Organismal Biology Lecture 1 PDF

Summary

This document covers lecture 1 of an organismal biology course. The lecture discusses the diversity of life, key characteristics of living organisms, and potential origins of life. It also includes details about the number of individuals of different organisms.

Full Transcript

BIO 211

Organismal Biology
 BIO 211

Lecture 1

Diversity of Life (Part A)
Yashraj Chavhan
Assistant Professor
Syllabus
What is life? What qualifies as a
living thing?
Some key characteristics of
living organisms
Organization (high order states): organisms are
made up of highly organized units called cells.

Homeostasis: Cells are bounded chambers that
interact with their external environment and
transform energy to maintain a regulated balance
of chemicals within them.

Reproduction: Organisms can make structurally
distinct copies that resemble them by making use
of an instructional (genetic) code.

Evolution: Organisms inevitably generate
variation (due to replication errors), and the
The smallest free-living organism
on Earth
Pelagibacter ubique
This bacterium is one of the most
common organisms found in the
ocean.

The combined weight of all P.
ubique bacteria outweighs all the
fish in the ocean.

A single P. ubique cell has a
volume ranging from 0.019 to 0.039
µm3.

Steindler et al. 2011 PLoS One A typical blue whale is as big as
And the blue whale may not even
be
the largest organism on the
Earth!
Two of the largest organisms on
Earth
Armillaria solidipes
(a parasitic fungus)
A single fungal individual can be
composed of a huge network of
hyphae that spans ~10 km2.

This individual is likely ~ 2400
years old.

It primarily grows underground.

Armillaria solidipes on a tree
Two of the largest organisms on
Earth
Posidonia australis
(an aquatic plant)
A single individual spans ~180
km2

© University of Western Australia / Rachel Austin
 Number of individuals

Image credit: Mark Belan Source: Bar-On et al. 2018 PNAS
Life on Earth is extremely
diverse
Size
Abundance
Habitat
Nutritional requirements and preferences
Life span
Mobility
Variability
But all life on Earth shares
some key features
There is a unity of organization in the highly
diverse living world.
Examples:
1. The genetic material: DNA
All things that can be unquestionably categorized
as “living” organisms have the same kind of
biomolecule (deoxyribonucleic acid (DNA)) as their
genetic material.

2. Fundamental information processing:
All living things transcribe DNA into RNA
(ribonucleic acid), the RNA then gets translated
into proteins. Proteins are the primary functional
building blocks of all living cells.
3. Energy currency: ATP
All living organisms use adenosine triphosphate
ATP as the energy currency of their cells.

4. The Genetic Code
Although the genetic code is not
universal, an overwhelming majority
of organisms on the planet uses the
exact same genetic code (which
contains information about how RNA
sequences are translated into protein
sequences.

Moreover, while some alternative
https://open.lib.umn.edu/evolutionbiology/chapter/5-8- genetic codes are found in very-very
We will try to understanding
life’s diversity through its
history on planet Earth
 The origin of life
The Earth is ~4.5 billion years old.

The oldest known fossils (the earliest signs of life) are
~3.7 billion years old.

The current theories state that life could have originated in
two1.different places:
Geothermal pools on land 2. Hydrothermal vents in
oceanic depths

Credit: Jeff Vanuga/Nature Picture Library Source: https://oceangeneration.org/are-hydrothermal-vents-the-origin-of-life-on-
earth/
Source: https://oceangeneration.org/are-hydrothermal-vents-the-origin-of-life-on-
A prebiotic soup, an RNA world, or
something else?
We do not exactly know how life originated.

Although there are many promising clues, the
origin of cascaded catalytic reactions remains
challenging.

RNA molecules can act as both enzymes and
replicators (they can make copies of
themselves).

But it is difficult to explain how RNA could
catalyze some of the reactions essential to
cellular metabolism.
The Last Universal Common
Ancestor
All life on the Earth
shares a common ancestor
(referred to as the Last
Universal Common Ancestor
or LUCA).

LUCA likely lived ~4.2
billion years ago and had
a genome (the sum-total of
the genetic material) with
at least 2.5 million base
pairs od DNA.

LUCA was unicellular and
prokaryotic (it did not
have a nucleus).

LUCA was anaerobic (its Source: Moody et al. 2024 Natur
 The three-domain system
Prokaryotes Eukaryotes
(cells without a nucleus) (cells with a nucleus*)

F

Image credit: Chiswick Chap
(Last Universal Common Ancestor)
LUCA would not have been alone on the Earth
~4.2 billion years ago

(Last eukaryotic common ancestor)

(Last bacterial common ancestor) (Last archaeal common ancestor)

Source: Moody et al. 2024 Nature
Prokaryotic diversity: Bacteria and
Archaea
 Prokaryotes were the
first organisms to
inhabit the Earth.

https://www.mun.ca/biology/scarr/Prokaryota_&_Eukaryota.ht
Prokaryotes existed for
billions of years before
plants and animals
appeared.

The first prokaryotes
could withstand high

Image source:
temperatures while
thriving in presence of
very little or no oxygen.

ml
Prokaryotes constitute ~14% of all
biomass on the Earth.
The prokaryotic cell
 The Metabolic Diversity of

Image source: https://bpb-us-w2.wpmucdn.com/sites.gatech.edu/dist/6/1810/files/2018/12/metabolic-
Prokaryotes
Prokaryotes can live in a vast diversity of
environments.

This is because prokaryotes can use multiple
diverse energy and carbon sources for their
metabolism:

Energy from chemical
oxidation
(organism uses chemical
reactions as the energy
source to catalyze
biochemical reactions)
 Image source: https://bpb-us-w2.wpmucdn.com/sites.gatech.edu/dist/6/1810/files/2018/12/metabolic-
It is important to note that not every bacterial
or archaeal cell has the capacity to have all
these four modes of metabolism.

Energy from chemical
oxidation
(organism uses chemical
reactions as the energy
source to catalyze
biochemical reactions)

Some prokaryotes specialize in chemoautotrophy
(e.g., Sulfolobus) while others specialize in
photoautotrophy (e.g., cyanobacteria). But
Sulfolobus is not a photoautotroph, and
Cyanobacteria are capable of
photosynthesis
Cyanobacteria have photosynthetic pigments (e.g., phycobilins
in many species, chlorophyll b in some others) which they use
to convert photonic energy (from sunlight) into chemical
energy.

Cyanobacteria
were also the
first
multicellular
living
organisms.
Credit: Epipelagic @ Wikimedia Commons Credit: Epipelagic @ Wikimedia Commons

Since such photosynthesis releases oxygen, cyanobacteria are
considered to be an important cause of the rise on
atmospheric oxygen concentrations. Such rise in atmospheric
oxygen led to the upsurge of more efficient (aerobic)
respiration, which allowed the evolution of larger and more
Our planet’s primary productivity has mostly
been cyanobacterial

Although land plants drive most of the primary carbon
fixation (conversion of inorganic carbon (CO2) to organic
forms) at present, most of the carbon fixation over the
course of our planet’s history has been done by
cyanobacteria.

Crockford et al. 2023 Curr.
Biol.
Many archaea live in extreme
environments
Organisms living in extreme environments are
called extremophiles.

For example, some archaea prefer to live in
environments with salt concentrations of 10% w/v
(~3-fold that of the oceanic salinity):

Credit: Crion @ Wikimedia Commons Credit: Grombo~commonswiki @ Wikimedia Commons
Many archaea live in extreme
environments
Some other archaea (e.g., Sulfolobus) prefer to
live in hot springs where the pH is 2–3 and the
temperatures are 75–80 °C.

This makes them acidophiles and thermophiles,
respectively.

Credit: Lascorz @ Wikimedia Commons Credit: Ser Amantio di Nicolaoi @ Wikimedia Commons
Many archaea live in extreme
environments
Some other archaea (e.g., Methanogenium frigidum)
live in the Antarctic sea ice.

This makes them psychrophiles.

Credit: Maasstev @ Microbewiki
Prokaryotes are key to biogeochemical
cycling
Prokaryotes are critical players in the biogeochemical
cycling of nitrogen, carbon and phosphorus.

Their role in the nitrogen cycle is particularly
critical for the survival of other living organisms
(i.e., eukaryotes).

Nitrogen is the building block of amino acids and
nucleotides; therefore, it is an essential component
of all organisms.

Although N2 is the most abundant gas in the
atmosphere, it cannot be used by eukaryotes in its
 Prokaryotes fix the
atmospheric N2 into
reduced forms (e.g.,
NH3).

Examples of N2 fixing
prokaryotes: soil
bacteria,
cyanobacteria, Frank
ia spp., etc.

Modified from “Nitrogen cycle” by Johann Dréo (CC BY-SA
3.0)
Prokaryotes are important agents for
bioremediation

Pic source: https://organismalbio.biosci.gatech.edu/biodiversity/prokaryotes-bacteria-
Bioremediation refers to processes that use a
biological system to remove environmental
pollutants.

Microbes have been used in the bioremediation
of pesticides, fertilizers, toxic metals, etc.

Interestingly, bacteria have been used
effectively to clean oil spills in the ocean.
Many bacteria are pathogenic
Many (but not all, not even most) bacteria cause diseases
in humans, animal, and/or plants.

Many pathogenic bacteria form biofilms, which are
ecological communities of microbes that are held together
by an extracellular matrix that is secreted by the
constituent microbes.

Biofilms are difficultSchematic
to treat with antimicrobial agents
such as antibiotics.

Source: Magdalena Kegel @ cysticfibrosisnewstoday
 Surprisingly, archaea are not known to cause
many diseases in either animals or plants.

it is possible that archaea-caused diseases are
real but just remain undiscovered or
understudies.

Another possible explanation might be that many
archaea live in extreme environments where a
larger host species may not be found.