and animals.

Diel vertical migration (DVM)
Water and oxygen
Water availability in habitats is
another important factor in
species distribution.
Desert organisms exhibit
adaptations for water
conservation.
Water affects oxygen availability
as oxygen diffuses slowly in
water.
Oxygen concentrations can be
low in deep oceans and deep https://www.nps.gov/orpi/learn/nature/images/Merriam-s_Kangaroo_Rat_Chihuahuan_Desert_New_Mexico_cropped.jpg

lakes. Kangaroo rats in the desert lose little water and can recover 90%
of the loss from metabolic water (long loop of Henle).
Salinity
Salt concentration affects
the water balance of
organisms through osmosis
(osmoregulation).
Most aquatic organisms
are restricted to either
freshwater or saltwater
habitats.
Few terrestrial organisms
are adapted to high-
salinity habitats.
 Wind
Wind is considered an
important factor in flat
plains, sea coasts, and
high altitude mountains.

Wind affects plant
7518889We transpiration, shape,

pollination, and seed
white8096gnd dispersion.
& 1666

https://www.treehugger.com/thmb/6T9KbIU8Yn4dCyOCd3QQjA1hgIM=/1500x0/filters:no_upscale():max_bytes(150000):strip_icc()/Lead-
8ba060bb458d4011a5547edd2ed659c3.jpg
Rocks and Soil
Many characteristics of
soil limit the distribution
of plants and thus the
animals that feed on
them.

Physical structure
pH
Mineral composition

https://qph.cf2.quoracdn.net/main-qimg-ec119c87a59ba24c04af2d2cbc811c30-lq
Can you identify the
biotic and abiotic
factors in this picture?
Climate and seasonality
Four major abiotic components of
climate are temperature,
precipitation, sunlight, and wind.
Macroclimate consists of patterns on the
global, regional, and landscape level
Microclimate consists of very fine
patterns, such as those encountered by
the community of organisms underneath
a fallen log.
Seasonal variations of light and
temperature increase steadily toward
the poles and control the phenology of
organisms.
Climate is very important in
determining why terrestrial biomes
are found in certain areas.
Biomes
Biomes are major life zones characterized by vegetation type (terrestrial biomes)
or physical environment (aquatic biomes).

Terrestrial biomes
6.2 Ecosystem function and energy in the
ecosystem
What is an ecosystem?
An ecosystem consists of all the
organisms living in a community,
as well as the abiotic factors with
which they interact.

Regardless of an ecosystem’s
size, its dynamics involve two
main processes: energy flow and
chemical cycling.
Ecosystem function
The various biological,
geochemical, and physical
processes within an ecosystem
contribute to its overall health,
productivity, and stability.
Ecosystem function to ecosystem services
Biodiversity, Ecosystem Functioning, Resilience, and Ecosystem Services 57
Ecosystem service: The benefits
that humans derive from
ecosystems.

Figure 1 Categories (UNEP, 2005) and examples of ecosystem services (Daily, 1997;
Daily et al., 2000; Malmqvist and Rundle, 2002; UNEP, 2005), according to the Millennium
Ecosystem Assessment framework.
(Song et al., 2014)
(Truchy et al., 2015)
25
disturbances (Frainer and McKie, 2015; Wardle and Jonsson, 2014). Insights
Ecosystem services
entston 1568 26 we
Provisioning services
Food & resources
Food production,
medicine, freshwater
Ecosystem services
M dis grade
Regulating services.

Maintain environmental
conditions and regulate
natural process
Climate regulation, clean
air, soil erosion control,
Pollination
Ecosystem services
n fontsanzigersseg

Cultural services
Cultural heritage, recreation,
aesthetic enjoyment,
education, tourism

https://mpics.mgronline.com/pics/Images/567000008718702.JPEG
Ecosystem services
n Wonsangie site sig
Supporting services.

Maintain all services
Fundamental ecosystem
processes, including soil
formation, nutrient cycling,
primary production, and
habitat formation.

https://media.geeksforgeeks.org/wp-content/uploads/20230207152946/Carbon-
Cycle.png
Energy transfer
Conservation of Energy: 1st law
of thermodynamics states that
energy cannot be created or
destroyed, only transformed.
Energy enters an ecosystem as
solar radiation, is conserved,
and is lost from organisms as
heat.
The second law of
thermodynamics states that every
exchange of energy increases the
entropy of the universe.
In an ecosystem, energy
conversions are not completely
efficient, and some energy is https://media.geeksforgeeks.org/wp-content/uploads/20230612102721/Energy-flow.png
always lost as heat.
Components and structure
The trophic structure of a
community is determined by
the feeding relationships
between organisms.
The transfer of food energy
from its source in
photosynthetic organisms
(Autotrophs) through
herbivores and carnivores
(heterotrophs) is called the
food chain.
 gene9156688 in
Grazing Food chain
Energy and nutrients
pass from primary
producers (autotrophs)
to primary consumers
(herbivores) to
secondary consumers
(carnivores) to tertiary
consumers (carnivores
that feed on other
carnivores).
 · 9519915genizing
Detritus Food Chain
Detritivores, or decomposers, are consumers that derive their energy from
detritus, non-living organic matter.
Trophic efficiency
Trophic efficiency is the percentage of
production transferred from one trophic
level to the next.
It is usually about 10%, with a range of
5% to 20%.
Pyramid of energy
Ecological pyramid
A pyramid of net
production represents the #

loss of energy with each
transfer in a food chain.
Most biomass pyramids
show a sharp decrease at
successively higher
trophic levels.
Certain aquatic
ecosystems have inverted
biomass pyramids.
Khan Academy
 Food Web
Food web
All food chains in an ecosystem.
Complicated
Food Web

Food
Chains
Bioaccumulation
The increasing concentration of a substance over time.

https://www.cattermoleconsulting.com/wp/wp-content/uploads/2023/01/bioaccumulation-vs-biomagnification-toxic-poisoning-process-outline-diagram.jpg_s1024x1024wisk20cVBUCRalaOqfnTHL9R387DgvedO7FS8B_dhLPsjxlj9Y-830x250.jpg
Biological magnification
Biomagnification
The increasing concentration of a
substance, such as a toxic chemical,
in the tissues of organisms at
 “The increasing concentration of a
successively higher levels
substance, such in
as aa food
toxic chemical, in
chain. the tissues of organisms at successively
higher levels in a food chain. As a
Organismsresult
at theoftop of the food organisms
biomagnification,
chain generally
at thesuffer
top ofgreater
the foodharm
chain generally
from a persistent toxin orharm
suffer greater pollutant
from a persistent
than thosetoxin
at lower levels. than those at lower
or pollutant
levels.”
Microplastics: Trouble in the Food Chain
(UNEP Frontiers 2016 Report)

- Biomagnification of DDT in a Long Island
(USA) salt marsh

56
6.3 Interaction within the same group of
organisms
 What is a population?
Population = the number of
organisms of the same species
that live in a geographic area at
the same time, with the
capability of interbreeding.

Population ecology = study of
the processes that affect the
distribution and abundance
of populations.
Population characteristics
Density & Dispersion

Population density = the number of individuals per unit area or
volume.

Population dispersion = the pattern of the spacing of individuals
in a population
Population density
Density is the result of an
interplay between processes
that add individuals to a
population (birth &
immigration) and those that
remove individuals (death &
emigration).

Population size (N)
Measure population density
In most cases, it is impractical or
impossible to count all individuals in a
population.

The sampling technique can be used
to estimate densities and total
population sizes.

Population size can be estimated by
Vege
either extrapolation from small
M.

samples, an index of population size
(e.g., number of nests), or the mark-
recapture method. https://thepopularflamingo.com/cdn/shop/articles/Shutterstock_590549576.jpg?v=1654901796
https://a-z-animals.com/media/2018/09/Flamingo-African.jpg
Sampling method: Quadrat sampling
organisms in the sampling areas
are counted directly,

We set a boundary of a sampling
area, for example, in a square
shape (1x1m, 5x5m, etc.).
Sampling method: Mark-Recapture Method
Scientists capture, tag, and release a random
sample of individual (s) in a population.

Marked individuals are given time to mix back
into the population.

Scientists capture a second sample of
individuals (n) and note how many of them
are marked (x)

Population size (N) is estimated by:
Demography
Demography = The study of the
vital statistics of a population and
how they change over time.

https://static.bangkokpost.com/media/content/20220221/4234731.jpg
 Age structure
Age structure of Japan's population 1950, 2000 and 2050.
Age structure is the
relative number of
individuals of each age.
The ratio of each
population
Pre-reproductive stage
Reproductive stage
Post-reproductive stage
Sex ratio
Age structure diagrams
can reveal a population’s
growth trends and can
point to future social
conditions. https://www.researchgate.net/profile/Thomas-Feldhoff/publication/304186655/figure/fig1/AS:375392608243712@1466511980551/Age-structure-of-Japans-population-1950-2000-and-
2050-Source-IPSS-2006a-12-own_W640.jpg
Age structure diagram

Prospects and Contexts of Demographic Transitions

https://cdn.kastatic.org/ka-perseus-images/48892870bdfc7e7ae1e39b9238597b9b95744495.png
Figure 6: Changing age structure of Thai population

Male Female

Changing age structure of Thai population (Prasertkul et al., 2019)
Sources: Calculated from population census, 1970, 1990 and 2010 and population projection for Thailand, 2010-
Social behavoir
digWashing80 Eigeeid
Intraspecific interaction.

between two individuals or
more.
Aggression
Cooperative
Courting and mating
Raising progeny
Altruism

https://images.nationalgeographic.org/image/upload/v1638889871/EducationHub/photos/meerkat-
mob.jpg
g 81521688

Hierarchies and Territoriality Lop Buri macaques

needengag
Dominance hierarchies are
found among chickens, wolves,
primates, etc. we Weeng
Alpha: top hierarchy

Territories are maintained in
part as a means of reducing
aggressive interactions
Alarm calls
Smell
https://www.thaipbsworld.com/police-monkey-control-unit-to-deal-with-
lop-buri-macaques/
Reproductive behavior
Related to reproductive fitness
Mating choice and sexual
selection

wesee wes
Courtship behavior: facilitates
attraction and mating with the
opposite sex
Lek: communal area in which
two or more males of a species https://www.coffsgardenclub.com.au/wp-content/uploads/2019/09/satin-bowerbird-with-blue-objects.jpeg
perform courtship displays.
Satin Bowerbird
 https://www.youtube.com/watch?v=nPhVOZiPokA&ab_channel=NatGeoWILD

(Scholes & Laman, 2018)

Y

Vogelkop Superb Bird-of-Paradise
Mating system
Promiscuous: low likelihood of
subsequent mating with the same
individual ↳ge bee
Monogamous: high likelihood of
subsequent mating with one individual 1 https://live.staticflickr.com/65535/50905319456_ab730da669_b.jpg

Elephant seal’s harem
Polygamous: high likelihood of
subsequent mating with more than
one individual 688%
Polygyny: one male mates with several
females
Polyandry: one female mates with several
males
https://i.pinimg.com/originals/10/57/d9/1057d9afe54761e90fc0165c7eb1927d.jpg

Honey bee mating
6.4 Interaction with others of different
groups
Interactions between species
Community interactions are classified by whether they help, harm, or
have no effect on the species involved.

Relationships between species = interspecific interaction

Interspecific interaction can affect the fitness of each species, and the
effects can be summarized as positive (+), negative (-), or no effect
(0).

Examples: competition, predation, herbivory, symbiosis (parasitism,
mutualism, and commensalism), and facilitation
 Competition
Interspecific competition (-/- interaction)
occurs when species compete for a
resource in short supply.

Competitive exclusion (Gause 1934)
Strong competition can lead to competitive
exclusion, and local elimination of a competing
species.
The competitive exclusion principle states that two
species competing for the same limiting resource
cannot coexist in the same place,
https://s3-eu-west-1.amazonaws.com/infogram-particles-700/1606590_1411558857950.jpg
eneinnigliboine
Ecological niche
Ecological niche = the sum of a
species’s use of biotic and abiotic
resources.

https://photos.demandstudios.com/getty/article/83/209/475414879.jpg

Ecologically similar species can
coexist in a community if there are
one or more significant differences
in their niches.
 Fundamental niche: the nicheตัวอยpotentially occupied.
าง การเจริญของเพรี ยง 2 ชนิด
Realized niche: the niche actually occupied.
 ↑ 1666996bnss
การแบanswers
งปนทรัพยากร
Resource partitioning
(Resource partitioning)

Resource partitioning is the
การแบงปนทรัพยากรหมายถึ ง การแบdifferentiation ofอมของสิ
งปนทรัพยากรที่มีอยูในสิ่งแวดล ecological
่งมีชีวิตกลุมหนึniches,
่งๆ ที่อาศัย
enabling similar species
อยูในสิ่งแวดล อมนั้น to coexist in a community.
·280 6689 wasWe k beguigeelegenwenn.
 Box 3. Observing ECD in Darwin’s finches

Character displacement
In a study of Darwin’s finches, Grant and Grant documented the
evolution of ECD across one generational boundary. In 2004,
depletion of seed resources during a major drought on Daphne Major
with observational data alone (see Figure 2 in main text).

island brought the medium ground finch, Geospiza fortis, into
competition with the large ground finch, Geospiza magnirostris, for (A)
large seeds. G. fortis altered its resource use towards smaller seeds

Character displacement is a
available in the seed bank and natural selection drove evolution
towards smaller beaks that were more adept at using such seeds
Small beaked phenotype
adept at handling small seeds
tendency for characteristics
(Figure I).
The change in phenotype matched the change in resource use

to be more divergent in
(criterion 4) because the shift to smaller seeds was matched by a shift
to a functionally more efficient smaller beak size. This was an evolved
Geospiza for!s
sympatric populations of
response (criterion 1; beak size has high heritability in this population
sym-same and should respond to strong directional selection) that occurred in
(B)

patric two species than in
situ (criterion 3). Three decades of data from the years prior to the
homeland
=
2004 drought served as a control, suggesting that there were no other Large beaked phenotype

allopatric populations of the
environmental factors that could have driven the beak size shift adept at handling large seeds
allo = other(criterion 5). Three lines of evidence directly implicate resource
same two species.
competition for seeds (criterion 6): (i) during a 1977 drought, prior to
the colonization of G. magnirostris, G. fortis relied on large seeds
when small seeds were depleted, indicating that the two species can
overlap evolutionary
an in resource use; change(ii) that when 214) similar
occurs observations
behavioral
suggested that G. magnirostris fed on a much higher fraction of
species
in 2004 (C)

largeinhabit the same
seeds than environment
did G. fortis; and. (iii) during the 2004 drought, the G.
fortis population declined to a level lower than during any past G. magnirostris
drought. Of course, because this was a singular event, Grant and specialist on large seeds
Grant could not rule out the possibility that the decrease in beak
size by G. fortis during the drought in the presence of G. magnirostris
was a coincidence (criterion 2) , although the wealth of long-term
data in this study suggests that that possibility is unlikely.
TRENDS in Ecology & Evolution
What advantages did the evolution-in-action approach provide? (Stuart & Losos, 2013)
First, the population was observed evolving in real time, leaving no Figure I. Large-beaked Geospiza fortis (B) were inferior competitors to Geospiza
Predation
Predation (+/- interaction) refers to
an interaction in which one species,
the predator, kills and eats the other,
the prey.
Some feeding adaptations of
predators are claws, fangs, and
poison.
Prey displays various defensive
adaptations.
Behavioral defenses include hiding,
Red 2998 fleeing, forming herds or schools, self- https://images.ctfassets.net/4yflszkpcwkt/4QdwNUHBhKbyuewl7F3aGr/3826298e6603687a007af7ca57c

defense, and alarm calls. · a1b92/2351873.jpg

·go 10268
Mimicry 626688
Mimicry can also be used by predators to approach prey.

Wasp Moth

Müllerian mimicry Batesian mimicry
Herbivory
Herbivory (+/- interaction)
refers to an interaction in
which an herbivore eats
parts of a plant or alga.
It has led to the evolution
of plant mechanical and
chemical defense and
adaptations by herbivores.

https://bio.libretexts.org/@api/deki/files/26716/Koala.jpg?revision=1&size=bestfit&width=397&height=297
 RES EARCH | R E P O R T

Bumble bees damage plant leaves and accelerate
adjacent to a patch of 36 flowerless plants owing to weather). Bumble bee workers we
f (from six different species; see supplemen- damaged plants in our experimental patches Th
tary materials for details). The colony and throughout this phase of the experiment fro

flower producaon when pollen is scarce.verbbedi
F
plants were replaced every 3 weeks, and we (Fig. 4A); furthermore, as predicted, we ob- agi
assessed plant damage and bee activity on served a strong decline in damage by the end abi
weekdays (except when bees were inactive of April, at which point local floral resources at
tio
by
im
in
T
per
thr
sig
in
les
ava
ple
sity
far
4A
dic
da
tio
oth
les
ph
thr
flic
Fig. 1. Bombus terrestris workers damaging Solanum melongena leaves. (A) Sequential images of a B.
worker penetrating a leaf with its proboscis (taken over ~3 s). (B) A worker cutting into a leaf with its als
mandibles. (C) Characteristic bee-inflicted damage. exc

A S. lycopersicum B B. nigra
(Pashalidou et al., 2020) 80
> 40
Fig. 2.
Flower
75 nigra p
damag
(contro
70 35 confide
respon
65 plant o
 Parasitism
Parasitism (+/- interaction):
one organism (parasite) t
derives nourishment from
another organism (host), -

which is harmed in the
process.
Endoparasites: parasites that
live within the body of their
host.
Ectoparasites: parasites that
live on the external surface of
a host.
Parasites can significantly
affect the survival,
reproduction, and the density
pf their host population.
 Mutualism
Mutualistic symbiosis,
or mutualism (+/+
interaction), is an
interspecific
interaction that
benefits both species.
Efficie A mutualism can be
8203bazi Obligate, where one
=68gi species cannot survive
without the other.
donig Facultative, where
both species can
survive alone.
Commensalism Egg
Commensalism (+/0
interaction): one species
benefits and the other is
neither harmed nor
helped.
Commensal interactions
are hard to document in
nature because any close
association likely affects
both species. https://www.texomashomepage.com/wp-content/uploads/sites/41/2023/05/gettyimages-1407011932-170667a.jpg?w=1280
6.5 Organisms in different levels interact
with the environment as a whole
Biogeochemical cycles
Pathways of elements in the
environment through 3
processes:
Biological processes
Geological processes
Chemical processes
Example: water, carbon,
nitrogen, phosphorus, and
calcium.

https://www.sciencefacts.net/wp-content/uploads/2021/07/Biochemical-Cycles.jpg
Water cycle
Water is essential to all organisms
The main physical state of water is
liquid.
Oceans hold 97% of the planet's
water, while 2% is found in glaciers
and polar ice caps. Only 1% exists in
lakes, rivers, and groundwater.
Water cycles through various
processes, including evaporation,
transpiration, condensation,
precipitation, and movement through
both surface and groundwater.
Carbon cycle
Carbon-based organic molecules are
crucial for all living organisms.
Photosynthetic organisms transform CO2
into organic compounds that heterotrophs
utilize. ·.gensenessrigs westa
80

Key carbon reservoirs include fossil fuels,
soils and sediments, dissolved substances
in oceans, biomass from plants and
animals, the atmosphere, and sedimentary
rocks.
CO2 is absorbed and released through
processes such as photosynthesis,
respiration, volcanic activity, and the
combustion of fossil fuels.
 Nitrogen cycle
Nitrogen is a component of amino
acids, proteins, and nucleic acids.
The main reservoir of nitrogen is the
atmosphere (N2), though this
nitrogen must be converted to
ammonium (NH4+ ) or Nitrate (NO3– )
for uptake by plants, via nitrogen
fixation by bacteria. 21589385682
Organic nitrogen is decomposed to
NH4+ by ammonification, and NH4+ is
decomposed to NO3– by nitrification.
Denitrification converts NO3– back to
N2.
one 156sideidasdedenedezi
Phosphorus Cycle
Process
Reservoir
Phosphorus cycle
Phosphorus is a major Pathway affected by humans
constituent of nucleic acids, Natural pathway
Phosphates Phosphates
phospholipids, and ATP. in sewage in fertilizer Plate
tectonics
Phosphate (PO43−) is the most Phosphates in
mining waste Runoff Runoff
important inorganic form of Sea
phosphorus. Runoff
birds

Phosphate in
The largest reservoirs are Erosion
rock (fossil
bones,
sedimentary rocks of marine guano) Ocean food
webs
origin, the oceans, and Animals
(consumers) Phosphate Phosphate in
organisms. dissolved
in water
shallow ocean
sediments
Phosphate
Phosphate binds with soil Plants
in deep
ocean
particles, and movement is (producers) sediments

often localized.
Bacteria

54
Fig. 3-21, p. 73
Eutrophication
Nutrient over-enrichment
(phosphorus/nitrogen)
changes in biodiversity.

https://upload.wikimedia.org/wikipedia/commons/7/74/River https://scienceinfo.com/wp-content/uploads/2023/07/Eutrophication-Causes-Classification-Impacts-Process.jpg
_algae_Sichuan.jpg
6.6 Effects of human on ecosystems
 Anthropocene
“Anthropocene” = human ('anthropo’) + new ('cene’)
(Crutzen and Stoermer, 2000)

Paul J. Crutzen Eugene F. Stoermer
(1933–2021) (1934–2012)
https://n5a7d2f2.stackpathcdn.com/wp-content/uploads/2023/01/Anthropocene-Epoch-Editorial-760x475.jpg
https://media.nature.com/lw767/magazine-assets/d41586-021-00479-0/d41586-021-00479-0_18864682.jpg?as=webp 76
https://2.bp.blogspot.com/-65xe4COXdUA/W5InHPSOO5I/AAAAAAAAAlg/0sM65JgSB0gwL_C3D_zQAiaPnTmyVgVRACLcBGAs/s1600/Stoermer_2007.jpg
Global Climate Change
Shifts in temperature and weather
patterns.
Change in the biotic elements of
ecosystems leads to biotic change.
Global boiling https://media.cnn.com/api/v1/images/stellar/prod/valencia-flood-lc9-20241030-
20241008-sbs-ml-v2.jpg?c=16x9&q=h_653,w_1160,c_fill/f_webp

Valencia, Spain, 2024

“Era of global boiling has arrived”
Antonio Guterres
UN secretary general
 Trends in Ecology & Evolution

Ecological mismatch

2024

hZps://bbc.com/news/av/uk-england-london-68638854
Trends in Ecology & Evolution

Figure 2. Examples of Hypothetical Ecosystem Responses to Phenological Mismatches, Focusing on Consequences for Plant Biomass an

(Beard et al., 2019)
Quality, Carbon (C) Source and Sink Strength, and Nitrogen (N) Uptake and Cycling. In (A), delayed herbivory increases the C sink strength in vegetat
increases N demand by plants. Delayed herbivory also means longer periods without N returned to soils as feces, slowing N cycling, and potentially limiting N a
When caribou (Rangifer tarandus) arrive, they find leaf tissue of lower quality because the tissue is older and the N pool is diluted across more biomass. (B) mirrors
Habitat destruction
It is important to protect
habitat to protect
biodiversity within it.
Huge pressure from the
World’s rapidly increasing
population.
Agricultural areas,
urbanization
Pollution
Air pollution
Chemical pollution
Pesticide

hMps://i.natgeofe.com/n/87d6217b-d811-4c1b-8296-8e59195388b2/16647.jpg

https://cdn-prod.medicalnewstoday.com/content/images/articles/327/327414/a-man-spraying-pesticides-into-a-field-of-crops-that-will-be-used-for-food.jpg
https://waterborne-env.com/wp-content/uploads/2022/10/death-by-a-thousand-cuts-874x1024.jpg
Alien and Introduced species
Introduced by humans
to regions where there
are no natural
predators.
 ปลาหมอคางดำ
Sarotherodon melanotheron 83
Plas