1. Wheat Development in the
U.S.
Fig. 3: Wheat plant development scale (modified from Large, 1954) |
The wheat plant itself goes through several stages of development from
the time it is planted until it has reached maturity (Fig. 3). These stages are
monitored and measured at each point by farmers and researchers in an effort to
understand how best to improve the amount of wheat produced by each plant. This
diligence combined with experience helps the farmer to make decisions about
fertilizers or other chemical applications for disease and pest control. Ultimately,
the goal is a large crop of high milling quality wheat produced at the least
cost.
2. Wheat Cultivation and
Harvest
Wheat planting practices and the labour required for planting have
seen dramatic changes over the last century. Powerful technology – enhanced tractors
and implements capable of working more than 120 acres (48.6 hectares) in a
single day (Fig. 4) – have replaced men with mules in the field.
Fig. 4: Harvesting wheat with a modern combine (source:
Kansas State University)
|
In some cases wheat is even planted over the top of the previous
year's stubble using a method called "no-till" in an effort to
preserve soil moisture, reduce soil erosion and lower the amount of fuel required
per acre. Using modern farm equipment, wheat seeds are "drilled" or
planted in narrow rows. As the wheat matures the space between the rows seems
to fill with the growing plants, giving the appearance of a sea of grain. In
North America, planting of winter wheat begins before September in the northern
areas, and continues through October in the southern regions (Fig. 5). The
harvest begins in May of the following year in the southern regions and continues
well past July in the northern regions (Fig. 6). Spring wheat, on the other hand,
is normally planted during the month of April with harvest taking place after
the 15th of August of the same calendar year.
Fig. 5: Wheat planting in the United States (modified
from Anon., 1993)
|
Fig. 6: Wheat harvest in the United States (modified
from Anon., 1993)
|
3. Global Significance
K. Brunckhorst
Cereals are the staple food of the world's entire population, albeit
with great regional differences. The main products are wheat, rice and maize,
that make up about 85% of the global grain harvest of about 2 billion t per annum
(Tab. 2).
Tab. 2: Cereal growing (five-year
average, 1996 - 2000)a
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In Germany, for example, the development of wheat growing over the
past few decades has been characterized by more and more intensive cultivation,
chiefly in the form of shorter and more lodging-resistant varieties and the increased
use of nitrogen fertilizers and highly effective fungicides. In the mid 1970s
the value tests carried out by the BSA2 – the relevant public authority
in Germany – to determine productivity and the resistance and quality attributes
of the wheat were conducted with 50 to 140 kg nitrogen per hectare depending on
the previous crop and the quality of the site, the average being 100 kg. Today
these field tests are carried out on the intensive level with 160 to 220 kg/ha,
with an average of 190 kg. Through this combination of high-yielding varieties
and suitable cultivation and plant protection methods, the wheat achieved yield
ncreases of about 0.150 t/ha per annum (Tab. 3).
Tab. 3: Development of the grain yield and baking quality
of German winter wheat in the period 1976 - 2001 (three-year averages of the
intensive variant in VT a 2 or 3 of the
BSA 2)
|
Simultaneously with this development, plant breeders succeeded in
programming more and more new breeds genetically for high flour and baking quality.
As a result, there was no longer any need to process summer wheat or the
usually valuable imported wheat from the USA or Canada for quality reasons. The
names of varieties such as Diplomat, Kormoran, Monopol, Astron, Zentos, Bussard
etc. are representative of this trend.
Besides the level and reliability of the yield as objectives of
breeding, and also processing quality – chiefly understood as baking quality and
more recently extended to include the special qualities "biscuit
wheat" and "starch wheat" – selection in respect. A comparison
of susceptibility to leaf and ear diseases shows that considerable progress has
been made in breeding for resistance, but what has been achieved so far still
leaves room for improvement (Tab. 4).
Tab. 4: Development of grain yield and agronomic and
resistance properties a according to
the year of approval in Germany
The interplay between the genes for resistance in the varieties and
those for virulence in the disease-causing organisms is complex and differs
from one disease to another. Breeding for resistance to mildew has been particularly
successful. Only 10 to 20 years ago this disease was still widespread in wheat and
made the use of fungicides necessary at a fairly early stage in the development
of the crop. There are now a number of varieties that are practically
unaffected by attack and are likely to remain healthy on a broad basis of resistance.
In the case of yellow rust the situation is similar, but with regard
to its virulence the fungus is even more capable of transformation than the mildew
fungus. This means that varieties that were initially resistant to yellow rust
still become susceptible to the disease when a new, aggressive yellow rust
strain occurs. But here, too, there are examples of long-term field resistance.
On average it has also been possible to considerably reduce
susceptibility to leaf rust in the new varieties, but as there are still great differences
in the degree of resistance we may expect further progress in breeding.
Progress has also been achieved in respect of the other leaf diseases such as
Septoria and DTR
(Drechslera tritici repentis), but compared to the above these are
less obvious because the genetic variance is smaller.
Very wet weather with little sunshine in the months of June and July
has caused an increase in the ear diseases of wheat in recent years. The main
problem in this case is the Fusarium fungi, which form mycotoxins damaging to man
and animals as well as reducing the yield. The preference for shorter and
usually more lodging-resistant wheat varieties with "shortstraw genes"
chiefly results in a shortening of the upper internodes; the ear comes very close
to the top leaf. Short infection routes and slow drying of the ears further
increase the risk of attack. Furthermore, where resistance to ear diseases is
concerned we are dealing with a polygenic system. It is the combination of
several smaller positive genetic effects that keeps the ears healthy. Moreover,
unlike many other diseases the different Fusarium types are not specific to
certain species or organs. All this makes the fusariose complex as a whole very
difficult for breeders to handle. But "on the bottom line" improvements
are to be seen in this field too.
Note :
2 The Bundessortenamt (BSA) in Rettmar, Hanover, is the
German agency responsible for the protection of new plant varieties.
(Source : The future of Flour)
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