We do not need unlimited amounts of tobacco, but potatoes will
certainly do. There we can go to a year round tropical growing
season and pump out a full weight every two months or an easy two
fold in productivity. Globally doubling the productivity of root
crops appears feasible.
Followers of my blog also know that all practical tropical soils are
actually available for agriculture through the application of biochar
methods. Thus we are a long way from running out of food as the
present abundance should make clear. The days of relying on the
family garden are long gone just about everywhere.
In fact by now, it should be rather clear that this world is
completely able to feed itself handily and do it at vastly higher
levels of population. I have found ways to take our population to
one hundred billion without been too clever at all.
Giant tobacco
plants that stay young forever
by Staff Writers
Munster, Germany (SPX) Jan 15, 2013
http://www.seeddaily.com/reports/Giant_tobacco_plants_that_stay_young_forever_999.html
Tobacco plants bloom
when they are just a few months old - and then they die. Now,
researchers have located a genetic switch which can keep the plants
young for years and which permits unbounded growth. In short, an
ideal source of biomass. The life of tobacco plants is short. They
grow for around three to four months, followed by flowering and then
die. Their size is also limited, with plants only growing to about
one-and-a-half to two meters tall.
Now, researchers at
the Fraunhofer Institute for Molecular Biology and Applied Ecology
IME in Munster have located the tobacco plant's very own fountain of
youth, which means they can keep it forever young.
The Munster-based
researchers discovered a genetic switch which can prevent the plants
from change blooming to flowering.
This also averts the
plants' early change demise to senescence - and suppresses the factor
that halts growth.
"The first of our
tobacco plants is now almost eight years old but it still just keeps
on growing and growing," says Professor Dirk Prufer, head of the
Department of Functional and Applied Genomics at the IME.
"Although we
regularly cut it, it's six-and-a-half meters tall. If our greenhouse
were a bit higher, it would probably be even bigger. Its stem is
already ten centimeters in diameter."
Whereas in normal
tobacco plants the leaves, which grow from the bottom of the stem,
soon turn yellow and drop off, the IME plant's leaves stay healthy
and green. This is why the scientists have christened their modified
plant species "forever young".
But what exactly do
researchers do to give the plants eternal youth and make them capable
of unbounded growth?
"We modify the
expression of a certain gene - or rather, the information contained
within it - so that the plant's flowering is delayed," explains
Prufer. Researchers then insert the modified gene back into the plant
using a bacterium. The role of the bacterium is to act as a sort of
shuttle service for the modified gene.
Producing more
biomass
The principle is transferable and could be used on other kinds of plants; at the moment, the scientists are working also on potato plants on behalf of a Japanese chemical company. They use their knowledge to get crops to yield a far greater amount of biomass. In the case of potatoes, this means a great deal more starch.
"If we want to
guarantee security of supply for foodstuffs and plant-based raw
materials, the yield per hectare will have to double by 2050,
claims the German Bioeconomy Council. This new technology brings us a
great deal nearer to that target," reckons Prufer.
"However, our
method is only likely to deliver success as long as the flowers of
the plant in question play no significant role - sugar beet, for
instance. It would make no sense to use the technique on rapeseed."
Preventing plants from
flowering presents a significant advantage, in that no flowering
means no production of seeds or pollen. As a result, plants have no
way of reproducing, which means they cannot spread into the
environment in an unplanned way.
In the future, the
researchers want to go further and be able to disable plants' growth
limits using chemical mutagenesis as well - that is to say, using
normal growing techniques. This process involves using chemical
additives to bring about changes in a seed's DNA sequence.
The advantage is that
a plant grown in this way would no longer be genetically modified but
simply a plant grown using standard techniques.
"But in order to
be able to do that, we first need to gain a better understanding of
the deregulation of genes," says Prufer, who hopes cultivation
experiments might begin next year. Then perhaps normal plants will be
in a position to grow tall, too.
WHAT ABOUT GRAFTING?Is the top or root graftable?
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