Nematodes as plant pathogens.pptx

Transcript

CSB 324

Introduction to
phytonematodes
 Introduction to nematodes

 Nematodes roundworms belonging to the Phylum Nematoda
 the second most abundant and diverse multicellular animals on
earth after insects.
 Nematode species are very difficult to distinguish because of
their subtle differences in their morphology.
 Number of cells that constitute the nematode’s body, except the
gonads are predetermined
 Size increase after that number is reached proceeds by cell
division as in other animals
 Introduction to nematodes
 over 80,000 genera have been described, of which over 15,000
are parasitic.
 Because of their abundance, nematodes are an important
component of every ecosystem.
 They occupy nearly all ecological habitats from marine to fresh
water, free living in the soil or as parasites of animals, insects
and plants.
 Of all the escribed genera, 50 % are marine dwellers; 25 % free-
living or fresh-water 15 % animal parasites and 10 % plant
parasites.
 Some are beneficial as entomopathogens
 Nematodes from different habitats

Freshwater
Plant parasitic Human parasiticInsect parasitic Free-living
Marine nematode nematode Nematode/
nematode nematode nematode
entomopathogenic
 Nematode morphology

 Nematodes are roundworm with unsegmented bodies.
 They are bilaterally symmetrical and triploblastic i.e. possessing three
layers: ectoderm, mesoderm, and endoderm.
 Nematodes are thin and round in cross section
 They have no circulatory system and transport nutrients through the body
via fluid in the pseudocoelom.
 They have a complete digestive system with separate orifices for food
intake and waste excretion, a pattern followed by more complex animals.
 The body cavity is a pseudocoelom, which lacks the muscles of coelomate
animals that protects the body from drying out, from digestive juices, or
from other harsh environments.
.
General morphology of a nematode

 There are different
morphologies
 Mostly nematodes are eel-
shaped
 Some exhibit sexual
diamorphism
 Female root knot nematodes
are pear-shaped
 Reniform and Citrus
nematodes are kidney-shaped
(Rotylenchulus spp. and
Tylenchulus spp. respectively)
 General morphology of
nematodes
 Although this cuticle allows movement and shape changes via a
hydrostatic skeletal system, it is very inelastic and so does not
allow the volume of the worm to increase.
 Therefore, as the worm grows it has to molt and form new
cuticles.
 The cuticles do not allow volume to increase so as to keep
hydrostatic pressure inside the organs very high.
 For this reason, the roundworms do not possess circular
muscles (just longitudinal ones) as they are not required.
 This hydrostatic pressure is the reason the roundworms are
round

Ecdysis in nematodes
 General morphology of
nematodes: The nervous system
 Nematodes have a simple nervous system, with a main ventral
nerve cord and a simple dorsal nerve cord.
 Sensory structures at the anterior end are called amphids, while
sensory structures at the posterior end are called phasmids.
 There are no circular muscles, so the body can only undulate
from side to side.
 Contact with solid objects is necessary for locomotion;
 its thrashing motion varies from mostly
to completely ineffective at swimming.
Amphids vs phasmids
 General morphology
 Nematodes generally eat bacteria, fungi and protozoans,
although some are filter feeders.
 Excretion happens through a separate excretory pore.
 Nematodes also contract bacterial infections within excretion
pores.
 The type of cephalic framework can give an idea as to what the
nematode feeds on.
 Most fungal and algal feeders have a mural tooth that is used to
pierce the cells while plant parasitic nematodes have a ´spear´
used to pierce plant cells.
Cephalic frameworks and feeding types
Morphology of the head
 Reproduction
 Reproduction is usually sexual.
 Males are usually smaller than females (often much smaller) and
often have a characteristically bent tail for holding the female for
copulation.
 During copulation, one or more chitinized spicules move out of the
cloaca and are inserted into genital pore of the female.
 Amoeboid sperm crawl along the spicule into the female worm.
 Nematode sperm is thought to be the only eukaryotic cell without
the globular protein G- actin.
 Eggs may be embryonated or unembryonated when passed by the
female, meaning that their fertilized eggs may not yet be
developed
 Reproduction
 In free-living roundworms, the eggs hatch into larva, which
eventually grow into adults;
 in parasitic roundworms, the life cycle is often much more
complicated.
 Nematodes possess a wide range of modes of reproduction
 some are hermaphroditic – they keep their self-fertilized eggs
inside their uteruses until they are ready to hatch
 the juvenile nematode will then ingest the
parent nematode through a process termed
Indotokia matricida.
 Reproduction
 Meloidogyne spp exhibit a range of reproductive modes
including:
 sexuality (amphimixis),
 facultative sexuality
 meiostic parthenogenesis (automixis)
 mitotic parthenogenesis (apomixes).
Nematode taxonomy and classification
 Traditional classification

 Mostly dependent on morphological characteristics of
nematodes especially the presence or absence of phasmids.
 Two classes;
 Adenophoria; without phasmids;
 Secernentea; with phasmids
 Modern Classification
 Based on small subunit ribosomal DNA (SSU rDNA).
 The small subunit is the 16s component of the rDNA.
 Current (2001, 2002, 2004 and 2006) integration by Paul de Ley
(UC Riverside) and Mark Blaxter (University of Edinburgh).
 Two Classes Enoplea and Chromadorea
 Order Dorylamia in Enoplea has members that are of Agricultural
importance
 Most plant parasites under Chromadorea (Tylenchids)
 Tylenchids constitute 94% of plant parasitic nematodes
belonging to several families, and genera, e.g. root knot
nematodes, lesion nematodes, rice nematodes etc
Table 1: Morphological characters that delineate
Chromadorea from Enoplea

Character Chromadorea Enoplea
Amphid Pore like/ Slit like Pocket like
Post labial pore/ spirals
Cuticle Annulated Smooth or finely striated
Oesophagus 3 parts with 3 to 5 glands Cylindrical or bottle
shaped
Morphology of nematode
oesophagus
Shapes of amphids
 PLANT PARASITIC NEMATODES
 They possess a stylet, which distinguish them from saprophytic
nematodes (see diagrams below).
 They are generally smaller than saprophytic nematodes.
 Piercing and thrusting muscles move stylet and allow the
nematode to puncture host cell and suck cell fluids to the
digestive system.
 Digestive enzymes move through the stylet and it is through this
process that viruses are acquired and transmitted.
 There are two types of stylets possessed by nematodes that are
used to separate them into classes:
 1) Stomatostylet ( Chromadorea)
 2) Odontostylet (Class Enoplea
 Types of stylets

Types of stylets A Stomatostylet and B Oontostylet
 LIFE CYCLE OF A TYPICAL PHYTONEMATODE

 Duration of life cycle of most phytonematodes is 3-4 weeks
from commencement of egg-laying to the appearance of
eggs of the next generation.
 Stages involved in the cycle:
 1. Egg – in the soil, in or on plant roots
 2. Juvenile (Larva)
 1st stage juvenile develops in the egg; 1st molt occurs
within the egg
 2nd juvenile: hatches from the egg; 2nd molt
 3rd stage juvenile: in the soil, in or on plant; 3rd molt
 4th stage juvenile; 4th molt
Lifecycle of a typical
phytonematode
 Growth and development
 Growth of the nematodes requires Molting
 During molting, the nematode becomes quiescent and halts its
feeding
 Enzymes from the hypodermis digest part of the old cuticle
 New cuticle is secreted by the hypodermis under the remains of
the old one
 Nematode resumes movement and crawls
out of the old cuticle

.
 Lifecycle of phytonematodes
 Pratylenchus spp. from 2nd stage juvenile on, moves freely into
and out of roots.
 Then the life cycle progresses as outlined below.
 Lifecycle of Meloidogyne spp
 Develop into 2nd stage juveniles within the eggs.
 The 2nd stage juveniles then emerge to move about in soil in search of susceptible
roots.
 Once inside the root, Meloidogyne juveniles become immobile and develop into
sausage-shaped individuals.
 The enlarged sausage-shaped juveniles (after 8-9 days in a favorable host and under
favorable temperatures) stop feeding and undergo three molts in succession in a
period of 2-3 days.
 The resulting individuals are differentiated into adult females and males.
 The female resumes feeding and enlarges and becomes pear-shaped. From the time
that the 2nd stage juvenile found a favorable position in the roots it lost its ability to
move.
 The male regains the ability to move while the female remains in one position.
 Female starts egg-laying by depositing several eggs in a gelatinous matrix that usually
protrudes from the root surface.

Lifecycle of Meloidogyne spp.
 Feeding types of
phytonematodes
1. Surface feeders:
 Feed on cells of the root epidermis and on root hairs
 Generally do not penetrate root cortex
 e. g. Trichodorus spp.
 Paratylenchus spp commonly known as Pin nematode

Paratylenchus spp
ffect of stubby root Trichodorus spp.
Nematode (Trichodorus spp
 Phytonematode feeding
types
2. Ectoparasitic feeders
 Feed on cells in the cortex
 They penetrate with their stylets and sometimes with a small
portion of the anterior body.
 e.
g. Belonolaimus spp., Xiphenema spp., Longidorus spp. and
Rotylenchus spp.
 Feeding types of phytonematodes
3. Migratory endoparasites
 Habitually enter plant tissues and move about actively.
 E.g.Pratylenchus spp ( lesion nematode)., Ditylenchus spp ( stem
and bulb nematode)., Radopholus spp ( burrowing nematode) and
Aphelonchoides spp (leaf/foliar nematode).
Nema wool

Pratylenchus spp Effect of Ditylenchus spp Effect of Rodopholus spp Effect of Aphelonchoides
spp
 Phytonematode feeding
types
4. Sessile endoparasites
 Are adapted to a sessile life and do not move
 Adult female are swollen and remain in one position while males are elongate and active
 They induce the formation of specialized cells in the host
 e. g. Meloidogyne spp (root knot nematode)., Heterodera spp. (lemon –shaped Cyst nematode). Globodera
spp. (globe-shaped Cyst nematode) and Naccobus spp. ( Fakse root knot nematode)

emale root knot nematode False root knot nematode Heterodera spp Globodera spp
DIAGNOSIS OF DISEASES CAUSED BY
NEMATODES
Observation of symptoms and signs
1.

 It may be possible to diagnose a few nematode-induced plant diseases by careful examination of
infected plants
 to look for specific signs and symptoms (galls, cysts, stubby roots, “nema wool” (for stem and bulb
nematodes), and areas of internal leaf necrosis filled with nematodes (for foliar nematodes).

2. Soil and plant tissue assay and Microscopy
 In the absence of obvious signs, soil-borne nematodes must be diagnosed by assaying soil and root
samples
 Nematodes tend to congregate in “hot spots”, so a composite set of samples will most accurately
reflect nematode populations
 The time of year and where nematodes are expected in the soil profile must also be considered when
samples are taken.
 Once the nematodes have been isolated from soil or plant tissue, microscopy is used to look at
morphological characters
 After extraction, nematodes must be identified and counted under a microscope.Other parts of the
plant must also be incubated to let nematodes move out
 Extraction of nematodes from soil
There is a number of extraction methods.
These include:
Washing and Sieving: a number of nestled sieves are used with the highest
perture size at the top and the smallest aperture at the bottom
Baermann funnel
Modified Baermann Funnel/ tray method

Decanting and sieving Modified Baermann tray Root incubation Foliar puncturing
technique method
Baermann funnel and incubation
 Extracting cyst nematodes

Washing and drying method Oostenbrink Elutriator Fenwick can
 Centrifugation-floatation technique
 Thismethod is used to extract all life stages including
eggs,sessile, moving and dead nematodes.
 Uses gravitational force to float out nematodes
 Traditionally termed ‘The sucrose method’
 Other ‘heavy’ chemicals such as iodixanol solution, and Ludox
solution
 Diagnosis of diseases caused by
nematodes
 Host specificity test in specific-host nematodes
 Molecular identification
 Culturing isolation DNA extraction

Identification Alignment Sequencin
With existing data g
Nematode dispersal and
dissemination