Chapter 2 - Systematics Lecture PDF

Summary

This lecture covers systematics and taxonomy, including the study of diversification and relationships of life forms, as well as the scientific study of kinds and diversity of organisms. It also discusses the two major components: taxonomy and phylogenetics, along with classifications, nomenclature, and evolutionary history across various organisms.

Full Transcript

CHAPTER 2: SYSTEMATICS & TAXONOMY
NORILIE JANN A. BORJA

President Ramon Magsaysay State University SYSTEMATICS 1
SYSTEMATICS
Systematics is the study of diversification and relationships
of life forms of extinct extant.
Systematics is derived from the Latinized Greek word
‘systema’ applied to the system of classification developed
by Linnaeus in the 4th edition of his historical book Systema
Nature in 1735.
Today’s systematics generally makes extensive use of
molecular biology and computer Programs to study
organisms.
Both taxonomy and evolution= SYSTEMATICS
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SYSTEMATICS
The famous paleontologist George Gaylord Simpson defined
systematics as the "scientific study of the kinds and diversity
of organisms and of any and all relationships among them.
“STUDY OF BIODIVERSITY”
TWO MAJOR COMPONENTS
1.Taxonomy
2. Phylogenetics

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TAXONOMY
derived from the Greek taxis (“arrangement”) and
nomos (“law”)
A discipline of classifying organism into taxa
Governs the practices of naming, describing,
identifying and specimen preservation.

CLASSIFICATION + NOMENCLATURE=TAXONOMY

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TAXONOMY
A field of biology and paleontology
that concerns the naming of living
(extant) and ancient (extinct)
plants, animals, and other
organisms.

Carl Linnaeus in the 18th century

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 STAGES IN TAXONOMY
1. Alpha taxonomy- In this stage species are identified and
characterized on the basis of gross morphological features.

2. Beta taxonomy- In this stage species are arranged from lower
to higher categories, i.e., hierarchic system of classification.

3. Gamma taxonomy:- In this stage intraspecific differences
and evolutionary history are studied.

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PHYLOGENETICS
the study of the evolutionary relationships among
organisms
tree-like diagrams
branching diagrams that depict hypotheses of
evolutionary relationships between extant and/or extinct
organisms
In 1837, Charles Darwin sketched one of the earliest
known phylogenetic trees in a notebook, which was
followed by another such tree in On the Origin of Species
in 1859
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 PARTS OF A TREE
Terminal taxa are connected
by branches. The branches are
the line segments that make up
the tree. Branches come
together at branching points
called nodes. Each nodes
represents a common ancestor
shared by two or more terminal
taxa.

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PHYLOGENETICS
On a phylogenetic tree, more
closely related terminal taxa are
connected by shallower nodes
(i.e., nodes nearer to the tips of
the tree) and more distantly
related terminal taxa are
connected by deeper nodes (i.e.,
nodes nearer to the base of the
tree). Graphic style of phylogenetic trees

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A circle-shaped phylogenetic
tree that depicts relationships
among the major groups of living
organisms (blue = bacteria;
green = Archaea; pink =
eukaryotes)

Trees with many terminal taxa

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 MAJOR DIFFERENCE BETWEEN TAXONOMY & SYSTEMATICS
1. Taxonomy is the most important branch of systematic and
thus systematics is a broader area than taxonomy.
2. Taxonomy is concerned with nomenclature, description,
classification and identification of a species, but systematics
is important to provide layout for all those taxonomic
functions.
3. Evolutionary history of a species is studied under
systematics but not in taxonomy.
4. The environmental factors are directly related with
systematics but in taxonomy it is indirectly related.
5. Taxonomy is subjected to change in course of time, but
systematics is not changed if it was properly done.
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NOMENCLATURE
derived from the Latin words nomen (name) and
cloture (to call). “TO CALL BY NAME”
The role of nomenclature to provide labels for taxa at
all levels in order to facilitate, communication among
biologists.
Common names are not authentic
Linnaeus- the system of naming to each organism
which is called binomial nomenclature in 1758.
1ST GENUS & 2ND SPECIES
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IMPORTANT REQUISITE OF TAXA NAMES
UNIQUENESS- name should be unique.
UNIVERSALITY- name should be name all over the
world.
STABILITY- name should not be change.

The International Code of Zoological
Nomenclature-a set of rules for naming of animals and for
resolution of nomenclature problems.
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BINOMIAL NOMENCLATURE
Combination of 2 names

TRINOMIAL NOMENCLATURE
Indian Lion – Panthera leo persica (Linn.)
Trinomen is used to recognized a subspecies

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Section Title 2
Subtitle

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APPROCHES TO CLASSIFYING ORGANISM

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The Three Domains of Life

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 Phylogeny refers to the evolutionary relationships
between organisms.
The Three Domain System, proposed by Carl
Woese and others, is an evolutionary model of
phylogeny based on differences in the sequences
of nucleotides in the cell's ribosomal RNAs (rRNA),
as well as the cell's membrane lipid structure and
its sensitivity to antibiotics.

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 The Bacteria

Bacteria (also known as eubacteria or "true
bacteria") are prokaryotic cells that are common
in human daily life, encounter many more times
than the archaebacteria
Bacteria include mycoplasmas, cyanobacteria,
Gram-positive bacteria, and Gram-negative
bacteria.

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 The Bacteria possess the following characteristics:
a. Bacteria are prokaryotic cells.
b. Like the Eukarya, they have membranes
composed of unbranched fatty acid chains
attached to glycerol by ester linkages (Figure
1.).
c. Cell walls of Bacteria contains
peptidoglycan.
d. Bacteria are sensitive to traditional
antibacterial antibiotics but are resistant to
most antibiotics that affect Eukarya.
e. Bacteria contain rRNA that is unique to the Figure 1.
Bacteria as indicated by the presence
molecular regions distinctly different from the
rRNA of Archaea and Eukarya.
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 The Archaea
The Archaea possess the following characteristics:
a. Archaea are prokaryotic cells.
b. Unlike the Bacteria and the Eukarya, the Archaea
have membranes composed of branched
hydrocarbon chains (many also containing rings
within the hydrocarbon chains) attached to glycerol
by ether linkages (Figure 1.).
c. No peptidoglycan on cell wall.

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 The Archaea

The Archaea possess the
following characteristics:
d. Archaea are not
sensitive to some
antibiotics that affect the
Bacteria, but are sensitive
to some antibiotics that
affect the Eukarya.
e. Archaea contains rRNA
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 The Eukarya
a. Eukarya have eukaryotic cells.
b. Like the Bacteria, they have
membranes composed of
unbranched fatty acid chains
attached to glycerol by ester
linkages.
c. Not all Eukarya possess cells
with a cell wall, but for those
Eukarya having a cell wall, that
wall contains no peptidoglycan.
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 The Eukarya
d. Eukarya are resistant to traditional antibacterial
antibiotics but are sensitive to most antibiotics that
affect eukaryotic cells.

e. Eukarya contain rRNA that is unique to the Eukarya
as indicated by the presence molecular regions
distinctly different from the rRNA of Archaea and
Bacteria.

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The Eukarya are subdivided into the following four kingdoms:

1. Protista Kingdom: Protista are simple, predominately
unicellular eukaryotic organisms. Examples includes slime
molds, euglenoids, algae, and protozoans.

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The Eukarya are subdivided into the following four kingdoms:

2. Fungi Kingdom: Fungi
are unicellular or
multicellular organisms.
The cells have cell walls
but are not organized
into tissues. They do not
carry out photosynthesis
and obtain nutrients
through absorption.
Examples include sac
fungi, club fungi, yeasts,
and molds. 27
The Eukarya are subdivided into the following four kingdoms:

3. Plantae Kingdom: Plants
are multicellular organisms
composed of eukaryotic
cells. The cells are organized
into tissues and have cell
walls. They obtain nutrients
by photosynthesis and
absorption. Examples
include mosses, ferns,
conifers, and flowering
plants.

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 The Eukarya are subdivided into the following four kingdoms:
4. Animalia Kingdom:
-multicellular organisms
-The cells are organized into
tissues and lack cell walls.
-They do not carry out
photosynthesis and obtain
nutrients primarily by
ingestion.
Examples include sponges,
worms, insects, and
vertebrates

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THANK YOU !!!

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