Lecture 2: Introduction to Insect Physiology PDF

Summary

This presentation introduces insect physiology, focusing on insect growth, development, and reproduction. It details the concepts of molting, the different types of insect growth, and the life cycle stages in insects; including determinate and indeterminate growth. It discusses the stages of molting and different types of insect growth and metamorphosis.

Full Transcript

LECTURE 2
INTRODUCTION TO
INSECT PHYSIOLOGY:
Insect growth, development and
reproduction, their Metabolic systems ,
coordination and integration

Marife S. Sayat
Faculty, Crop Protection Department
BS Agriculture Program

Course: AGRIC MC 312: General Physiology and Toxicology
 A. Introduction to Insect Growth,
Development, and Reproduction
Molting An insect’s skeleton is on the outside of its body and is called
an exoskeleton. It serves as a support for muscles and internal organs
as well as a covering. As the insect’s rigid exoskeleton cannot expand
much, it must be shed and replaced with a larger one as the insect
grows. This process is called molting. The life stage between each
molt is called an instar.

Course: AGRIC MC 312: General Physiology and Toxicology
 Kinds of Insect Growth
Molting may occur up to three or four times or, in some insects, fifty times or more during its life. The two kinds of insect
growth are directly related to molting patterns. Those that show a determinate pattern of growth have a fixed number of
molts, whereas those that have indeterminate growth continue to molt indefinitely

Course: AGRIC MC 312: General Physiology and Toxicology
 The Stages of Molting

Apolysis Sclerotisation
After emergence the new cuticle is soft and this a
Molting hormones are released into the particularly vulnerable time for the insect as its hard
haemolymph and the old cuticle separates protective coating is missing. After an hour or two the
from the underlying epidermal cells. exocuticle hardens and darkens. The wings expand by
the force of haemolymph into the wing veins.
1 2 3

Ecdysis
Shedding of the remnants of the old cuticle, and this
begins with the splitting of the old cuticle, usually
starting in the midline of the thorax’s dorsal side.

Course: AGRIC MC 312: General Physiology and Toxicology
 Life Cycle
An insect’s life-cycle can be divided into three types:

 Ametabolous

o No metamorphosis

These insects are
primitively wingless
where the only
difference between adult
and nymph is size.

Example:
o Order:Thysanura
(Silverfish).

Course: AGRIC MC 312: General Physiology and Toxicology
 Hemimetabolous
 Incomplete metamorphosis

o The terrestrial young are
called nymphs and aquatic
young are called naiads.
Insect young are usually
similar to the adult. Wings
appear as buds on the
nymphs or early instars.
When the last moult is
completed the wings
expand to the full adult size.

o Example:
o Order:
Odonata (Dragonflies)

Course: AGRIC MC 312: General Physiology and Toxicology
 Holometabolus
o Complete metamorphosis

o These insects have a different form in their
immature and adult stages, have different
behaviors and live in different habitats. The
immature form is called larvae and remains
similar in form but increases in size. They
usually have chewing mouthparts even if the
adult form mouth parts suck. At the last
larval instar phase the insect forms into a
pupa, it doesn’t feed and is inactive, and
here wing development is initiated, and the
adult emerges.
o Example:
o Order: Lepidoptera (Butterflies and Moths).

Course: AGRIC MC 312: General Physiology and Toxicology
 Metamorphosis and Reproductive Cycles
Stage Complete Metamorphosis Incomplete Metamorphosis

Egg Present Present

Larva Present Absent

Nymph Absent Present

Pupa Present Absent

Adult Present Present

Course: AGRIC MC 312: General Physiology and Toxicology
 Insect Reproduction and
Development
Life Cycle Egg Larva Pupa Adult
Stages

Description Fertilized The The The final,
egg laid immature, transitional sexually
by the worm-like stage between mature
female stage of the larva and stage of the
insect, insect, adult, where insect's life
which will which the insect cycle,
hatch into undergoes undergoes a capable of
a larva. a series of dramatic reproducing
molts to transformation. and starting
grow and the cycle
develop. anew.

Course: AGRIC MC 312: General Physiology and Toxicology
Course: AGRIC MC 312: General Physiology and Toxicology
Course: AGRIC MC 312: General Physiology and Toxicology
 Sexual and Asexual Reproduction

Reproduction

A biological process by which new individual organisms (off-
springs) are produced from their parents.

Sexual or asexual process by which organisms generate new
individuals of the same kind.

A fundamental feature of all known life.

Course: AGRIC MC 312: General Physiology and Toxicology
 Importance of Insect
Reproduction
1 Ecosystem Balance 2 Agricultural Impact
Insects play crucial roles in Many crops depend on insect
pollination and food chains. pollination. Understanding
Their reproduction maintains insect reproduction is vital for
biodiversity and ecological sustainable agriculture.
stability.

3 Pest Control 4 Scientific Research
Knowledge of insect Studying insect reproduction
reproduction helps develop provides insights into
effective pest management evolution and genetic
strategies. This protects mechanisms. It contributes to
crops and human health. broader biological
understanding.
Course: AGRIC MC 312: General Physiology and Toxicology
 Sexual and Asexual Reproduction

Types of Reproduction in Insects

Insects have different & opposite sexes and
reproduce by sexual and asexual reproduction.

These are the following;

1. Oviparity

 Most common mode of reproduction in insects.

 Insects lay the fertilized eggs, which hatch
outside the body of the female.

 Such insects are said to oviparous

 Butterflies, moths, flies, beetles, bugs, locusts,
grasshoppers, dragonflies, mayflies, etc.

Course: AGRIC MC 312: General Physiology
 Sexual and Asexual Reproduction

Types of Reproduction in Insects

2. Viviparity

 Eggs complete their embryonic development and
hatch within the body of the female.

 Hence the female gives birth to the young
ones, instead of laying eggs.

 Such insects are said to
viviparous

 Aphids, certain flies, stylopids, etc.

Course: AGRIC MC 312: General Physiology
 Sexual and Asexual Reproduction

Types of Reproduction in Insects

3. Parthenogenesis

 Eggs undergo full development without having been
fertilized.

 Females lay the unfertilized eggs

 Eggs have both the haploid (half)
or diploid (double) number of
chromosomes.

 These eggs undergo full development and give
rise to males, females or both sexes.

 Aphids, bees, wasps, some whiteflies, thrips, etc.

Course: AGRIC MC 312: General Physiology
 Sexual and Asexual Reproduction

Types of Reproduction in Insects

4. Paedogenesis

 Immature stages (larvae & pupae) produce young

 Have functional ovaries in which eggs are
developed parthenogenetically

 E.g. In some cecidomyids the larvae gives birth
to other larvae, which become adult under
favorable conditions.

 In certain midges (Hernia & Tanytarsus) the
pupa produces larvae, some which become
normal adults.
 A few beetles (Micromathus) also show this
phenomenon,
Course: AGRIC MC 312: General Physiology
 Sexual and Asexual Reproduction

Types of Reproduction in Insects
6. Hermaphroditism

5. Polyembryony  It is an extremely rare phenomenon

 It is a rare phenomenon  A single individual has both the male and
female reproductive organs
 A single egg produces two or more larvae  E.g. in the scale insects (Icerya purchasi) the
outer cells of the gonads produces eggs, while
the inner cells produces sperms,
 E.g. several parasitic wasps (Hymenoptera),
some cecidomyids & a few stylopids.  Thus the eggs are fertilized in the gonads by
sperms in the same individual.

 In the Phorid flies of the genus Termitostroma
each individual has a pair of ovaries & testis to
release the eggs & sperms.

Course: AGRIC MC 312: General Physiology
B. Metabolic Systems of Insects
Insect External Anatomy

The insect is made up of three main body regions (tagmata),
the head, thorax and abdomen.

 The head comprises six fused segments with compound
eyes, ocelli, antennae and mouthparts, which differ
according to the insect’s particular diet, e.g. grinding,
sucking, lapping and chewing.

 The thorax is made up of three segments: the pro, meso
and meta thorax, each supporting a pair of legs which may
also differ, depending on function, e.g. jumping, digging,
swimming and running. Usually the middle and the last
segment of the thorax have paired wings.

 The abdomen generally comprises eleven segments and
contains the digestive and reproductive organs.
External Anatomy of Ants
External Anatomy of Cockroach
 Insect Respiratory System
Tracheal System Spiracles and Air Sacs

Insects do not have lungs like The tracheal system is
vertebrates. Instead, they rely on a connected to the outside
network of tubes called the tracheal environment through small
system to distribute oxygen openings called spiracles,
throughout their bodies. This system which allow air to enter and
consists of branching tubes that carry exit the insect's body. Some
air directly to the insect's cells, insects also have air sacs,
bypassing the need for a circulatory which act as storage and
system. distribution hubs for the
oxygen-rich air.

Respiratory Regulation
Insects can regulate their respiratory system by controlling the opening and closing of their
spiracles, as well as the contraction of their abdominal muscles. This allows them to adjust their
oxygen intake and carbon dioxide release to meet the demands of their activities and
environment.
 There are many different patterns of gas
exchange demonstrated by different groups of
insects. Gas exchange patterns in insects can
range from continuous, diffusive ventilation, to
discontinuous gas exchange.

Terrestrial and a large proportion of aquatic insects perform gaseous exchange as previously mentioned under an
open system. Other smaller numbers of aquatic insects have a closed tracheal system, for example, Odonata,
Tricoptera, Ephemeroptera, which have tracheal gills and no functional spiracles. Endoparasitic larvae are without
spiracles and also operate under a closed system. Here the tracheae separate peripherally, covering the general body
surface which results in a cutaneous form of gaseous exchange. This peripheral tracheal division may also lie within
the tracheal gills where gaseous exchange may also take place
Insect Circulatory System
1 Open Circulatory System 2 Dorsal Vessel and Hemolymph
Unlike the closed circulatory systems
The insect's circulatory system is
of vertebrates, insects have an open
centered around a tube-like structure
circulatory system. This means that
called the dorsal vessel, which acts
their blood, called hemolymph, flows
as a simple heart. The hemolymph is
freely through the body cavity and
pumped through the dorsal vessel
does not travel through a complex
and then flows freely through the
network of vessels.
body cavity, delivering nutrients and
oxygen to the insect's tissues.

3 Hemocytes and Immune Response
Insect hemolymph contains specialized cells called hemocytes, which play a crucial
role in the insect's immune response. These cells help to defend the insect's body
against pathogens and other threats, ensuring its overall health and survival.
 The main function of insect blood,
hemolymph, is that of transport and it
bathes the insect’s body organs.
Making up usually less than 25% of an
insect’s body weight, it transports
hormones, nutrients and wastes and
has a role in osmoregulation,
temperature control, immunity, storage
(water, carbohydrates and fats) and
skeletal function. It also plays an
Pumping of the hemolymph occurs by waves of peristaltic contraction,
originating at the body's posterior end, pumping forwards into the essential part in the molting process.
dorsal vessel, out via the aorta and then into the head where it flows An additional role of the hemolymph in
out into the haemocoel.
some orders, can be that of predatory
defense. It can contain unpalatable
Pumping rate accelerates due to periods of increased activity.
Movement of hemolymph is particularly important for thermoregulation and malodourous chemicals that will
in orders such as Odonata, Lepidoptera, Hymenoptera and Diptera.
act as a deterrent to predators.
Insect Digestive System
Specialized Feeding Adaptations
Insects have evolved a wide range of
specialized feeding adaptations, from
the chewing mouthparts of beetles to
the long, slender proboscis of
butterflies. These adaptations allow
insects to exploit a diverse array of
food sources, from plant matter to
animal tissues.

Gut Microbiome Efficient Nutrient Utilization
Many insects also rely on a complex Despite their small size, insects are
gut microbiome to aid in the digestion remarkably efficient at extracting and
of their food. These symbiotic utilizing the nutrients from their food.
relationships between insects and This ability, combined with their
their gut bacteria play a crucial role in diverse feeding adaptations, allows
the insect's overall health and insects to thrive in a wide range of
nutritional status. environments and ecological niches.
Digestive Tract Structure
The insect digestive system typically
consists of a foregut, midgut, and
hindgut, each with its own specialized
functions. The foregut is responsible
for storing and breaking down food,
the midgut for further digestion and
absorption, and the hindgut for waste
elimination.

The foregut (stomadaeum)
is differentiated into five
parts: Buccal chamber,
pharynx, oesophagus, crop
and gizzard.

Midgut (mesenteron or
ventriculus) is short,
tubular lined with glandular
endoderm.

Hindgut (proctodaeum)
comprises ileum, colon
and rectum.
Insect Nervous System
Central Nervous System
The insect's nervous system is centered around a brain-like structure called the
ganglia, located near the head. This central nervous system coordinates the
insect's sensory input and motor functions, allowing it to respond to its environment
and execute complex behaviors.

Peripheral Nerves
Extending from the central nervous system are numerous peripheral nerves that
carry information to and from the insect's various body parts. These nerves allow
the insect to perceive its surroundings and coordinate its movements with precision.

Sympathetic or Stomatogastric Visceral Nervous System
The insect nervous system integrates a wide range of sensory inputs, including
vision, olfaction, gustation, and mechanoreception. This sensory integration
enables insects to navigate their environments, locate food and mates, and respond
to potential threats.
Insect Sensory Organs

Olfaction
Vision
Insects rely heavily on their sense of
Insects possess a wide range of visual smell, using specialized olfactory organs
capabilities, from simple light detection to like antennae to detect pheromones,
complex, compound eyes that can food sources, and other environmental
perceive color and motion. Their visual cues. This sense of smell is essential for
systems play a crucial role in tasks like insect behavior, from finding mates to
navigation, prey/predator detection, and avoiding predators.
communication.

Gustation
Mechanoreception Insects use specialized gustatory
Insects have a variety of specialized organs, often located on their mouthparts
sensory structures, such as bristles and or feet, to detect and analyze the
campaniform sensilla, that allow them to chemical composition of their food and
detect mechanical stimuli like touch, environment. This sense of taste is
vibration, and wind. This sense of touch critical for insect feeding behavior and
helps insects navigate their environment helps them identify suitable food
and respond to potential threats. sources.

Auditory receptors
for hearing, present on the anal cerci respond to air or earth borne vibrations.
Insect Excretory System
Excretion is performed by Malpighian tubules.

 Each tubule is lined by glandular and ciliated cells. They
absorb nitrogenous waste products and convert them
into uric acid which is excreted out through the hindgut.
Therefore, this insect is called uricotelic.
Insect Reproductive Systems

Male reproductive systems

 Contains a pair of testes, usually located near
the back of the abdomen.
 Each testes is subdivided into functional units
(called follicles) where sperm are actually
produced.
 Near the distal end of each follicle, there are a
group of germ cells (spermatogonia) that divide
by mitosis and increase in size to form
spermatocytes. Mature sperm pass out of the
testes through short ducts (vasa effentia) and
collect in storage chambers (seminal vesicles)
that are usually little more than enlarged
sections of the vasa.
 Similar ducts (vasa deferentia) lead away from
the seminal vesicles, join one another near the
midline of the body, and form a single
ejaculatory duct leads out of the body through
the male’s copulatory organ (called an
aedeagus).
Female reproductive systems

 The female’s reproductive system contains a pair of ovaries.

 When the insect is actively reproducing, these organs swell
with developing eggs and may nearly fill the abdomen.

 Each ovary is subdivided into functional units (called
ovarioles) where the eggs are actually produced.

 A typical ovary may contain dozens of ovaries, generally
aligned parallel to one another.

 Near the midline of the body, these lateral oviducts join to
form a common oviduct which opens into a genital chamber
called the bursa copulatrix.

 Female accessory glands (one or more pairs) supply
lubricants for the reproductive system and secrete a protein-
high egg shell (chorion) that surrounds the entire egg.
 These glands are usually connected by small ducts to the
common oviduct or the bursa copulatrix.
C. Insect Coordination and Integration

Insect Navigation and
Spatial Awareness
Navigation Method Example Species Key Features

Sun Compass Honey Bees Uses polarized light
patterns

Magnetic Sense Monarch Butterflies Detects Earth's
magnetic field

Landmark Desert Ants Remembers visual
Recognition cues

Odor Plumes Moths Follows chemical
gradients
Symbiotic Relationships and Interspecies
Coordination

Mutualism Ecosystem Engineering Pollination
Leaf-cutter ants cultivate fungus gardens. Termites build complex mounds. These Bees coordinate with plants for
The ants provide nutrients, while the structures modify local environments, pollination. This relationship shapes plant
fungus serves as a food source. benefiting other species. evolution and ecosystem diversity.