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General
Production Information
Idaho ranks third in U.S. hop production accounting for 8%
to 10% of the U.S., and 2% of the world hop production. Idaho
hop production from 1993 to 1996 averaged 1,388 pounds per
acre on 3,977 acres. Total production for that period averaged
5,521,210 million pounds with an on-farm value of $8,889,148
million dollars, annually. In 1998, production dropped well
below that average to 4,529,000 pounds on 3,909 acres with
a total farm-gate value of 6,838,394. Establishment costs
for a hop yard range from $2,950 to $3,885 per acre. Production
costs for an established yard range from $2,103 to $2,890
per acre. Gross returns have averaged $2,236 per acre since
1991.
Over 90%
of the crop is generally contracted at the time of harvest.
Some contracts prohibit the use of certain pesticides on the
contracted crop, in order to meet specific brewing industry
requirements or to comply with the import tolerance requirements
of importing countries. In a given year 40% to 60% of the
crop is exported to overseas markets.
Production
Regions
Hop production in Idaho is concentrated in two geographically
distinct areas: the cool, moist region of the northern Idaho
panhandle in Boundary County (53 %) and the warmer, arid region
of southwestern Idaho in Canyon County (47 %). Climate, soil
type, hop varieties, and therefore, hop production practices,
vary greatly between these two areas.
General
Information
Hop is a specialty crop produced for the female flowers, or
cones, which either raw or processed, are an essential ingredient
in the production of beer. Lupulin glands on the hop cones
contain soft resins (a and b acids) essential oils that impart
bitterness, flavor, aroma, foam (head) characteristics, and
preservative qualities to beer. The total amount and percentage
composition of these compounds varies with variety and growing
conditions. Because the brewing industry depends on hops to
provide distinctive and proprietary characteristics to beer,
a stable supply of high quality hops is a high priority.
Hop, Humulus
lupulus L. (Urticales: Cannabaceae), is a perennial plant
related to nettles and cannabis that produces climbing annual
stems from a perennial rootstock and crown. The stem grows
in a clockwise direction around its support and may reach
a total length of 25 feet or more in a single growing season.
The stem dies back to the crown after the hop flowers mature.
Hop is dioecious, producing male and female flowers on separate
plants. The commercial hop is a female plant with flowers
(burrs) produced on side arms that develop along the stem.
Burrs develop into hop cones. Fertile male plants are not
tolerated in commercial hop yards as their pollen causes seeds
to be produced reducing the brewing quality of the cones.
Hops are vegetatively propagated, with new yards established
by planting root cuttings (rhizomes) or, occasionally, softwood
cuttings.
Cultural
Practices
Hop plants are grown on a wire and cable trellis suspended
about 18 feet above the ground on a regular arrangement of
poles. Cement anchors, attached to trellis cables and buried
five feet deep, surround the yard and hold the trellis upright
under the weight of the developing crop. Plant spacing is
either wide, with 14 to 15 feet between rows and 3.75 feet
between plants with in rows, or narrow, with plants set 7.5
feet apart on a regular grid. With either planting arrangement
there are approximately 55 poles and 900 plants per acre.
Once established, the hop rootstock will produce indefinitely
although industry practice is to rotate plantings every 10-15
years. Timing of rootstock replacement is influenced by declining
yield caused by insect and disease and pests and by brewer
demand for specific varieties. The major cultural practices
used annually to produce hops include pruning, stringing,
training, irrigating, and harvesting. Each of these is discussed
below.
Pruning
is an annual spring practice used to hold back the vigorous
new annual growth until the proper training date for that
variety. Pruning begins in late March and is accomplished
either mechanically or chemically. Mechanical pruning uses
tractor-drawn equipment with spinning steel "fingers,"
to remove early vine growth, debris from the prior season,
and leave a clean, surface from which the new shoots will
arise. Chemical pruning involves the use of desiccants to
kill back early vine growth. Fields pruned chemically are
often 'scratched' with a harrow to remove surface debris.
Stringing
the trellises begins in early April as seven-man crews using
tractor-drawn elevated platforms tie the coir (coconut husk
fiber) twine to overhead trellis wires and secure the lower
end of the twine into the hop crowns with small metal clips.
Training
is the practice of wrapping the hop shoot in a clockwise direction
around the stringing twine to facilitate rapid vine growth.
Training begins in early May and is by the end of May. Due
to the relationship between plant height and day length that
determines flowering time, the training date is one of the
most critical factors in determining yield. Training date
is variety specific. Hop vines (or bines) in narrow spaced
fields must be tied together, or arched, 6 ft. to 8 ft. above
the ground in late spring to facilitate crop management activities.
Irrigation
of hop fields begins in the latter part of May or early June,
depending on weather and growing area. The hop field will
require approximately 30 inches of water during a normal growing
season. Various methods of irrigation are utilized, including
rill, sprinkler and drip. In Idaho most irrigation is by rill
method, where water is siphoned out of head ditches into smaller
ditches (rills) alongside the rows of hop plants.
In rill
irrigated hop yards, cultivation for weed management, and
to mechanically maintain hill size and rill integrity, occurs
four to six times during the season. Drip irrigated hop yards
are generally cultivated fewer times per season.
Harvest
begins in late- August, and progresses through late-September
with each variety reaching peak maturity at a different time.
Harvest begins in the field as the hop vines are cut at the
ground and at the overhead support wires, and are placed into
a trailer or truck bed. The vines are transported to stationary
picking machines that are capable of picking 8 acres in a
single 10-12 hour shift or 15 acres if picking runs round
the clock. Most U.S. hop growing operations have one picking
machine for each 250-300 acres of hops.
The vines
are hung upside down on hooks and carried into the picking
machine, where hops and leaves are stripped from the vine
and sent through a series of cleaning devices to remove leaves
and other debris.
The stripped
vines and other debris are chopped and spread back onto the
fields and service roads. To date, this activity has not resulted
in the build up of disease or insect pest in hop yards. The
introduction of hop powdery mildew into the Pacific Northwest,
this practice may force growers to change this practice. Powdery
mildew cleistothecia (spores from sexual reproduction between
two different mating types) can exist on dead plant debris.
If powdery mildew cleistothecia become common other methods
for disposing of plant debris may need to be found.
Cleaned
cones are transported by conveyor belt to the hop kilns. Kiln
floors are each approximately 32' x 32', and hold some 15,000
pounds of hop cones. Cones are spread to a depth of about
32 inches. Once the kiln is filled, cones are dried as hot
air (140°F) from oil or gas burners is forced through
the bed of green hops. The drying process requires about 9
hours, reducing the hops to 30% of the green weight, with
8-10% moisture content. Hops are removed from the kiln floor
and cooled for 24 hours. After cooling, the hops are compressed
into 200-pound bales, wrapped in burlap, subjected to quality
inspection, and transported to cold storage warehouses.
IPM
Programs
The hop industry has received an EPA PESP grant and is in
the process of collecting information for the purposes of
building an industry-wide IPM program.
Resistance
Management Strategies
The
hop industry is actively pursuing three alternate chemistries
for each major pest of hops for the purposes of resistance
management.
Insect
Pests
Regardless of production practices, arthropods represent a
major factor limiting hop production in Idaho. Although numerous
arthropods are known to attack hop, the most serious pests
in the Idaho hop-growing region are the twospotted spider
mite, Tetranychus urticae, the hop aphid, Phorodon humuli
(Schrank) (Homoptera: Aphididae), the black vine weevil, Otiorhynchus
sulcatus (Fab.) (Coleoptera: Curculionidae), and the California
prionus, Prionus californicus. A review of the life cycle,
damage to hops, and current management practices for each
of these arthropods is provided below. Hop aphid and two-spotted
spider mite are the two most important pests. The majority
of efforts to control non-disease hop pests are targeted at
these two species.
The
twospotted spider mite, Tetranychus urticae
Damage
to hop. Spider mites damage hops by feeding directly on hop
leaves. Leaf feeding by spider mites results in silvering
and browning of hop leaves, and reduced plant vigor. Severe
infestations can cause complete defoliation and are accompanied
by heavy production of webbing that can hinder chemical and
biological control efforts. Most economic damage, however,
is associated with spider mites feeding on hop cones. Spider
mites not only contaminate the cones by their presence, but
their feeding results in dry, brittle, discolored (red) cones.
Spider mite-damaged cones tend to shatter so that both quality
and quantity of yield is reduced. When infestations are severe,
total crop loss can occur. Damaging populations of twospotted
spider mite (TSSM) are favored by hot, dry climates. In the
hop growing regions of Washington and southern Idaho, where
these conditions prevail, spider mite populations frequently
reach outbreak levels. Without control of these pests, there
would be 100% crop loss.
Management
Miticide sprays are scheduled based on scouts monitoring TSSM
populations. Various sampling schemes have been developed
to serve different purposes. Economic thresholds shift with
the season: two colonizing females/20 leaves in late June,
10 females or 50 motile forms/leaf in late July, and 50 females/leaf
in mid-August.
Chemical
Controls:
Abamectin
(Agri-Mek 0.15EC, 16 fl oz./A). 14 day PHI. This product is
the industry's main miticide. 100% of the acres are treated.
Propargite (Omite-CR, Omite 30WS). 14 day PHI. Rates of 1.5-2.25
lbs. AI/A for Omite-CR, or 1.5 lbs. AI/A for Omite 30WS. Omite,
first registered on hops in 1971, has been slowly fading in
performance. Resistance has been implicated but no definite
studies documenting resistance have been done. Approximately
5%-10% of the acreage is treated on a regular basis.
Dicofol (Kelthane MF, 1.0 - 1.25 lbs. AI/A). 7 day PHI. Used
extensively in the late 1950s until the late 1960s when mites
developed high levels of resistance. It is now of limited
importance. In recent years, researchers suggested reserving
use of this compound only for phytosensitive varieties with
one application/season spaced three years apart.
In 1997 and 1998 a Section 18 request for cyhexatin (Pennstyl
5F) was submitted but not approved. In 1999 another Section
18 request was submitted and approved. Elf Atochem is pursuing
a full Section 3 label for this compound on hops. 40% of the
total acreage was treated in 1999.
In 1998 a crisis exemption was issued for hexythiazox (Savey
50WP), but none of the Idaho acres was treated because spider
mite populations flared outside of the 60-day PHI. A 24c was
obtained in 1999, restricting use to pre-bloom applications.
Hexythiazox is an ovicide, with end use dates of July 1. The
industry estimates 1999 usage will result in approximately
10%-20% of the acres treated.
The hop aphid, Phorodon humuli
Damage
to hop
Economic damage to hop can result from direct feeding of aphids
that lowers plant vigor and productivity through the consumption
of water, carbohydrates and other nutrients being transported
in the phloem tissues on which aphids feed. If severe hop
aphid infestations are not controlled, defoliation of hop
plants and loss of yield by premature drop of hop cones can
occur. Contamination of hop cones with aphids and honeydew
are the major cause of economic damage. Growth of sooty mold
on aphid-produced honeydew discolors the hop cones, severely
lowering crop value. Large infestations can render an entire
crop unmarketable. In contrast to T. urticae, damaging populations
of P. humuli are favored by cool, moist climates. If not properly
managed, P. humuli is capable of causing serious damage to
hops grown in any of the hop-producing regions of the U.S.
P. humuli is also implicated in the transmission of several
viral diseases of hop.
Management
Insecticide sprays are scheduled based on aphid abundance
(leaf counts of less than 10 aphids/leaf). Sampling schemes
have been devised, but industry-wide firm economic thresholds
have been difficult to establish. Growers using drip irrigation
may set thresholds slightly higher than growers using rill
irrigation, as spray timing in drip irrigated yards is not
complicated by coordination of spray and irrigation schedules.
The two goals, preventing economic loss at bloom and preventing
aphids entering cones late in the season, have different thresholds.
Most hop
acreage in Idaho is treated one or two times per season although
in bad aphid years some yards may be sprayed five times. The
average probably is two times for the entire acreage. Without
control, 100% of the hop acreage would be lost to this pest.
Chemical
controls:
Diazinon
(various trade names, 1 lb. AI/A). 14 day PHI. Still the most
important aphicide in Idaho hop fields. The product provides
early season aphid control and is important as a rotation
partner to prevent resistance development to imidacloprid.
It has limited residual activity. Acreage treated about 80%-100%.
Imidacloprid (Provado, 8 fl oz of 1.6 F product/A). 14 day
PHI. This product is highly effective against but more costly
than diazinon. It works well as a foliar spray but has also
been applied under experimental use permits through drip irrigation
systems and as a shanked-in soil application with excellent
results. Such application methods may favor conservation of
beneficial organisms. Percent acreage treated is about 40%-60%.
Bifenthrin (Brigade, 0.06-0.1 lbs. AI/A). 14 day PHI. A very
effective, widely used compound used to treat about 75% of
the acreage. While it also kills some adult mites, it causes
spikes in mite populations later in the season. It has great
value to the industry as a rescue treatment for lepidopteran
pests.
Malathion (various trade names, 1.25 lb. AI/A). 10 day PHI.
Used for approximately 40 years but recent use has been very
limited, as efficacy is poor. No acreage is treated.
Phorate (Rampart 10-G, 2-3 lbs. product/A). 42 day PHI. Used
early season it can be banded over the row after crowns begin
regrowth, or incorporated 2-4 inches deep. Acreage treated
is about 10%. The registrant did not renew the registration
of this 24c in 1998. A tolerance remains and existing stocks
can be used.
A registration for pymetrozine on hops is imminent. The industry
hopes to be using this compound by the year 2000 growing season.
It is a very effective aphid control.
The black vine weevil, Otiorhynchus sulcatus
Damage
to hop
Adult O. sulcatus feed on hop foliage. Adult feeding is not
reported to result in economic loss. Economic losses can result
from larvae feeding on the roots of hop plants. Root damage
by larval results in reduced nutrient uptake, water stress,
and reduced plant growth. Premature leaf drop and plant death
have been associated with feeding damage caused by black vine
weevil larvae. Heavy infestations may require that individual
hop plants or even whole hop fields be removed from production.
Management
Currently black vine weevil is controlled by using insecticides
targeted at adult weevils. Applications are made about three
weeks after adult emergence, but before egg laying begins.
It is important to apply insecticides at night when adult
weevils are most active. No host-plant resistance to O. sulcatus
in hop has been identified. Little research has been conducted
with respect to the identification of arthropod natural enemies
of O. sulcatus in hop. However, control by several parasitic
nematodes has been demonstrated in field trials.
Chemical
controls:
Bifenthrin
(Brigade, 0.06-0.1 lbs. AI/A). 14 day PHI. A very effective
compound used to treat about 10% of the acreage. Should not
be used when mites are present.
The California prionus, Prionus californicus
Damage
to hop
Prionus californicus is widely distributed in the Pacific
Northwest and has been recorded as a pest of hops in Idaho
for over 60 years. Adult P. californicus are not known to
damage hop plants. Larvae feeding on the roots of hop plants
can, however, cause serious economic loss. Feeding by P. californicus
larvae damages plant roots resulting in decreased nutrient
uptake, water stress and reduced plant growth. Severe infestations
can completely destroy plant crowns resulting in plant death.
Less severe infestations can result in the wilting, yellowing,
and death of one or more bines of infested plants.
Management.
Management of P. californicus in hop consists of identifying
and removing infested plants. It may be necessary to dig up
and remove all plants in severely infested fields. Fields
taken out of production must be fumigated and/or left fallow
for two-three years before being replanted to hops. There
are no chemicals presently registered for preventing new,
or controlling established P. californicus infestations in
hop.
Loopers,
Cutworms, and armyworms
These
insects can cause serious damage at certain stages of growth,
but outbreaks tend to be less widespread than those seen with
mites and aphids.
Spotted
cutworm (Amathes c-nigrum) and redback cutworm (Euxoa ochrogaster)
are pests of early season crown growth. They are usually not
a problem unless a heavy infestation feeds on newly trained
vines. Bifenthrin is the only effective registered compound
but treatment is usually not economically feasible.
Hop looper
(Hypena humuli) is a summer defoliator. Damage is usually
confined to the lower portion of the vine. Chemical control
has been poor except for bifenthrin, which is rarely economically
feasible.
Bertha
armyworm (Mamestra configurata) and Corn earworm (Helicoverpa
zea) are pests at harvest. Eggs are laid on pigweed or lambs
quarter in the hop yard. Every three to four years, populations
reach levels causing severe damage (30%). Caterpillars defoliate
the weeds and move up into hops, chewing on the stems and
causing cones to fall on the ground. Emergency harvest results
in worms curling up inside the cones and later becoming a
contaminant in the dryers. An effective control is a low rate
of bifenthrin if the problem is recognized at least 14 days
prior to harvest.
Chemical
Controls:
Bifenthrin
(Brigade, 0.06-0.1 lbs. AI/A). 14 day PHI. It has great value
to the industry as a rescue treatment for lepidopteran pests.
Acreage treated is about 10%.
Dibrom (Naled, 1 lb. AI/A). 7 day PHI. Works very well on
worms only. Up to five applications may be made at 14-day
intervals. Acreage treated is about 10%.
Bacillus thuringiensis var. kurstaki (Dipel, Javelin, 0.5
to 1 lbs. product/A). 0 day PHI. The material must be ingested
by the worms to be effective. Little to none of the Idaho
acreage is treated.
Diseases
Downy Mildew
Downy
mildew is a serious threat to profitable hop production. Direct
losses result from reduced yields, infected and shattered
cones, and crown die-out. Certain hop varieties are more susceptible
to the disease, and Oregon growers must deal with annual outbreaks,
due to their moist climate. The fungus overwinters in infected
hop crowns and first appears in the spring as an infected
shoot, commonly known as a primary "spike." The
spike has pale green or light yellow, slightly downward-cupped
leaves, and shortened internodes. Under favorable environmental
conditions, the under surface of the leaves becomes blackened
with spores, which spread the disease to other shoots, causing
lesions to develop on the leaves. Secondary spikes are formed
from these shoots.
Spike
formation halts growth of the infected shoot reducing or eliminating
flower and cone production. Infection of hop flowers results
in flower death directly reducing cone yield. Cone infection
results will be death of a portion of the cone. The dead portion
becomes blackened and is unacceptable to brewers. Crown infection
with downy mildew in certain varieties results in crown death
during the winter. Fungicides are utilized on an "as
needed" basis to control this disease. Without control
susceptible varieties will experience substantial yield loss
and crown die-out, necessitating replanting (100% loss).
Chemical
Controls:
Metalaxyl
(Ridomil Gold, 0.25lbs. AI/A). 45 day PHI. Used as a tank
mix with copper compounds (2 lbs. Kocide 101) for resistance
management. This fungicide is the most effective against downy
mildew. One treatment per year is applied on 25%-100% of the
total acreage, depending on environmental conditions.
Fosetyl-al (Aliette WSP, 2 lbs. AI/A). 24 day PHI. This fungicide
is also effective against downy mildew, and is alternated
with copper sprays for resistance management. Depending on
environmental conditions, 25%-100% of the total acreage may
be treated.
Copper (various formulations). 14 day PHI. This fungicide
is effective against downy mildew and can be used alone or
tank mixed with metalaxyl. Depending on environmental conditions,
25%-100% of the total acreage may be treated.
Powdery Mildew
Powdery
mildew is a serious disease in hops in other hop growing areas
of the world. The disease was largely responsible for eliminating
commercial hop production in New York during the early part
of this century. Prior to 1997, powdery mildew had not been
observed in the Pacific Northwest. The hop industry has attempted
to protect their growing region from introduction of this
disease through the use of state hop quarantine laws. As the
disease was not present, no fungicides were registered to
control it.
The Idaho
hop industry discovered hop powdery mildew in 1998. Approximately
20 hop fields were infected with infections ranging from light
to heavy in individual fields. One lesion in a single field
was found prior to harvest in 1999. Without control 100% loss
would be expected on susceptible varieties. It is expected
that varieties currently exhibiting some resistance/tolerance
for the disease will rapidly become susceptible due to disease
mutation.
Chemical
Controls:
In
1998, Section 18s were requested and granted for fenarimol
and myclobutanil, and a crisis exemption was issued for use
of tebuconazole. Preliminary results indicate good activity
at field rates. 100% of the acreage was treated with one or
more of these compounds.
In 1999, Section 18s were requested for trifloxystrobin, myclobutanil,
and tebuconazole. None of the Idaho acres was treated with
any of these compounds.
Biological Controls:
AQ10
(Ampelomyces quisqualisis a hyperparasite of powdery mildew.
As a parasite it is only able to survive when its host is
already present in the field. It is only effective during
early season in high humidity and at low temperatures. Mildew
rates must be 2% or lower for any control, as the parasite
cannot keep up with mildew growth rates. At rates higher than
2%, and during different environmental conditions, the AQ10
fungus is not effective against mildew. Growers use this product
in the early season, and then start preventative spray schedules.
About 25% of the Idaho acreage was treated in 1998. None of
the acres was treated in 1999.
Other diseases include Verticillium wilt, and crown and root
rot caused by downy mildew or Phytophthora spp. Previously
listed fungicides control these diseases. The primary viral
disease in hops is necrotic ringspot virus, which is spread
through propagation material. The U.S. hop industry promotes
the use of virus-free rootstock by growers and regular replanting
of hop yards to avoid viral problems. Nematodes are not an
economic concern at this time.
Weeds
Few herbicides are available for hops, and weed control is
largely done by cultivation, which can exacerbate water quality
problems in return flows (the majority of Idaho hop acreage
is rill irrigated). Desiccants are very important tools for
the hop industry, as early season growth must be burned back
for several weeks prior to optimum training dates for the
specific hop variety. Desiccation is also important for the
prevention of powdery mildew through spike removal. In late
June to early July, the lower leaves need to be removed from
hop vines in order to improve airflow through the hop yard,
and to control diseases and pests. Herbicides for adequate
weed control and desiccation efforts are generally lacking
in hop production. Without control losses will vary by variety.
Chemical
Controls:
Paraquat
(Gramoxone Extra, 0.47 - 0.78 lbs. AI/A). 14 days PHI. Used
for chemical pruning on hops. Marginally effective when used
alone and temperatures are below 7°F. Approximately 100%
of the acreage is treated.
Endothall (Des-I-Cate, 0.5-1.0 lbs. AI/A). 28 days PHI. A
desiccant used for chemical pruning. It does not have any
weed control activity. Growers may tank-mix endothall and
paraquat to enhance the activity of both products. Temperatures
of at least 75°F are needed for acceptable desiccation.
Approximately 100% of the acreage is treated.
Norflurazon (Solicam DF, 2.0-4.0 lbs. AI/A). Controls grasses
and some broadleaf weeds in established hops. Apply in the
fall or within one week after stringing in the spring. Approximately
20% of the acres are treated.
Trifluralin (Treflan HTP, TR-10, EC and 5 formulations, 0.5-0.75
lbs. AI/A). A dormant application. Controls grasses, but has
to be soil incorporated which restricts weed control to cultivated
areas. Weed control within the crown is not possible using
trifluralin, as foliar spray results in damage to the hop
crown in the following year. Less than 5% of the acreage is
treated.
Contacts
Author, Industry, and Technical Contact
Jim
Barbour, Hop Pest Management
University of Idaho
Parma Research and Extension Center
Parma, ID 83660
Phone:
(208) 722-6701
FAX: (208) 722-6708
Email: jbarbour@uidaho.edu
Prepared
September 1999
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