Bio 102 General Biology 2 PDF

Summary

This document provides an overview of general biology, focusing on the classification of living organisms. It details the historical context of classification methods, the concept of taxonomy, and the hierarchy of biological classification. This document then discusses the different kingdoms and their characteristics.

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GENERAL BIOLOGY II
BIO 102
GENERALIZE SURVEY OF PLANTS
AND ANIMAL KINGDOM
Classifications of Living Organisms
Aristotle (384-322 BC) a Greek philosopher,
was the first to make an attempt to classify
living organisms.
The present method of classifying and
naming living organisms is based on the
work of Linnaeus (1707-1778), a Swedish
naturalist.
The study of the general principle of
classification is known as taxonomy or
systematic.
 Hierarchy of Living Organisms
Kingdom has the largest group of
organisms.
Each kingdom is split into smaller groups,
and these groups into even smaller
groups and so on.
The arrangement of living organisms in this
hierarchy from the highest to the lowest is
as follows:
Kingdom
Phylum or Division (Plants)
Class
Order
Genus
Species
 As we go down the variety of organisms
decreases.
The kingdom has the largest variety of
organisms. They have certain important
features in common but show many
differences.
The species is the smallest unit of
Classification.
They are identical in general appearance.
They can mate with one another and
produce fertile offspring. Organisms
within a species are very closely related
 Binomial Nomenclature
This is the use of a standard system to name
living organisms, though we are familiar with
common names of living organisms such as
Mango, Goat, Pawpaw, Lion etc.
In Binomial Nomenclature, each kind of
organisms is given two names: the first name
is the genus to which the organism belongs
and the second been the species to which it
belongs.
On the genius name begins with an initial
capital letter, Hence the scientific name of
Pawpaw is Carica Papaya, Lizard – Agama
agama.
The names are written in italics or underlined
separately.
 Kingdoms
All living organism were placed into two
kingdoms by Linnaeus.
The Kingdom was plants and animals.
This is known as two – kingdom
classification.
In this classification, many one-celled
organisms could not fit in properly; it failed
to establish clear-cut distinction between
plants and animals.
It also could not indicate correct relations
among organisms.
 So, in 1969, Whittaker proposed the five-
kingdom classification which is generally
used at present. The classifications are:
Moneras
Protists
Fungi
Plantae and
Animalia
 The Kingdom Monera contains
the prokaryotes – Which are
the very simple –celled
organisms that has no true
nuclei. The eukaryotes- which
cells are highly organized with
definite or true nuclei are
classified into the four
remaining kingdom: protist,
Kingdom Monera (Prokaryotes)
Single- Celled organisms, motile or non-
motile, microscopic. Simple – Celled
Structure with no definite nucleus.
Examples includes Bacteria, Blue-green
algae, actinomycetes
 Kingdom Protista (Eukaryotes)
Single –Celled, motile or non-motile.
Organisms are much larger than the
monerans.
Complex Cell Structure with a definite
nucleus. Examples includes:
Chlamydomonas, Amoeba
 Kingdom Fungi (Eukaryotes)
Non-motile organisms usually of thread-like
structure or hyphae.
Plant- like but cannot carry out
photosynthesis due to absence of
chlorophyll, obtain food through surface
from living or non living organism source by
absorption, reproduction could be by
asexual or sexual or sexual spores.
Examples includes: moulds, Mushrooms,
shine moulds, yeasts.
 Kingdom Plantae
Many-celled, non-motile, contain
Chlorophyll that enables them make their
own food by Photosynthesis.
Plants have indeterminate growth.
Examples includes: Mosses, Ferns, Pines,
Seed Plants (yam, bean, and plants).
 Kingdom Plantae
Plants can readily be understood in the
context of their autotrophic mode of nutrition.
They simply transform light energy into
chemical energy by anchoring firmly in one
place with a maximum surface area to
capture sunlight.
Plants use the cheapest material around,
water and carbohydrate to generate size.
Because plants are immobile, they are
extremely responsive to environmental cues
and have their life cycle in perfect synchrony
with the seasons.
 Plants have a unique mode of
development.
This involves giving by meristems at
their tips.
They also have remarkable power of
regeneration.
Any single plant cell can regenerate
an entire plant with its cell types. The
cells have cellulose cell wall.
 The plant kingdom is mainly
classified into:
Thallophytes (Alga)
Bryophytes
Pteridophytes
Gymnosperms
Angiosperms
 Tracheophytes (Pteridophytes,
Gymnosperm and
Angiosperm)
The tracheophytes are known as vascular
plants.
This is because they have vessels or
vascular tissues for conducting water and
food.
They are the largest group of plants which
includes the seed plants (flowering plants)
as well as some spore-bearing, non
flowering plants like ferns.
 Pteridophytes,
A pteridophyte is a vascular plant (with
xylem and phloem) that reproduces by
means of spores. Because pteridophytes
produce neither flowers nor seeds, they
are sometimes referred to as "cryptogams
", meaning that their means of
reproduction is hidden
E.g fern in forest
 Gymnosperm
The gymnosperms 'revealed seeds') are a
group of seed-producing plants that includes
conifers, cycads, Ginkgo, and gnetophytes,
forming the clade Gymnospermae. The term
gymnosperm comes from the composite
word in Greek: 'naked' and seed'), literally
meaning 'naked seeds'. The name is based on
the unenclosed condition of their seeds
(called ovules in their unfertilized state).
E.g conifers, cycade, ginkgo biloba, pine tree
Gymnosperm
 Angiosperm
Flowering plants are plants that bear flowers and fruits,
and form the clade Angiospermae commonly called
angiosperms. They include all forbs (flowering plants
without a woody stem), grasses and grass-like plants,
a vast majority of broad-leaved trees, shrubs and vines,
and most aquatic plants. The term "angiosperm" is
derived from the Greek words ('container, vessel') and8
('seed'), meaning that the seeds are enclosed within a
fruit. They are by far the most diverse group of land
plants with 64 orders, 416 families, approximately
13,000 known genera and 300,000 known species.
Angiosperms were formerly called Magnoliophyta
(/mæɡˌnoʊliˈɒfətə, -əˈfaɪtə/).
Flowering plants
 Evaluation
1. Differentiate between Bryophytes and
Tracheophytes
2. Why are invertebrates grouped under the
kingdom Animalia
 Evaluation 2
Give an example(s) of the following alga
types:
1. Green Algae
2. Brown Algae
3. Golden – Brown Algae
4. Yellow-green Algae
 Monocotyledonous Root
The anatomy of the monocot root is similar
to the dicot root in many respects. It has
epidermis, cortex, endodermis, pericycle,
vascular bundles and pith.
As compared to the dicot root which have
fewer xylem bundles, there are usually more
than six (polyarch) xylem bundles in the
monocot root.
Pith is large and well developed.
Monocotyledonous roots do not undergo
any secondary growth.
 Dicotyledonous Stem
The transverse section of a typical young
dicotyledonous stem shows that the
epidermis is the outermost protective
layer of the stem Covered with a thin layer
of cuticle, it may bear trichomes and a few
stomata.
 Algae or Thallophyta
Objectives
Algal Morphology
Characteristic Forms of Algae
Classification of Algae
Spirogyra
Structure of a spirogyra
Ecological Adaptation
 Introduction
In this unit we shall be looking at the first
classification of the plant kingdom, which is the
Algae.
Algae show great diversity in size and structure.
They are unicellular, Colonical, filamentous and
thalloid in form.
Some are microscopic, while others are very big in
size. They do not form complex organs or tissues.
The study of their ultra structure under electron
microscope shows that blue-green algae have
prokaryotic type of cell like that of bacteria while
all other algae are eukaryotes
 Algal Morphology
Morphologically, algae can be
distinguished as unicellular, colonial,
filamentous, heterotrichus, thalloid and
polysiphoid forms. Examples of each of
these types of algae are given below.
 Various Forms of Algae
1. Unicellular Algae: Example Anacystis,
Microcystis
2. Colonial Algae Microcystic, Volvox
3. Filamentions Algae Nostoc} blue-green
algae; Ulothrix, Oedogonium
4. Heterotrichous Algae Draparnaldiopsis,
Coleochaete, Ectocarpus
5. Thalloid Ulva, Fucus} Brown algae
6. Polysiphonoid Polysiphonia (Red algae)
 Characteristics of Algae
They are simple plants without roots, stems and
leaves.
They have Chlorophyll. Some have blue, yellow,
brown and red pigments with the chlorophyll.
Majority are uni-cellular while few are multicellular.
Some, such as sea weeds are large.
They are mainly aquatic, with a few on damp soils
and shady places examples are spirogyra, anabaena
and Sargassum
The cell wall of algae is composed of a true
celloulose.
Reserve carbohydrates are usually starch and not
glycogen as in fungi.
 Classification of algae
1. Cyanophyta (prokaryotic algae) or blue-green algae eg.
Including Nostoc, An abaena, Oscillatoria.
2. Chlorophyta (algae) eg. Chlamydomonas, Spirogyra,
Chlorella
3. Phaeophyta (brown algae) eg. Fucus, Sargassum, laminaria.
4. Xantophyta (yellow –green algae) eg. Vaucheria, Botrydium
5. Chrysophyta (Golden-Brown algae) eg. Synura, Mallomonas,
Chromalina.
6. Euglenophyta (Euglenoids) eg. Euglena, Trachelommas.
7. Dinophyta (Dinoflagellates) e.g. Ceratium, Peridinum.
8. Crytophyta(Crytomanads) e.g. Crytomones, Chroomonas.
9. Bucillariophyta (Diatoms) eg. Diatoma, fragilaria.
 Spirogyra
Spirogyra a green algae belongs to the
family Chlorophyceae and the order
conjulaes or Zygnematales.
It is a cosmopolitan plant which forms a
tangled mass of filaments floratiny on
stagnant fresh water, especially in ponds,
ditches, springs and streams.
Some species grow in running water.
Such species produce a short unicellular
organ of attachment, called hapteron, for
anchorage on Sea weeds.
 Spirogyra is commonly found as bright
green masses of thread-like or
filamentous structures on the surfaces of
waters, and is often referred to as a “Pond
Scum”.
 Structure of a Spirogyra
Mature filament is unbranched and consists of single
row of identical cylindrical cells joined end to end.
Cell wall is made of Cellulose and pectin
External cell wall is covered by mucilage, making it
shinny.
Cyloplasm is a thin layer with spiral bands of
chloroplast.
Nucleus is suspended at the centre by strands of
Cytoplasm.
Chloroplast contains small nodular protoplasmic
bodies called the pyrenoids.
Starch grains are deposited around each pyrenoid.
 Algae range from Unicellar (microscopic) to large
(macroscopic) thalloid forms growing in variety of
habitats almost all over the surface of earth.
Wherever there is water, a little moisture or water
vapours, and light, however feeble, Algae are sure
to appear as green, yellow or brown patch. When
several types of algae grow together under similar
natural conditions we call them communities.
The composition of a community is determines by
the physical and chemical nature of the habitat.
In many cases, the algal community indicates to
us about the nature of the habitat, whether, it is
rich or poor in nutrients or polluted etc., in other
words it serves as an ecological indicator.
 Aquatic Algae
Most of the algae grow in water; however, there
are also sub-aerial algae.
Depending on the concentration of salts there are
various kinds
of water bodies, such as fresh water brackish
water, sea water, brine-salt lakes and salt pans.
There habitats nowadays may contain many types
of pollutants, like excessive organic metal, heavy
metals, pesticides, industrial effluents which are
produced and dumped into them by man.
This greatly affects algae and other organisms
present in the water.
 Fresh Water Habitats
Fresh water habitats comprise of rivers,
mountains streams, lakes and temporary
rainwater puddles. Examples of Algae find
here include green algae like oedogonium,
diatoms, desmids, etc.
In slow flowing rivers with rocky shores,
one may find many filamentous algae like
spirogyra, oedogonium. The surface of
submerged rocks also shows epiphytic
algae like desmids and Cyanobacteria.
 Marine Habitats
Sea inhabits largest number of algae collectively known
as seaweed.
Seacoast is periodically flooded and exposed to sun
because of the
feeds. The area between the high tide and low tide level
is known as intertidal zone. The seaweed that grows in
the intertidal zone face alternate drying and wetting.
They are also firmily attached to the underlying rocks by
means of hold fasts.
At times they may get detached and found flowing in the
open sea as in the case of Sargasso sea.
Example of seaweed include Sargassum wightii (brown
algae), Turbinaria, gracilaria edulis
 Special Attributes
Algae are also found in special habitats
where environmental conditions are in
extreme such as Brines and salt lakes where
cyano bacteria (Anabaeria) and Unicellulal
green alga Dunaliella can be found;
Thermal Regions (not water) thermal springs
with temperatures ranging from 40º to 70 ºc)
inhabit alga like oscillareria, Mastigocladus
and Cyanobacteria; Polar Regions (extremely
cold climate conditions) where Nostoc,
oscillatoria, can be found.
 Soil and Subaerial Algae
Surface layers of soils provide a favourable
substratum when wet for the growth of several types
of algas. Terrestrial algae such anabaena, play a
major role as primary colonizers on newly exposed
areas.
Subaerial algae obtain their water from the moisture
in air and grow if moisture is available.
They are capable of enduring drought like the soil
algae.
One can see dark brown patches, sometimes with a
velvelty carpet like cushions covering extensively the
exposed surfaces of buildings, walls, finances,
asbestos, roofs, rock surfaces and also tree trunks.
 Evaluation
Give an example(s) of the following alga
types:
1. Green Algae
2. Brown Algae
3. Golden – Brown Algae
4. Yellow-green Algae
 Evaluation
Outline the general characteristic features
of named Algae
2. Describe the structure of filamentous
Algae
 BRYOPHYTES
During the course of evolution, a change from
aquatic habitat to terrestrial habitat occurred
and the only primitive land plants evolved.
These are known as bryophytes. Although
bryophytes colonize terrestrial habitats but
they are still dependent on water for
completion of their life cycle.
They produce motile male gametes which
require a thin film of water for their motility to
reach the non-motile female gamete to
accomplish fertilization.
 General Characteristics of
Bryophytes
Bryophytes lack roots and do not have vascular system.
Some mosses have a primitive system of tubes that conduct
water and food – conducting tubes are called leptoids.
A single plant is very small, hardly a few cm in size. It seldom
grows large because of lack of supporting tissues.
Bryophytes show two distinct and well defined phases of life
cycle, sexual and asexual which follow each other. T he
gametophyte is haploid and produces gametes.
The Sporophytes is diploid and produces spore. The haploid
generation alternates with diploid genetic known as Alternation
of generation.
The gametophyte may be thalloid or has an axis differential into
stem-like and leaf-like structures which have xylem and phloem.
The gametophyte is green, photosynthetic and nutritionally
independent, and anchors to the soil by unicellular or
multicellular filaments called rhizoids.
 Rhizoids appear like roots but they lack
vascular tissues
 Morphology of Bryophytes
Bryophyte is mostly divided into liverworts
and mosses.
 Liverworts
Gametophytes usually are close to the ground.
There are 2 forms of liverworts namely; thalloid
liverworts
(gametophyte) and is dorsi-ventral, with upper
and lower surfaces.
Leafy liverworts (differentiated into leaf-like
and stem-like structures).
Leaves of liverworts are without midribs.
Grows on moist ground or rocks that are also
wet. (can be found in muddy areas.
Examples include Marchantia and Riccia
 Mosses
This is the largest class of Bryophytes.
They are divided into three subclasses:
Sphagnidae (Reat mosses)
Andreaide rock mosses) and Bryidae (true
mosses).
Example includes funaria
 BRYOPHYTE summary
1. Bryophytes are simple non-vascular land plants and
it is believe that they evolved from green algae
because of several common characteristics.
2. Bryophytes shows two distinct and well defined
phase of life cycle ie. The gametophyte phase and the
sporophyte phase. The gametophyte produces the
gamete while the sporophyte produces the spore.
3. The challenges of land environment for a plant are
fixation to the ground conduction of water and
dispersal of sperms and spores. Bryophytes take care
of there by developing land adaptations such as
epidermis, cuticles, stomata, air spores, rhizoids, etc.
4. Liverworts (Marchantia) and Mosses (Funaria) are
example of Bryophytes.
 Pteridophyte
General Characteristics of Pteridophytes
i. Pteridophytes have two distinct phases
in the life cycle. These are Gametophyte
and Sporophytes which follow each other
in regular succession. The two
generations look different.
 Xtics of Pteridophytes cont’d
ii. The sporophyte is the dominant generation, independent
of the gametophyte; it possesses a vascular system and
it is in a different habitat.
iii. Pteridophytes exhibit a great variation in form, size and
structure.
iv. Most are herbaceous except a few woody tree ferns.
v. They may be dorsi-ventral or radial in symmetry.
vi. They have dichotomously or laterally branched stems
that bear megaphyllous leaves.
vii. Roots are generally adventitious, the primary embryonic
root being short-lived.
viii. Spores are produced in special structures called the
sporangia that are invariably subtended by life-like
appendages known as sporophylls.
ix. In most cases, the sporangia are compacted to
form distinct spore producing regions called the
strobile. The sporangia in some cases, may be
produced within specialized structures called the
sporocarp.
x. The leaves of a fern plant is called frond.
xi. Pteridophytes, in general, are homophonous i.e.
they produce only one-type of spores. However, a
few species produce two types of spores (micro-
spores and megaspores).
xii. They form green, dorsiventrally differential,
thallose gametophytes with sex organs restricted
to the ventral surface.
xiii. The female reproductive structure is
archegonium and the male reproductive structure
is antheridium.
 Relationship of Pteridophytes with Other
Groups
Pteridophytes and Bryophytes: Similarities
1. Liverworts and Pteridophytes show similarity in vegetative
structure of gametophytes.
2. Their female and male reproductive structures are
archegonium and antheridium, respectively.
3. The opening of the mature sexual reproductive organs and the
subsequent fertilizations are condition by the presence of
water in liquid salt. ie both require water for fertilization.
4. They usually show a distinct and clearly defined heteromorphic
alternative of generations and the two generations follow each
other in regular succession.
5. The spores arise in the same manner in both groups.
6. Development of embryo occurs in the archegonium.
7. The young sporophyte or embryo is partially parasitic upon the
gametophyte.
 Difference
1. In Pteridophytes, the sporophyte is
independent at maturity and is the
dominant phase of life cycle instead of
gametophyte as in bryophytes.
2. The Sporophyte has true roots, stems,
and leaves and well developed conducting
tissues-xylem and phloem, which are
absent in bryophytes.
3. Some of the Pteridophyte is
heterosporous but all the bryophytes are
homosporous.
Pteridophytes and Flowering Plants
In Pteridophytes, plant body is not divided into root
and shoots system, in flowering plants, plant body
differentiated into distinct root and shoot system.
Vascular bundles are less developed in
Pteridophytes, (tracheids) Flowering plants has well
developed vascular bundles (xylem and phloem).
There is no pollen grain, pollen tube; in Pteridophytes
following plant has pollen grain.
Pteridophytes have no seeds (but sori) while
flowering plants produce seeds with cotyledons or
endosperms.
 Morphology of a Pteridophyte–
Pteris vittata
Pteris is a widely distributed genus with
about 250 species.
It grows abundantly in cool, damp and shady
places in tropical and subtropical regions of
the world.
Pteris Vittata is a low level fern which brings
out new leaves throughout the year.
It is very common along mountain walls and
grows up to 1200 metres above sea level.
 All the species of pteris are terrestrial,
perennial herbs with either creeping or
semi erect rhizome covered by scales.
Roots arise either from the lower surface
or all over the surface of rhizome.
Leaves are compound in most species,
but a few have simple leaves eg. Pteris
cretica.
The stalk of leaf continues as rachis and
bears leaflets called pinnae.
In Pteris vittata, the pinnae present near
the base are tips are smaller than those in
the middle.
 Condition for Adaptation
Sporophyte shows greater degree of complexity in
structural organization.
It is organized into stem, root and leaves.
The Vascular tissues (xylem and Phloem) are
developed only in the sporophyte.
The aerial parts are covered with a layer of cuticle.
On the Epidermis, there are stomata for the
exchange of gases.
These anatomical complexities of the sporophyte
of Pteridophytes helped in inhabiting a much
wider range of environmental condition than the
gametophyte could do.
 Alternation of Generation
Heteromorphy ---alternation of distinct
generation
Haploid gametophyte –1n set of
chromosome
Diploid sporophyte– 2n set of
chromosome
Gametophyte produce sperm and egg
Sporophyte produce spores
 Evaluation

Outline the relationship between
Pteridophytes and Bryophytes in respect
to their similarities and Differences.
 SEED PLANTS (GYMNOSPERM
AND

ANGIOSPERM)
Seed plants are seed producing vascular plants. They
are also called Spermatophyte. They have well
developed roots, stems and leaves. The seeds
containing the embryo develops from a fertilize egg of
a very small gametophyte which is completely
dependent on the sporophytes, the plant form we see
around us. The efficient seed dispersal of seed plants
account for their continued existence and widespread
occurrence. The fertilization of the egg is by the male
gamete which is brought by pollination, followed by the
growth of the pollen tube which carries the male
gamete to the egg. Water is not needed in this process,
hence the seed plants are true land plants. In this unit,
we shall be looking at the seed plants: Gymnosperm
and Angiosperms.
 OBJECTIVES
By the end of this unit, you should be able to:
list out general characteristics of seed plants
outline the specific characteristics features of
gymnosperms and angiosperms
highlight morphological characteristic of a
named gymnosperm and angiosperm
classify gymnosperms and angiosperm
highlight the terrestrial (ecological) of seed
plants.
 General Characteristics of Seed
Plants
They are terrestrially adapted i.e they are land
plants.
The gametophytes of seed plants become more
reduced and dependent on the sporophytes.
They produce two types of spores (Megaspores
and Microspores) ie. they are heterospores.
They undergo pollination which replaces
swimming as the mechanism for delivering
sperm to egg.
They produce seed.
 Gymnosperms
Classification
Gymnosperms are generally classified into
four divisions. These are
- Coniferophyta - the conifers
- Cycadeophyta - Cycads
- Ginkophyta - ginko
- Gnetophyta - gnetae.
 Conifers
Among the gymnospems, the conifers are the most
important. They have the following characteristics:
They are cone bearing plants with vascular tissue.
All are woody plants; the great majority been trees with
just a few shrubs.
Species can be found growing naturally in almost all
parts of the world.
They are frequently dominating plants in their habitats.
They are of immense value, primarily for timber and
paper production.
The wood of conifers is known as softwood.
Examples are: Cedars, Cypresses, Pines, Redwoods etc.
External Morphology of Conifers
All are wood plants, and most are trees.
Majority has a monopocal growth (ie. a
single, straight trunk with side branches)
with optical dominance.
Size varies from less than a metre, to over
100 meters.
They are the world largest, tallest and
oldest living things.
Ecological Adaptation of Conifer
The have distinctly scented pesin, which is
secreted to protect the tree against insect
infestation and fungal infection of woods.
They maintain high rates of photosynthesis
at relatively low temperature.
Their needles (leaves) have thick warty
coatings and sunken stomatas which
prevent excessive loss.
The sapwood column is large and acts as a
short-term reservoir that supplies water to
foliage during drought periods.
 Angiosperms
The angiosperms are also known as
flowering plants. They occupy every habitat
on earth except extreme environments. They
live as epiphytes (i.e living on other plants); as
floating and rooted aquatics in both fresh
water and Marine habitats, and as terrestrial
plants that vary tremendously in size,
longevity and overall form. They can be small
herbs, parasitic plants, shrubs, vines or giant
trees. They are also sources for other
important resources such as medicine and
timber.
 Classification
Angiosperm are generally classified into two
(2). These are:
Monocotyledons (Monocots)
Dicotyledons (Dicots).
General features of Angiosperms
They could be photoautotroph, Saprobes
or parasitic.
Mostly pollinated by insects, birds, and
other animals, while some are by wind
They have vessels (xylem and phloem).
The monocots include lilies, grasses, corn,
wheat, palms, while the dicots include
roses, maples, oaks, peas, and beans.
Angiosperms posses certain external features
that remarkably distinguish them from other
seed plants. This feature includes:
1. Flowers
They have modified leaves
Has sepals – usually green
Petals –brightly colored and insect pollinated
Petals –drab – wind pollinated
Has carpels – female reproductive organ.
Has stamen- male reproductive organ.
 2. Fruits
It protects documents seeds.
They have mature ovary.
Simple fruit has single ovary flower (e.g.
Pea pod, apple)
Aggregate fruit – produce from separate
flowers (e.g pineapple)
Modifications for dispersal includes:
attractive food, dispersal by wind, burns.
 Terrestrial Adaptation of Vascular
Plant (Seed Plants)
Possession of cuticle
They do not need immediate aquatic
habitat.
Roots have no cuticle.
They are woody materials made of
Cellulose and lignin.
Possession of vascular tissues (Xylem
and Phloem).
 Evaluation
1. Outline how conifers are terrestrially
adapted.
2. What are the distinguishing features of a
flowering plant?