Evolution of Algae PDF

Summary

This document discusses the evolution of algae, focusing on the development of oxygenic photosynthesis and the origins of photosynthetic eukaryotes, as well as the process of primary endosymbiosis. It explores the relationships and classifications of various types of algae.

Full Transcript

Evolution of Algae

Dr.R.D.A.Gunasekara
Department of Botany
University of Ruhuna
 The first organisms that developed oxygenic
photosynthesis are thought to have been the anoxygenic
ancestors of cyanobacteria (Allen & Martin, 2007)

Estimates based on geological and geochemical evidence
and molecular phylogenetic analyses calibrated with the
fossil record agree on a minimum age of 2.3 billion years
ago (Tomitani, Knoll, Cavanaugh, & Ohno, 2006)
 With oxygen becoming gradually available as a very
potent electron acceptor, the path lay open for aerobic
organisms to evolve.
Aerobes soon managed to maintain much more
productive ecosystems and formed more complex
organisms in the planet.
The rising atmospheric oxygen is thought to have directly
triggered cellular
2 H2O + COcompartmentalization
 and
2
eukaryogenesis. O + CH O +
2 2
H2 O
 Origin of Plastids: Primary Endosymbiosis

Even though there is still considerable debate regarding
the precise mechanisms and sequence of events that
resulted in the first eukaryotic cell (de Duve, 2007;
Embley & Martin, 2006; Martin & Muller, 1998; Poole &
Neumann, 2011; Roger, 1999).

There is a general consensus that photosynthetic
eukaryotes emerged from a heterotrophic eukaryote
which engulfed a cyanobacterium.
eukaryote engulfed a cyanobacterium

Ingestion of a
cyanobacterium

Incorporation of the
cyanobacterium as a
chloroplast
 The cyanobacterium was gradually enslaved and
integrated into the cellular machinery as a new organelle:
the plastid.
This event has been termed primary endosymbiosis.

In this way the green algae like complex organisms origin
Three extant groups of photosynthetic eukaryotes have
primary plastids:the green plants, red algae and the
glaucophytes.
Together they make up the Archaeplastida.
 Following the origin of Archaeplastida, photosynthesis
spread widely among diverse eukaryotic groups via
secondary and tertiary endosymbiotic events (Archibald,
2009; Gould et al., 2008; Keeling, 2010).

In that way brown and red algae origin
Evolutionary tree
 Cyanobacteria
(Blue Green Algae)
they are photosynthesis Prokaryotes
they are ancient life forms known as bacteria
what are prokaryotes?

no nucleus
no chloroplasts
no mitochondria

dividing cell
 What are the different between the Prokaryotes and
Eukaryotes/ algae?

Prokaryotes Eukaryotes

nuclear materials not nuclear materials in
contained within nucleus nucleus
no chromosome or nuclear chromosome are formed
membrane and surrounded by nuclear
membrane
no mitochondria or mitochondria in most
plastids cells, plastids in plants and
some flagellates
ribosomes small ribosomes small
(70 S Type) (80 S Type)
 What are the different between the Prokaryotes and
Eukaryotes?

Prokaryotes Eukaryotes

nuclear materials not nuclear materials in
contained within nucleus nucleus
no chromosome or nuclear chromosomes are formed
membrane and surrounded by nuclear
membrane
no mitochondria or mitochondria in most
plastids cells, plastids in plants and
some flagellates
ribosomes small ribosomes small
(70 S Type) (80 S Type)
 What are the different between the Prokaryotes and
Eukaryotes?

Prokaryotes Eukaryotes

nuclear materials not nuclear materials in
contained within nucleus nucleus
no chromosome or nuclear chromosomes are formed
membrane and surrounded by nuclear
membrane
no mitochondria or mitochondria in most
plastids cells, plastids in plants and
some flagellates
ribosomes small ribosomes small
(70 S Type) (80 S Type)
 What are the different between the Prokaryotes and
Eukaryotes?

Prokaryotes Eukaryotes

nuclear materials not nuclear materials in
contained within nucleus nucleus
no chromosome or nuclear chromosomes are formed
membrane and surrounded by nuclear
membrane
no mitochondria or mitochondria in most
plastids cells, plastids in plants and
some flagellates
ribosomes small ribosomes small
(70 S Type) (80 S Type)
Prokaryotes Eukaryotes

cell wall usually contains Peptidoglycan absent
peptidoglycan
nuclear division not by nuclear division usually
chromosome or nuclear by mitosis or meiosis
membrane sexual reproduction is
no sexual reproduction but common
this process in some
bacteria
flagellum has
flagellum, when present characteristic 9+2
does nt have 9+2 structue structure (9 outer & 2
inner)
some can fix nitrogen non can fix nitrogen
e.g.-bacteria & blue green e.g.-All other plants and
algae animal
Prokaryotes Eukaryotes

cell wall usually contains Peptidoglycan absent
peptidoglycan
nuclear division not by nuclear division usually
chromosome or nuclear by mitosis or meiosis
membrane
no sexual reproduction but sexual reproduction is
this process in some common
bacteria
flagellum has
flagellum, when present characteristic 9+2
does nt have 9+2 structue structure (9 outer & 2
inner)
some can fix nitrogen non can fix nitrogen
e.g.-bacteria & blue green e.g.-All other plants and
algae animal
Prokaryotes Eukaryotes

cell wall usually contains Peptidoglycan absent
peptidoglycan
nuclear division not by nuclear division usually
chromosome or nuclear by mitosis or meiosis
membrane
no sexual reproduction but sexual reproduction is
this process in some common
bacteria
flagellum has
flagellum, when present characteristic 9+2
does nt have 9+2 structue structure (9 outer & 2
inner)
some can fix nitrogen non can fix nitrogen
e.g.-bacteria & blue green e.g.-all other plants and
algae animal
Prokaryotes Eukaryotes

cell wall usually contains Peptidoglycan absent
peptidoglycan
nuclear division not by nuclear division usually
chromosome or nuclear by mitosis or meiosis
membrane
no sexual reproduction but sexual reproduction is
this process in some common
bacteria
flagellum has
flagellum, when present characteristic 9+2
does nt have 9+2 structue structure (9 outer & 2
inner)
some can fix nitrogen non can fix nitrogen
e.g.-bacteria & blue green e.g.-All other plants and
algae animal
Prokaryotes Eukaryotes

cell wall usually contains Peptidoglycan absent
peptidoglycan
nuclear division not by nuclear division usually
chromosome or nuclear by mitosis or meiosis
membrane
no sexual reproduction but sexual reproduction is
this process in some common
bacteria
flagellum has
flagellum, when present characteristic 9+2
does nt have 9+2 structue structure (9 outer & 2
inner)
some can fix nitrogen non can fix nitrogen
e.g.-bacteria & blue green e.g.-All other plants and
algae animal
Common characteristic features of the
algae
Algae diversity range from tiny unicellular microalgae to
giant seaweeds which can grow over 50 m.
The are defined as unicellular or multicellular
photosynthetic organisms.
Algae do not possess specialized root, stem, nor vascular
bundles.
They lack diploid embryo stage.
They lack sterile tissue around its reproductive structures.
Zygote development is by mitosis or meiosis but not via
embryo formation
Rhodophyta

( Red Algae)
 General characteristic features

Abundant & diverse in warm tropical and subtropical areas.
Some common in temperate and polar seas.
Hot springs algae – some unicellular forms.

Critical role in coral reef building (encrusting, calcified corallines),
consolidation role.

Carbonate deposits from overlaid red algae with calcium carbonate
in cell walls – global role in carbon storage.

Deepest growing photosynthetic eukaryote (>210 m, Bahamas).

Some parasitic forms – on macro algae (even other reds).

6,000 spp. – 97% marine, 3% freshwater,