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AUTHOR’S
DISCLAIMER
The author of this website declines all responsibility for any damage
resulting from use or misuse of the following information or from improper
manipulation and application of the agricultural chemicals mentioned in this
article, all of which are registered trademarks belonging to the legitimate
owners. Insecticides, fungicides, acaricides and other chemicals referred to
in this webpage are recommended solely for informational purposes. If an
active principle has never been used before it is advisable to test it for
phytotoxicity on a single plant first. The retail sale of certain chemicals
may be legal in some countries and illegal in others; you may also require a
private license to purchase some restricted products that are potentially
toxic or harmful to humans. When handling or applying a chemical product you
must be aware that you are doing it at your own risk and that the
instructions printed on the package label or insert have priority over the
information provided in this section.
Before using any chemical product it is essential that you read the
manufacturer’s instructions carefully, especially with regard to its active
principle, dosage, mode of action against parasites, composition, directions
for use, toxicity class, compatibility with other products, time of
application, the possible dangers to wildlife, the interval after which the
chemical is no more harmful (PHI), the nature of risk (exposure by
inhalation, ingestion and skin or eye contact). All chemicals must be
locked in a cabinet and stored in a room or building away from living areas
and out of the reach of children; the preparation and application of a
solution should always be done outdoors, never inside a building or a
greenhouse. Take care not to spray chemicals against the wind; do not
eat, drink or smoke when handling dangerous substances; always wear
protective clothing including gloves and goggles and avoid the inhalation of
the fumes or the contact with eyes or mucous membranes. Wash yourself
thoroughly after every treatment; do not pollute the environment and
dispose of empty containers properly. In case of contact wash affected skin
areas with soap and water immediately; if symptoms arise consult a doctor
carrying the product label with you.
NOTICE: beginners usually tend to become too anxious about an unhealthy
plant and start looking for some expert advice in order to save it, not
really knowing the gravity of the problem. I would like to point out that,
exceptions aside, even a phytopathologist needs to examine a specimen
closely and possibly run some laboratory tests to establish an accurate
diagnosis.
You should also be aware of the fact that most cryptogamic diseases cannot
be cured as symptoms usually become visible only when the pathogen has
already spread within the vascular system of the host plant and harmed the
organism irreparably.
Since prevention is the best remedy for this kind of infections, you will
find further information which should give you some clues to identifying a
plant disease correctly, especially when you have taken a first-hand look at
the specimen; once determined the stage and seriousness of the infection you
can start the right treatment straightaway.
FOREWORD.
A plant is in good health if it can carry out its physiological functions
efficiently. According to Owens "A disease is a disturbance to or a
deviation from the normal structure or physiology of a plant, either
localized or generalized, which can be identified through specific signs or
symptoms and causes damage to the plant".
At least three factors play a fundamental part in the parasitisation of a
plant: the receptivity of the specimen, the virulence of the pathogen and a
suitable environment; when these occur simultaneously they create the
conditions for the pathogen to enter the host. This concept, developed by
Bateman, is known as ‘Disease Triangle’: Host, Pathogen, Environment;
sometimes a fourth factor, Time, is considered, understood as the
duration of favourable conditions for the infection which can influence the
extent and seriousness of the damage.
PHYTOPATHIES AND PESTICIDES
VEGETAL PARASITES
Vegetal parasites are usually divided into four groups:
a) Fungi: these microscopic organisms are incapable of movement and
reproduce both sexually and asexually; they invade vegetal tissues by means
of hyphae feeding on the plant sap. Fungal spores can survive cold
weather and drought and when conditions are suitable for germination they
might be easily spread through water used for irrigation. Many of the
problems concerning fungal diseases are caused by our carelessness as we
often introduce pathogens unintentionally into the greenhouse and if they
become established eventually they lead to serious consequences. Fungi can
enter a host through wounds in its stem or roots, natural openings such as
stomata and some of them can even bore through the plant cuticle using a
specialized hypha. Most fungi thrive in high humidity associated with low
temperatures and poor or absent ventilation; altering these parameters can
stop the spread of the disease which can, however, start again if conditions
worsen. Vegetal debris and certain kinds of plants may harbour fungi such as
Alternaria, Cercospora, Colletotricum; others like Phytophtora
and Fusarium are hidden in the soil; Rhizoctonia, Pythium,
Sclerotium are among the saprophytes found in dead organic matter.
This is why using garden soil as a potting mix is not recommendable as
it might contain resistant spores or other survival structures of pathogens
and bacterial infections unless it is sterilized either with steam at 90°C
(194°F) or fumigants (methyl bromide, carbon tetrachloride); both
procedures, however, cannot be easily carried out at home. The prevention of
diseases is achieved through the accurate sanitization of potting mixes,
propagators and cold frames, greenhouses and any other room where plants are
kept, ensuring at the same time plenty of ventilation, good drainage, a
balanced fertilization as well as the disinfection of seeds..
b) Bacteria: (Schizomycetes): these simple monocellular
prokaryotic organisms with a cell membrane but no distinct nucleus usually
reach a diameter of a few microns and fall halfway between the animal and
the vegetal kingdoms. They can be either aerobic or anaerobic, double their
number by cell division every 20 minutes and survive extreme conditions
which do not allow any other life form to develop. They are found in the
air, in the water, inside and outside every living thing and abundantly in
the soil (between 1 and 50 millions per gram of soil). Most of them are
saprophytic while very few are autotrophs. Many bacteria have a major role
in soil improvement with their oxidation process and decomposition of
organic matter; some are able to fix nitrogen from the air combining it with
hydrogen making it available to plants. They thrive in a temperature range
of 10°C to 35°C (50-95°F), the optimal growth temperature being around 25°C
(77°F), high soil moisture content and in the presence of infected or
non-decomposed organic matter and can be transmitted by insect vectors.
Penetration into the host occurs indirectly through wounds or natural
openings (stomata, scars due to leaf or flower abscission); once inside the
plant they anchor themselves to the cell walls, multiply and invade adjacent
cells or find their way through the parenchymal tissues or the vascular
bundles. That’s why bacterial infections may be systemic, vascular,
parenchymal or hyperplastic. Systemic infections cause leaf wilt and
blackening of vascular tissues resulting in canker formation. Vascular
infections produce wedge-shaped necrotic lesions with black rot. Treat seeds
with copper compounds or water at 50°C (122°F) for 20 minutes as a
preventive measure.
The bacteria Pseudomonas and Erwinia cause rot and tissue
blackening, root canker, vascular occlusion and dieback.
c) Viruses: varying from 0,05 to 0,2 micron in size, these
biological intracellular entities are composed of nucleic acids like RNA
(ribonucleic acid) or DNA (deoxyribonucleic acid) enclosed in a protein coat
(capsid). They do not have a cell structure, cannot move or grow but they
are able to evolve and mutate in order to adapt to different environments.
They cannot, therefore, enter plant tissues directly so possible ways of
transmission are grafting, vegetative propagation of contaminated specimens,
plant-to-plant contact (through epidermal lesions in the healthy specimen)
and finally infected pollen which may give rise to diseased seedlings.
Viruses can also be transmitted by insects, such as aphids, leafhoppers,
mealy bugs, whiteflies, thrips, beetles as well as by mites, nematodes,
fungi and of course humans through careless cultivation. Once inside they
can spread within the plant travelling through the phloem. Viruses can only
reproduce within a ling host cell which is penetrated and forced to
replicate the virus genetic material. They can induce chromatic alterations,
stem or flower malformation, chlorosis and dieback. Yet sometimes infections
may account for interesting variations in stem and flowers, producing spots,
deformities, mosaic patterns or chlorotic ring spots. We should keep an eye
on any alterations in the colour of flowers as these may indicate the
presence of a pathogen.
Correct diagnosis can be obtained using an electronic scan microscope,
serological test kits and fluorescent probes.
Viroses can be prevented through sterilization of tools, suppression of
disease vectors, protection of plants with horticultural fleece, weeding and
keeping your greenhouse clean and tidy. Thermotherapy may be effective in
removing the virus while meristem culture is used to produce virus-free
plants. Moreover, genetic engineering helps to develop virus-resistant
species. On the other hand biotech vaccines are of little or no use since
plants lack a real immune system.
 d)
Mycoplasmas: these
microscopic prokaryotic organisms do not possess a cell wall but are instead
enclosed by a three-layered membrane, are gram-negative, have no flagella
and do not produce spores. Mycoplasmas are neither bacteria nor viruses but
something in between and live inside the phloem of the plants. These
parasites can cause serious disorders in the host that can result in
anomalous growth, not to be confused with the cristate form which is not
caused by an infection. They interfere with the metabolic hormone
stimulating the production of a substance which encourages the development
of new shoots from axillary buds. Because the disease is relatively benign,
it is common practice among most nurserymen to graft infected plants onto
others in order to obtain monstrose forms to be sold as oddities. All cacti
are believed to be prone to this infection, particularly the genera Opuntia,
Echinopsis, Gymnocalycium, Cereus. So far researchers have never been able
to isolate the pathogen responsible for such malformations. The symptoms
are: deformities and aberrant
growth;
proliferation of axillary buds particularly near the apex; weak and stunted
basal offsets; leaf yellowing and pronounced internodal elongation, nanism
of apical meristem, reduced growth, virescence. Affected plants do not need
to be eliminated since there’s no risk of the disease spreading naturally.
Avoid using them for grafting unless you want to experiment; sterilize tools
with denaturated alcohol before using them on other plants. Try to keep your
greenhouse free of pests like leafhoppers, psyllids, mealy bugs, aphids,
whiteflies which can transmit the pathogen. Mycoplasmas can be treated with
hot water (immerse the plant in water at 45°C/113°F for five hours) or
antibiotics such as Tetracyclines and Streptomycin (the latter
is prohibited in some countries).
Diseases caused by groups b, c and d are still quite rare though
becoming increasingly common and hardly curable. Mycoses, though, are
usually treatable but once the disease has spread through a large collection
it is almost impossible to get rid of; prevention is therefore essential
through appropriate horticultural practices and hygienic-prophylactic
measures to be observed in any place where plants are raised or grown.
Here are some general rules that are always valid: disinfect and
quarantine plants that are newly introduced in your collection; always use
good, wholesome potting soil with a low amount of organic matter; spray
plants and soil once a year with systemic products; sanitize cutting and
pruning tools using a solution of water and bleach in a 10:1 ratio; always
ensure good ventilation; apply water early in the morning so that plants
stay dry at night, preferably avoiding overhead watering; make sure that the
soil is never waterlogged, that plants are fed with a balanced fertilizer,
that the air moisture is not too high; germinate seeds that have been
treated with fungicide or bought from specialized nurseries; throughout the
year remove plant debris, spent flowers and fallen leaves from the
greenhouse; disinfect the place with a powdered broad-spectrum fungicide in
late autumn before overwintering plants. Destroy those specimens that have
shown symptoms of infectious disease in order to prevent the proliferation
of the pathogen and the contamination of other plants and get rid of the
soil and pots in which they have been grown; do not forget to wash your
hands before handling other containers or plants. Always bear in mind that
some microorganisms cannot enter vegetal tissues but for our carelessness,
finding their way through cuts and wounds, spreading during repotting
operations or vectored by pests, which therefore must be dealt with
immediately.
Among diseases attributable to vegetal parasites some are worth examining a
little closer: Helminthosporiosis,
Fusariosis,
rot due to
Rhizoctoniosis,
Pythium, Phytophthora,
necrosis produced by Coniothyrium,
Monosporiosis, spots caused by
Septoriosis, Anthracnosis,
Moulds.
Because many diseases manifest themselves in a similar way and yet require
different approaches, it is best to have valuable specimens tested in a
laboratory of phytopathology for a correct diagnosis.
   HE LMINTHOSPORIO SIS-ALTERNARIOSIS/Bipolaris/Drechslera.
It is probably the most dreaded and widespread
 fungal
disease to hit succulents and is caused by Helminthosporium cactivorum
(Drechslera cactivora). In young plants it gives rise to brown rot and
leads rapidly to death. On mature specimens it is known to follow a slower
course, manifesting itself at first as yellowish spots which then turn black
and rotten when the pathogen penetrates into deeper tissues. The most
vulnerable parts are plant collar and concavities in the surface where
humidity usually lingers. High levels of air moisture speed up the
progression of the disease which sometimes shows itself as a black velvety
efflorescence formed by tiny dome-shaped clusters.
Favourable conditions for the proliferation of the fungus are temperatures
between 16 and 30°C (61-86°F), constant humidity and overhead watering,
closely packed plants, the presence of wounds in the leaves or stems and
poor ventilation.
The recommendation is to take preventive action against the problem,
sterilizing the soil with suitable products, removing and destroying
affected plants and avoiding waterlogging or excess wet. Under critical
conditions or at the onset of the first symptoms start treatments with
systemic products such as thiabendazole, zineb, mancozeb, ferbam,
chinosol, captan (the use of certain substances may be subjected to
limitations). Similar symptoms are associated with Alternariosi
(Alternaria tenuis).
FUSARIOSIS.
The symptoms of this
disease, caused by Fusarium oxysporum, are wilt, dry rot, canker,
yellowing of leaf margins, reduced growth with slight tissue alterations in
the basal region which appears opaque and less turgid with soft round spots.
A straight cut across the plant stem will show that sections of the vascular
system are red or brown-coloured; this means that the fungus, which was
lying dormant in the soil, has entered the host plant through its roots,
invaded the vascular bundles obstructing them and released a toxin that
reduces osmotic pressure. In its most acute form it leads to basal rot and
eventually death of affected plants. There is also a milder form of the
disease which tends to become chronic, causing dry rot, a sort of
suberization, which spreads over the surface quite slowly and usually allows
the host to survive for some time. Certain species of Fusarium may infect
the aerial parts instead and then work their way downwards to the rest of
the plant.
The control of Fusariosis and Verticilliosis (Verticillium) along
with other vascular diseases is very difficult; you might try using
benzimidazolic fungicides (carbendazim, benomyl, etc.) with a
broad-spectrum systemic action or thiophanate, dodine (Syllit 35).
Prevention is therefore the best cure: do not grow on soil that is suspect
of contamination; use wholesome horticultural products only; always sanitize
pots, tools etc; avoid excess water and unbalanced fertilizers.
A common problem affecting succulents, especially seedlings and plants
propagated from cuttings is ROT which can suddenly attack the part of
stem in contact with the soil. Unfortunately, if the disease spreads to
young seedlings it is fatal so it is best to treat preventively with
systemic fungicides like propamocarb (Previcur) or
iprodione (Rovral).
ROOT ROT AND COLLAR ROT
are attributable to different fungi yet producing analogous alterations and
cause tissues to soften and become reddish-brown with the discolouration
spreading from the collar to the roots and leading to plant collapse. Other
symptoms are interruption of growth and yellowing of stem and/or leaves. You
might be able to save a diseased plant by immediately removing the infected
portion of stem with a sharp cutter until the exposed surface looks healthy
and shows no dots or tiny spots near the vascular rings. Make sure to
sterilize the blade with alcohol each time you make a cut so that you won’t
spread the disease upwards to the healthy part. The upper portion may be
grafted, if short, otherwise rooted as cutting after being dusted with
sulphur-copper powder or zineb. Such problems may also stem from
excess watering and poor drainage and can be avoided by repotting the plant
in better soil, by following a correct watering schedule and in case of
fungal attack by treating with Benomyl or Thiram. If the
disease is too advanced for treatment, stems can be cut off to be rooted as
cuttings.
ROT CAUSED BY RHIZOCTONIOSIS. The pathogen
responsible for this disease is Rhizoctonia solani, a parasite
attacking mainly Opuntia, Mammillaria, Cucurbitaceae and young seedlings.
This saprophyte fungus is found in the soil surviving within dead tissues
and germinates at temperatures between 8°C and 30°C (46/86°F) invading the
host plant through the root system. The first symptom is basal rot which
progresses rapidly through the whole stem. At the first appearance of the
disease the epidermis looks tight and glossy then the inner tissues start to
deteriorate and eventually collapse. The pathogen is easily detectable
through a microscope.
Effective measures against the disease are preventive soil sterilization
with steam or fumigants and treatments with pencycuron, tolcofos
metil, iprodione once infection has occurred. Benzimidazolics
(carbendazim, benomyl, thiabendazole) also work quite well.
ROT CAUSED BY PYTHIUM SP. There are
different species of this fungus that are known to attack roots and collar
of seedlings with lethal consequences. In mature specimens the affected
parts are covered in light-coloured mildew. Treat with Previcur.
ROT CAUSED BY PHYTOPHTHORA AND
ARMILLARIA. Although this disease is rather infrequent in succulent
cultivation in some cases it may harm plants severely, especially young
seedlings. The fungus responsible for the infection is Phytophthora
cactorum which is commonly found in garden soil. The infection first
manifest itself as soft, spongy rot which spreads rapidly and later causes
the formation of cracks along the stem. The affected tissues appear dark-coloured
and sticky and in the more advanced stages of the disease the parenchymal
tissues eventually become dry. Nematodes are likely to be found in
association with this infection. Lesions caused by Phytophthora
usually harbour other fungi that give rise to dry rot (Fusarium) and
soft rot (Erwinia).
Shoestring root rot is caused by a fungus called Armillaria mellea
and its symptoms differ slightly from those of Phytophthora root rot
in that there is no gum exudation and the infected mass has a distinct smell
of mushrooms.
The disease can be effectively controlled only through prophylaxis which
means disinfecting the
soil, eliminating waterlogging and excess humidity problems, isolating and
destroying any infected specimens. We might also resort to specific chemical
products if necessary, such as dithiocarbamates (ziram, mancozeb,
propamocarb, iprodione) after having perfomed a phytotoxicity test on
the plant.
NECROSIS CAUSED BY CONIOTHYRIUM.
The infection, which some Euphorbias seem to be particularly susceptible to,
first attacks the main stem, sometimes secondary branches, and is
recognisable by the presence of dark-coloured roundish spots. As the
infection progresses the affected parts become either soft or withered and
the whole plant gets weak and eventually dies. It is believed that the
pathogen can enter the plant only through wounds. The disease produces
fruiting bodies containing the parasite that look like black specks, often
arranged in concentric circles. When mature these structures exude
cirrus-like masses of conidia that dispersed by water rapidly spread the
infection. Once again prevention consists in avoiding causing injuries to
plants, ensuring sharp drainage, feeding with balanced fertilizers and
finally eliminating infected material. Captan is the best product for
treating the disease, but should it be difficult to get, benzimidazolics
are also recommended.
MONOSPORIOSIS AND MINOR FUNGAL DISEASES.
Monosporium cactacearum
and Sporotrichum cactorum are other pathogens that might cause
serious damage to certain succulents. The genus Echinopsis and some Cerei
are particularly prone to the aforesaid diseases. The infection starts
attacking the basal cladodes manifesting itself as black spots, at first
small then becoming bigger. It soon penetrates the inner tissues causing
plant death. The recommendation is to remove infected parts, isolate
diseased specimens and treat with products whose main ingredient is
methyl, ziram or dodine (Syllit 35); otherwise use copper
oxychloride.
     
SPOTS CAUSED BY SEPTORIOSIS and
ANTHRACNOSIS. The
fungi Septoria cacticola, Ascochyta opuntiae and
Colletotrichum are known to attack mainly Euphorbia, Opuntia, Cereus,
Echinocactus, Ferocactus, Agave although hypothetically all cacti could be
infected, particularly those grown outdoors and therefore exposed to hail
damage. These fungi spread in the autumn favoured by the high humidity and
the shorter day-length. The sticky droplets found over or near the spots are
the remainders of the fungus after it has penetrated into the plant
epidermis. Following this, dry lesions begin to appear on the cladodes along
with little yellowish spots. The disease spreads rapidly causing stems to
dry out and eventually killing the plant so it is essential to take measures
at the onset of first symptoms in order to stop the pathogen from infecting
the rest of your collection.
On the other hand, symptoms of anthracnosis caused by Colletotrichum
are round sunken spots with regular margins in which at first you might
distinguish three or four different colours like black, light brown and
yellow. After a while the spots turn brownish-grey as a result of the
formation of black spores.
Prevention: take care not to cause any damage to plants; do not keep them
too crammed together; do not overwater plants especially diseased ones in
order to avoid spore dispersal; ensure good ventilation; destroy affected
parts at the first appearance of an infection; discard old soil and apply a
systemic fungicide (thiabendazole) to the new one. Cure: use
anilides such as diclofluanide but also ziram, zineb,
dodin, benomyl (Benlate), mancozeb, maneb, captan, bordeaux mix.
 
MOULDS.
Botrytis cinerea is a pathogen that is commonly known as grey
mould’. It is usually harboured by plant debris that accumulates on the
floor and attacks mainly seedlings and succulents grown in a humid and
poorly ventilated environment. The temperature range favourable to the
development of grey mould is between 0 and 33°C (32/91°F), preferably
15-23°C (59/73°F), at a relative humidity of 80% or above. It thrives
inside greenhouses therefore it is essential that infected parts be removed
and destroyed at once in order to minimize the presence of spores in the
air.
Symptoms: initially, dark green specks or little spots with yellow margins
appear on the leaves and stems and later turn brown or black until they are
finally covered in a fuzzy coating (mycelium) whose colour may vary from
silvery to greenish grey; the affected plant soon rots and dies.
Prevention:
place potted plants at a reasonable distance from one another; sterilize
your conservatory or greenhouse each Autumn; remove plant debris; install an
adequate ventilation system in the glasshouse especially in cold and damp
locations; keep humidity levels in check; do not use a sprinkler irrigation
system; avoid using high-nitrogen fertilizers; apply fungicide to plant
wounds; eliminate weeds from your greenhouse. Affected plants should be
treated with systemic fungicides like benzimidazolics (Benlate) in
combination with one of the following products: ronilan, iprodione,
euparen, copper oxychloride. You might treat preventively with captan
and benomyl.
If a plant shows signs of infection it has to be placed inside a plastic bag
and isolated from the other specimens so as to avoid further contamination;
after that remove all the infected parts of the diseased plant and treat the
cut surface with a fungicide.
Biologic al
control agents against Botrytis are Gliocladium roseum,
Myrothecium verrucaria, Trichoderma spp., Cladosporium cladosporioides.
POWDERY
MILDEW
is a fungal disease that might affect Spurges and Cucurbits and some other
plants, particularly during late Summer; it appears as a white powdery
coating usually causing leaves to curl up. Favourable conditions to the
development of the infection are temperatures of about 20-25°C (68/77°F) and
a relative humidity between 60 and 80%. Its spores are spread by the wind;
it can be controlled spraying wettable sulphur.
SOOTY
MOULD
is caused by saprophytic fungi (Antennaria, Capnodium, Cladosporum)
which feed on honeydew, a sugary substance produced by some parasites
  such
as aphids, mealy bugs, planthoppers, white flies etc. or on nectar drops
exuded by the glands of cacti belonging to the genera Ferocactus and
Opuntia. The disease manifest itself as a greyish black encrustation or
powder resembling soot. These fungi are not pathogenic as they do not
penetrate the epidermis yet they give the plant a sick, unsightly
appearance. The recommendation is to remove the coating using a toothbrush
dipped in a solution of sulphur-copper powder. This should be done without
delay especially when the affected area is quite wide otherwise the plant
loses vigour as a result of poor photosynthesis and gas exchange. The most
effective way to deal with the problem is preventing it by eradicating
insect pests that excrete honeydew and, with regard to Ferocactus, by
washing away the nectar drops exuded by the plants.
NOXIOUS
ANIMALS.
When it comes to the management of pest animals it is extremely important to
look into their life cycle, physiology, natural enemies, reaction to
chemical substances and how this is influenced by environmental factors.
MEALY BUGS
and SCALE INSECTS belong to the
order Hemiptera; they are deleterious and prolific (up to eight
generations per year); they suck the plant sap through a piercing-sucking
mouthpart (stylet) simultaneously injecting saliva thus weakening the plant,
causing epidermal discoloration and increasing its vulnerability to sunburn.
Other symptoms are an increment in the respiration rate and damages to the
apex and basal part of the stem as well as to the roots. They are covered in
a waxy coating, some having the appearance of cotton wool, others of small
bumps. They number a few hundred species but those attacking cacti are
Diapsis echinocacti (cactus scale, family Diaspididae), Eriococcus
coccineus (woolly cactus scale) and Hypogeococcus festerianus or
pungens (cactus mealy bug) both in the family Pseudococcidae as well as
Icerya purchasi and Gueriniella serratulae (family
Margarodidae). Coccus hesperidum is known to attack Euphorbias and
Bromeliads. Hypogeococcus festerianus has been inadvertedly
introduced from the Canary Islands into continental Europe around the ‘80s.
This species is a serious threat to cacti; in affected plants growth is
distorted if not arrested and clumps of new shoots may arise from the
tubercles. It can be distinguished from other mealy bugs by its pinkish
colour and smaller size.
All mealy bugs can be recognized fairly easily and when squeezed they ooze a
yellowish liquid.
The sugary liquid waste(honeydew) excreted by these parasites attracts ants
and is an excellent medium for pathogenic fungi which eventually cause
cryptogamic diseases like sooty mould. If allowed to proliferate
unchecked they are likely to kill the affected plant. Males move by means of
legs and wings so they can easily reach nearby plants. The small nymphs, an
immature stage of the insect, are just as mobile and take advantage of the
wind to be dispersed and expand the colony. Female mealy bugs have neither
wings nor legs but they usually possess glands that secrete wax which covers
and protects the eggs. They thrive in a warm and dry environment preferably
with mild winters which they spend inside a protective waxy coating.
Some scale insects are of commercial value, such as Coccus cacti,
which is used to make a red dye called ‘carmine’, or Laccifer lacca
(Tachardia lacca) which produces Indian lac.
A possible way to control the parasite in case of small localized
infestations is mechanically removing the insects or dabbing them with a
toothbrush or cotton bud dipped in methylated spirit which melts their
protective coating. Biological control with ladybugs (Coccinellidae)
and mites (Trombidiidae) in an enclosed environment like that of a
small greenhouse is not advisable as it is likely to give rise to biological
balance problems. The recommendation is to use indigenous insects, not
exotic ones as the latter may pose a real threat to the ecosystem. On the
other hand, chemical control, usually done during spring-summer, utilizes
organophosphate products containing malathion (Fenix), diazinone
(Basudin), dimetoate (Rogor, Digotan), fenitrothion (Fenitan), parathion,
fosalone, or endosulfan, paradichlorobenzol, acephate, carbaryl,
imidacloprid (Confidor, Provado), pyrethrins while during the winter
rest it is best to treat with polysulphur of Barium or Calcium. In
order for the chemical compounds to be really effective, protective barriers
like the fluffy mass of wax or the encrustations produced by the parasite
must be eliminated. That is why the abovementioned pesticides usually
contain denaturated alcohol, wetting or adhesive additives.
Mealy bugs are far more dangerous if they establish themselves below the
ground feeding on the plant roots (Rhizoecus falcifer, Hypogeococcus
barbarae, H. othnius, H. spinosus), favoured by dry conditions in the
soil, thus making themselves undetectable until growth is arrested first and
then the plant begins to show signs of illness. The remedy is to wash
the plant with a jet of water until all soil is removed and then immerse it
in one of the specific pesticides already mentioned; let it dry out
completely then repot with new soil.
Prevention: carefully control any new plants you intend to introduce into
your collection, roots included; it is also recommendable to keep it under
quarantine; avoid adding peat or organic matter to soil mixes; do not leave
the soil bone dry for too long; a common cause of contagion is repotting
with old soil as this might be infected with parasites which are transferred
in the process; clean and sterilize used pots and containers with a diluted
bleach solution (1 part bleach to 10 parts water); wash and sanitize your
hand thoroughly before handling other plants.
RED SPIDER MITE.
This tiny phytophagous eight-legged mite
(Tetranychus urticae), actually not a spider, measures 0,3 mm (0,012
in) approximately therefore can only be observed through a magnifying lens.
It thrives in warm and dry conditions and it spins a fine web, preferably on
the upper part of the plant stem where tissues are softer; cacti that are
most likely to be attacked are Rebutia, Lobivia, Coryphantha and
occasionally Melocactus, Sulcorebutia, Mammillaria, Lophophora,
Turbinicarpus, Pelecyphora. Susceptible plants are also some
Mesembrianthemums and caudiciforms. It sucks the plant sap after piercing
the epidermis with its mouth parts allowing pathogenic fungi to penetrate;
it also intoxicates the host with its gland secretions and cause great
damage because of its rapid diffusion under favourable conditions. The
affected part dries up and turns almost grey with a reddish tinge and later
cracks pushed by new growth.
Spraying water from time to time helps to prevent the parasite from
establishing itself on the plant as it notoriously keeps away from humid
places. Biological control is achieved using a predatory mite,
Phitoseiulus persimilis, which can be purchased from biocontrol agents
producers. Chemical treatment uses acaricides like kelthane, dimetoate,
organophosphate insecticides. Unfortunaltely, the massive application of
these products has resulted in the development of mite strains resistant to
a wide range of chemicals. A more targeted treatment consists of two
applications separated by a 15-day interval, the first one aimed at adult
insects with dicofol, the second one at the egg with dienochlor.
It is advisable to clean and sanitize the greenhouse at the very
beginning of the growing season spraying pyrethrins or burning
sulphur.
  ROUNDWORMS.
These invertebrate, worm-like organisms are called
Nematodes;
their body is elongated, unsegmented, filamentous, either cylindrical or
fusiform and covered in a thick chitinous cuticle and has an internal
cavity. Normally they show sexual dimorphism and most species are
oviparous. After a few moults, generally four, the larvae reach maturity.
The most common species are Meloidogyne javanica, Heterodera cacti
and Globodera spp. They prosper in moist, fresh, rich soil; if
conditions become unfavourable, nematodes enclose themselves in a cyst in
which they can survive for quite a long time. Some of them can enter plant
roots blocking sap circulation, causing masses of woody tissue (galls) to
form and eventually plant death. This leads to infection which can be
determined by viruses (blisters), insects (Diptera, Hymenoptera, Rincota),
mites, bacteria (outgrowths, galls, cankers), fungi (blisters, cankers).
Symptoms: affected plants stop growing, turn yellow and production or
development of flowers is arrested; That is why, if a plant looks sickly,
the first thing to do is to check the health of its roots, repotting the
specimen if necessary.
The best treatment is to soak the plant in water at 50°C (122°F) for 20
minutes. You might also try using halohydrocarbons and
organophosphorates. Remove all infected roots cutting them as close as
possible to the root collar and treat the plant as if it were a cutting.
Eliminate all the dead parts of the plant as well as the soil and pot; in
the most serious cases you might have to destroy the entire plant due to the
high transmissibility of the disease to nearby plants. Planting marigold
(Tagetes sp.) where ringworms have been spotted is useful as a
biological remedy to limit their spread.
 SCIARA
FLY.
It belongs to the order Diptera characterized by having one pare of
wings only, while the hind wings (halters) are sensory organs whose
function is to stabilize flight. It has piercing-sucking mouth-parts. Its
larvae looks like tiny transparent worms (about 6-7 mm / 0.24-028 in long)
with a black head and no legs and feed on vegetal organic substances. The
adult insect is a small black fly measuring 3 to 4 mm (0.12-016 in) in
length; some female flies generate males only, others females only because
they lack certain chromosomes. They attack roots and plant collar causing
great damage especially to seedlings. They occur mostly in peaty soils; both
adults and larvae can be eliminated with a suitable insecticide.
APHIDS.
These insects, belonging to the order
Hemiptera,
are polyphagous, green or black-coloured, and very prolific; they do not
often attack cacti except sometimes the flower parts. Here are some among
the most common together with the species most likely to be targeted:
Aphis gossypii for Cucurbits, Aphis nerii for Asclepiadaceae and
Apocinaceae, Aphis sedii for Sedum, Macrosiphum euphorbiae for
Spurges and lastly Aleophagus myersii for Aloe and Haworthia. The
attack results in a general weakening of affected plants as well as a
possible diffusion of viral, fungal or bacterial infections. In addition,
the sugary secretion (honeydew) as it dries up favours the formation of
sooty mould and the species Eriosoma lanigerum may also cause
malformations. They can be eliminated manually, using soapy water (50 gr.
Marseille soap per litre of water), an infusion of tobacco leaves or a
chemical insecticide (rotenone) which you will need to change quite
often because more resistant strains of aphids are likely to develop every
few generations.
  
THRIPS.
Belonging to the order Thysanoptera, these tiny insects that measure
around 1.5 mm (0.06 in) have a flat body, narrow wings and are
characterized by exceptional motility; they show a marked preference for
cacti pollen. The thrip Frankliniella occidentalis is distinctly
polyphagous and attacks not only flowers but also leaves and fruits. It
injects its saliva, piercing the plant epidermis to feed but also to lay
eggs. By doing so it causes flowers to dry up and is responsible for
malformation of petals, leaf margin necrosis, rusty discolouration, scars
and can vector TSWV (tomato spotted wilt virus). Female thrips are larger
than males and can oviposit without mating, usually about fifty eggs inside
petal tissues. After ten days or so, depending on the temperatures, the
nymphs burrow below the ground developing into pupae first and then into
adult insects. Normally the reproductive cycle is repeated 5 to 7 times a
year. Two other species worth mentioning are Heliothrips haemorrhoidalis
and Thrips tabaci. Recommeded as biological remedies are chromotropic
traps, sticky and blue-coloured, the bioinsecticide Naturalis or a
mixture of Marseille soap and quassia extract; alternatively
use a pesticide (dimetoate). The most important natural enemies of
thrips are the mite Amblyseius cucumeris (Phytoseiidae) and the bug
Orius
laevigatus
(Anthocoridae).
CITRUS FLATID PLANTHOPPER.
It’s a small insect in the order Homoptera, family Flatidae,
introduced from North America
into Europe in the early 80s. Metcalfa pruinosa is completely white
after emerging from the egg and as it develops it turns light green becoming
whitish again later because of the waxy coating that covers its body; the
exuviae (remains of exoskeleton after moult) are quite noticeable on the
stem. The adults are a greyish white and become more grey as they grow to a
maximum length of 7 mm (0.28 in); they are able to jump and fly and possess
a strong buccal apparatus which they use to pierce the plant and suck the
sap. Nymphs develop around mid-May and live on the underside of leaves of
succulents while the adults appear by June and secrete a whitish waxy
substance accompanied by honeydew and sooty mould. The
parasites show a gregarious behaviour and usually line up along the plant
stem. They disappear as the weather turns cooler after laying eggs in bark
fissures. Conventional pest management entails the use of the same
insecticides recommended against mealy bugs applied three times starting in
early May with a one-week interval between each application. Biological
control avails itself of the natural enemy, the insect Neodryinus
typhlocybae. Another natural remedy to be used early in the season (May)
is to direct a forceful jet of water onto affected plants, best if mixed
with potassium nitrate so as to melt the waxy coating protecting the
immature stages of the insect.
 
WHITE FLIES.
The tiny white flies are native to tropical regions but their ability to
cope with cooler climates has allowed them to spread over a much wider area.
They stay on the underside of leaves of succulents, caudiciforms and
succulent pelargoniums and fly away when the plant is shaken. They
suck sap using their mouth weakening the plant, retarding flowering, causing
the formation of yellow circular spots, producing honeydew and consequently
sooty mould as well as vectoring viruses and bacteria. The species
which is most commonly encountered in our greenhouses is Trialeurodes
vaporariorum, whose females can lay some 200 eggs on the underside of a
leaf. The nymphs hatch after incubation for approximately ten days and pass
through four instar stages before becoming adult insects; the whole process
lasts nearly a month. Placing yellow sticky chromotropic traps ensures good
biological control. Aphicides remain the most successful treatment (dimetoate,
malathion, acephate, imidacloprid) although the parasite protective
coating might reduce the effectiveness of the products. At least three
applications should be made with a one-week interval between them so as to
kill also newly hatched insects. The active principle should be changed from
time to time since the parasite tend to develop a resistance to the
insecticide. Good results have also been achieved alternating treatments
with mineral oil and with a solution of water and 0.25% of laundry
detergent. Encarsia formosa, E. tricolor and Chrysoperla caenea
are their natural predators.
SNAILS and SLUGS. These gastropod molluscs belonging to the
family Helicidae have a well developed foot secreting a mucous substance
that enables them to glide over a surface; they are easily spotted because
of the silvery trail of dried mucus they leave behind. They are
hermaphrodite but most of them still reproduce by mating with another
individual; they have lungs and some develop a single dorsal shell. Among
the numerous species we have to mention Helix pomatia, quite common
throughout central Europe as well as H. adspersa and H. pisana
frequently encountered in Italy. They constitute a threat to
succulents, especially once they have been moved out of the greenhouse or
where they are permanently grown outdoors; they usually crawl out after dark
and eat fleshy leaves, cladodes, tender shoots and seedlings spoiling the
appearance of plants. They can be removed manually or use shallow containers
filled with beer as baits: slugs and snails are attracted to it and will
fall into the liquid and drown. In case of massive infestation sprinkle some
poisonous slug pellets (acetic metaldehyde).
ANTS. Belonging to the family Formicidae, ants have both sexes
but females can either be fertile or sterile. Fertile females lose their
wings after having performed a nuptial flight and mated while the males soon
die. The egg passes first through a larval stage then becomes a chrysalis
until they finally reach maturity. Many species may choose to establish
their long-lived colonies in a raised bed or large pot digging their
galleries in the soil and causing damage to the roots; others are just
solitary predators. They collect aphid eggs so that they can rear them
inside the nest because the sugary honey-like substance excreted by aphids
when palpated on the abdomen by ants with their antennae is a valuable food
source. Therefore ants can be held accountable for tending harmful insects,
carrying away seeds from trays and indirectly damaging roots. Use an
insecticide like carbaryl if necessary.
      LEAF-EATING
CATERPILLARS. The definition includes the larvae of Lepidoptera
(also comprising butterflies) which possess chewing mouth parts. While in
the pupal stage most species spin a cocoon inside which the insect undergoes
the final metamorphosis. During the larval stage many of them are
phytophagous and quite deleterious, especially those characterized by
nocturnal activity. These voracious pests are variable in size and colour
and can appear in the spring, summer or autumn, depending on the species.
The preferred food of caterpillars are young plants, succulents, fleshy
leaves, flowers and seedlings. Remove manually if there are still few of
them otherwise you might have to apply chemical products like
Imidacloprid, Diflubenzuron, Alphamethrin, Endosulfan.
 COMMON
ROUGH WOODLOUSE.
Porcellio scaber is the scientific name for this very common insect
belonging to the order Isopoda; it has a rough shell-like
exoskeleton, two tail-like appendages and a pair of short antennae. They do
not directly harm plants but since they usually live in colonies they might
cause disturbance to seed germination and seedling growth. They can easily
be got rid of by hand or lured away using a potato which is something they
really crave.
INADEQUATE CULTIVATION
Light.
Insufficient light levels during the growing period cause plants to develop
spindly shoots and take on a yellowish appearance due to lack of
chlorophyll.
This phenomenon is known as etiolation and results in general weakening and
irreparable disfigurement of plant.
On the other hand, placing a plant in full sun too suddenly without allowing
it to acclimatize to increasing light levels causes the epidermis to get
sunburned and permanently marred. All this can be avoided by gradually
exposing them to more sunlight when moving them outdoors in the warm months
at first providing some shade during the midday hours. In doing this we must
take account of the conditions which our plants are used to in their
habitats, protecting from intense light those that live in the tree canopy
or find shelter among rocks, bushes or tall grasses. Some species, if
exposed to full sun during the winter months, may take on a reddish hue but
this is not in the least detrimental to the plant health.
Water.
If plants are watered too sparingly their tissues lose turgor and stems
appear withered and start to bend; epiphytic cacti from tropical and
subtropical forests are known to be more prone to this.
The remedy is watering and spraying on a more regular schedule. On the other
hand, waterlogging and excess moisture often cause rot; keep in mind that
succulent plants are more likely to be killed by excessive water than by
lack of it. Moreover, water that has a high mineral content, particularly in
calcium, causes the roots to suffocate in the long run.
Humidity.
Excess air moisture, dripping water from condensation on the greenhouse
covering, poor ventilation are the main causes of rotting and mould
formation, especially during the winter.
Only species that are native to forest of South East Asia require higher
temperatures and humidity. During the warmer months it is advisable that
such plants (Hoya, Dischidia, etc.) be placed on large pot saucers filled
with gravel kept constantly moist and sprayed frequently with non-calcareous
water.
Temperature.
Every species, during its evolutionary course, has adapted to surviving in a
different temperature range, which is more extreme in subarctic or
high-mountain regions and constantly decreases as we proceed towards the
Tropics, characterized by more even temperatures. If we go below the
critical point the plant juices freeze and expand thus destroying the cell
walls and causing plant death. In less serious cases the plant epidermis
might remain permanently blemished by dark spots. The recommendation is that
you never allow the temperature to go below the critical point the plant is
known to withstand in its habitat and that you also reduce watering
frequency in the autumn until you stop when temperatures drop.
Excessive heat can cause scorching of leaves and stems and also sunburn
which can scar plants irreversibly and subsequently expose them to fungal
infections. If damage is severe and the plant loses too much moisture, this
may be fatal. Such injuries are suffered by cultivated plants especially in
the spring when they are moved into full sun after spending the winter in
most cases under low-light conditions; of course young specimens and
seedlings are even more susceptible. It is also very likely to happen inside
a poorly ventilated greenhouse. Finally, cacti that have been overwintered
in an unnaturally warm environment such as an heated room are also at risk
of being severely damaged.
Soil.
Generally, the majority of succulents do not need a type of soil identical
to the one found in their habitat, instead they make do with a well-drained
mix with little humus and a nearly neutral pH that can provide good air
circulation around the roots. Obviously there are a few exceptions:
Aztekium, Geohintonia and some Thelocacti, for instance, which require
chalky soil or plants living on the forest floor or on tree branches below
the canopy which prefer humus-rich soil or finally some others thriving in
calcareous or quartzy soil.
Unsuitable soil may cause, in the worst case, irreparable damage as it
usually happens with a peaty mix which does not allow water to drain quickly
thus favouring the insurgence of rot. Iron or other micronutrients
deficiency, substrates that are too alkaline or too acidic, lack or excess
of minerals along with other factors may hamper or slow down plant growth,
hinder flowering, result in yellowing of the epidermis and lastly impede
root development. The remedy is to remove the old soil and repot the plant
with a suitable mix. If roots have been irreversibly damaged the only way to
save the plant is rooting it as a cutting or grafting it onto a proper
rootstock.
Feeding.
Succulent plants usually occur in regions with low rainfall and this means
that they are not able to absorb a large amount of minerals; if fertilizer
is applied to cultivated succulents in large quantities it accumulates in
the soil lowering its pH and disrupting the osmotic balance. This weakens
the plant, makes it more susceptible to parasite attacks and in more serious
cases it might also lead to yellowing, wilting and even rotting of the
specimen.
Apply fertilizer only during the growing season and not too frequently; it
should contain micronutrients and be low in nitrogen with a 1:2:4 ratio
(nitrogen, phosphorus, potassium respectively). The recommended
concentration is 1 gr. per litre of water (1/1000). Epiphytic cacti do well
with a bit more nitrogen, a lower concentration of nutrients and more
frequent applications.
Pesticides.
Usually the manufacturers of these products provide instructions for the correct use and
dosage on a number of plants but fail to include succulents so unless we
know for sure that a certain active principle is not harmful to our plants
it is always advisable to test it on a single specimen first, sprayed or
applied through watering in case it is a systemic.
**************
SEED DISINFECTION
Most often the seeds we buy have not been disinfected and this is the most
likely cause of bacterial, fungal and viral infections. The simplest way to
eliminate the risk is sterilization which consists in treating the seeds
with one of the following powdered products: copper carbonate,
mancozeb, maneb, propamocarb, metalaxil, m etiram, zineb, thiram, captan
etc. Sprinkle a thin layer of product over the seeds.
PHYTOSANITARY
PRODUCTS
They have been classified by the European Community into seven toxicity
categories: T+ = very toxic; T = toxic; Xn = harmful;
Xi = irritant; F = highly flammable; O = oxidizing;
N/C = not classified. Toxicity is expressed as L.D. 50 (lethal dose
administered to rats via oral route measured in
milligrams per
kilogram of body weight). You might need to
get a license to use certain substances.
Some may be toxic, mutagenic or carcinogenic. An active principle can be
commercialised under different names.
According to the way the substance is delivered into the plant body,
chemical products are grouped into the following categories:
- Contact products (or protectants): they are active only on the plant
surface and do not penetrate into tissues.
- Cytotropic products: the substance penetrates only partially and is not
translocated into the vascular system.
- Cytotropic-translaminar products: penetration occurs at a deeper level and
the substance reaches the opposite side of the leaves.
- Systemic products: they are absorbed into the plant tissues and
transported via the vascular system to cells throughout the plant.
Notes
about some phytosanitary products.
-
Inorganic fungicides (copper and its derivatives, sulphur) have a
broad-spectrum activity and high persistence; they act as an exterior shield
that hinders direct penetration by fungi although, under certain conditions,
they might stop plant growth. Sulphur exerts its action attacking the
pathogen’s cell membrane and is particularly effective against powdery
mildew. It should be applied when temperatures stay between 12 and 28°C
(54/82°F); avoid using it on Cucurbits as it is harmful to them.
- Contact and protectant fungicides such as carbamic acid derivatives
(zineb, maneb, mancozeb, metiram, propineb as well as ziram
and thiram) are less harmful to plants than copper fungicides; they
inhibit fungal respiration and are successful against Helminthosporiosis,
Monosporiosis, Septoriosis, Anthracnosis and root rots. They lose efficacy
after 8 to 10 days.
Carbamate, organonitrogenous and aromatic ester compounds containing
Benfuracarb such as Oncol® and Furacon® have a systemic
action and should be used at the beginning and at the end of the growing
season as soil disinfestants.
Derivatives of terephtalic acid (captan) are broad-spectrum
pesticides exerting their action on enzymes and on the Krebs cycle.
Dicarboximides (iprodione etc.) are quite effective against
Rhizoctonia, Alternaria and moulds, especially if combined with thiram.
Guanidine derivatives (dodine) are usually employed against
various pathogenic fungi.
- Systemic fungicides like benzimidazole derivatives (benomyl,
carbendazim, thiabendazole, methyl thiophanate, etc.) have preventive (protectant)
and curative (eradicants) properties, a broad-spectrum activity and good
sistemicity; they are also able to protect the new growth that has developed
after the treatment. These substances are taken up by roots and quickly
transported to the aerial parts. They are active against Alternaria,
Septoriosis, Anthracnosis, Coniothyrium, rusts, Fusariosis, rots and moulds.
However, only a single point mutation in a particular gene is needed for the
pathogen to completely neutralise the activity of these chemicals therefore
it is always better to mix them with a contact fungicide.
Phenylamides are both protectants and eradicants but they too give
rise to resistant strains.
Carbamates (propamocarb) are used as soil disinfestants and against
collar rot.
Thiadiazoles (etridiazole) are useful in disinfecting the soil and
work well as protectants for seedlings.
The group of Triazole fungicides is comprised of a number of
chemicals among which is Penconazole, an effective treatment against
many fungi.
- Chinosol applied to the seedbed might delay germination so it is
best used after the seedlings have emerged from the soil.
- Emulsionated mineral oils, mixed with phosphoric esters, are usually
recommended as good contact insecticides against planthoppers, scale insects
and mealy bugs as well as mite eggs. Avoid applying the product during the
warmer months and don’t let it come into contact with the soil as this might
cause root asphyxia.
- Organophosphate insecticides (malathion, diazinone, dimetoate,
parathion, etc.) should not be used on Crassulaceae or any other plant
whose leaves have a hairy or waxy covering if you don’t want to spoil their
beauty. Due to its toxicity, dimetoate has been banned in many
countries.
BIOLOGICAL CONTROL AND NATURAL REMEDIES
Unfortunately biological control, which avails itself of natural
enemies of insect pests, is little help to the amateur grower owning a small
greenhouse because of the difficulty of identifying the pest accurately and
creating a balance between the insect and its natural predator, the
expertise that this requires and lastly the higher costs. In larger
greenhouses, important collections and botanical gardens biological
solutions can be profitably employed within an integrated pest control
program which combines different strategies such as hygiene, phytosanitary
protection, environmental monitoring, the use of highly targeted chemicals
and so on. You might find it useful to refer to the Phytosanitary Index
published by A.C.T.A.
To fight mealybugs the lady beetle Cryptolaemus monstrouzieri
is generally released in association with Leptomastix dactylopii,
Kaladiplosis floridiana, Anagyrus sp.; an alternative might be Nephus
riunion or Scymmus (also useful against aphids). In large
greenhouses pest control is achieved introducing antagonists like
Allothrombium fuliginosum, Rodolia cardinale, Chilocorus bipustulatus.
Scale insects belonging to the genus Diapsis (Diapsis
echinocacti - cactus scale) are usually fought with control agents like
Aspidiotus nerii.
On the other hand there seems to be no specific predator for root mealy
bugs.
Aphids of the genera Aphis gossypii and nerii are
attacked by the Hymenoptera Aphelinus abdominalis and Lysiphlebus
testaceipes.
Larvae of thrips are preyed on by the mite Neoseiulus cucumeris
which, however, is less active in the peak heat of summer.
The red spider mite (Tetranychus urticale) can be controlled
with the help of the predatory mite Phytoseiulus persimilis, although
this treatment generally has a slow response time, and Amblyseius
californicus, which on the other hand may not survive low winter
temperatures.
The amateur growers can more easily and profitably employ these other
natural remedies:
Ants, which feed on honeydew and favour the proliferation of mites,
scale insects and aphids, can be managed by using poison baits prepared
mixing honey with avermectin, a natural insecticide which does not
pose significant risk to man or the environment and leaves no traces.
Against aphids and mites use a potassium soap like Marseille
soap (50 gr. per litre of water with a neutral pH). Alternatively you might
use nicotine (macerate a few cigarette butts until the solution turns a
tea-like colour then filter it) or garlic (boil a whole head in 500 cc. of
water until soft, then filter).
Infestations of scale insects and citrus flatid planthopper
can be treated using a solution of water and Marseille soap (50 gr. per 100
cc.) additioned with 900 cc. of denaturated alcohol.
Naturalis,
a bioinsecticide based on the fungus Bauveria bassiana, is effective
against white flies, red spider mite, aphids and thrips;
spread the product over affected parts. The insects die from dehydration. It
is commercialised as oil suspension which is harmless to man and the
environment including pollinating insects. Moreover it leaves no trace on
plants so no withholding period has to be observed.
The following substances are known to have antiseptic properties,
sometimes both antibacterial and antimicotic, especially if used
preventively.
Horsetail (Equisetum sp.): an anticryptogamic useful against
fungal diseases (rusts, blackspot, anthracnosis) which also stimulates the
plant biological processes. Preparation: leave a spoonful of powdered
product to macerate in a litre of water for two or three days. After that
boil it for approximately 20 minutes then filter. Use: mix one part of the
solution with three parts of water before spraying plants.
Propolis extract: it is a natural antibiotic that inhibits the growth
of moulds and bacteria and has disinfecting and wound healing properties.
Preparation: add 50 drops per litre of water and apply it on cuts, wounds,
graft joints or use it to drench the seedbed. Soy lecitine is often added to
the mixture (one tablespoon per litre).
Grapefruit extract: effective against fungi, bacteria, viruses,
collar rot. Preparation: 30 drops per litre of water, with the addition of
10 drops per litre of cypress essential oil and 30 drops per litre of
propolis hydroalcoholic extract.
Essential oils: they have antiseptic properties, especially the ones
extracted from thyme, cypress and pine. Use: these mild insecticides are
effective against the eggs of mealy bugs, white flies, mites and several
other insects. Preparation: mix 15 grams in one litre of water adding one
teaspoon of Marseille soap.
Sodium bicarbonate: it has antifungal action. Preparation: one
teaspoon per litre of water with the addition of an essential oil.
Sodium silicate: it is an insecticide, acaricide and fungicide used
to fight mealy bugs, mites, downey mildew, powdery mildew. The parasite dies
from cell dehydration. It is sold as aqueous solution of sodium
tetrasilicate (38/40° Bé). Dosage: 30 gr/lt of water in the winter; 10
gr/lt in the growing season.
Bitter Quassia: an aphicide insecticide with repellent activity whose
characteristics are similar to those of pyrethrum although is not harmful to
man, pets and pollinating insects. It is useful against aphids, sawflies,
psyllids, codling moth, olive moth. It is commercialised in the form of 15%
acqueous solution; dissolve 7 grams in one litre of water.
Azadirachtin: an insecticide and repellent capable of inhibiting
insect growth, reequilibrating the soil microflora and killing roundworms.
It is available as 15% aqueous solution of Azadirachta indica; mix 10
grams per litre of water and add 7 gr. of sodium silicate.
Nettle: a phytostimulant insecticide with a high content of
formic acid, salicylic acid, iron and micronutrients. It acts as a repellent
against mites and various insects. It is sold as 15% aqueous solution of
Urtica dioica (stinging nettle) and Urtica urens (dwarf
nettle); mix 7 grams per litre of water with the addition of a teaspoon of
Marseille soap and apply during the growing season.
Wormwood (Artemisia sp.): it acts as biorepellent against ants and
ground dwelling insects. Sprinkle some of the powder around the stem and on
the root collar once a month.
Copper sulphate: it is an anticryptogamic with antifungal action,
effective against alternariosis, cladosporiosis, cankers, blackspot, downey
mildew, coryneum blight. Mix 15 grams per litre of water and apply during
autumn or winter.
**************
ENDOTHERAPY (low
environmental impact treatment)
It is a method for treating plants by means of systemic products which are
transferred into the plant vascular system. This way the substance is not
washed off the plant and dispersed in the environment and you should only
need to treat once or twice a year. They can be applied in irrigation water
or, if the plant is a tree, injected into the trunk with a similar procedure
to that followed in intravenous therapy.
Presently, the registered systemic products are: Acephate, against
scale insects; Imidacloprid, against aphids and scale insects;
Methomyl, against aphids; Thiabendazole, a wide-spectrum
fungicide.
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