Organic Gardener's Composting eBook

This eBook from the Gutenberg Project consists of approximately 224 pages of information about Organic Gardener's Composting.

Organic Gardener's Composting eBook

This eBook from the Gutenberg Project consists of approximately 224 pages of information about Organic Gardener's Composting.

Krasilnikov’s great contribution to science was discovering how soil microorganisms assist the growth of higher plants.  Bacteria are very fussy about the substrate they’ll grow on.  In the laboratory, one species grows on protein gel, another on seaweed.  One thrives on beet pulp while another only grows on a certain cereal extract.  Plants “understand” this and manipulate their soil environment to enhance the reproduction of certain bacteria they find desirable while suppressing others.  This is accomplished by root exudates.

For every 100 grams of above-ground biomass, a plant will excrete about 25 grams of root exudates, creating a chemically different zone (rhizosphere) close to the root that functions much like the culture medium in a laboratory.  Certain bacteria find this region highly favorable and multiply prolifically, others are suppressed.  Bacterial counts adjacent to roots will be in hundreds of millions to billions per gram of soil.  A fraction of an inch away beyond the influence of the exudates, the count drops greatly.

Why do plants expend energy culturing bacteria?  Because there is an exchange, a quid pro quo. These same bacteria assist the plant in numerous ways.  Certain types of microbes are predators.  Instead of consuming dead organic matter they attack living plants.  However, other species, especially actinomycetes, give off antibiotics that suppress pathogens.  The multiplication of actinomycetes can be enhanced by root exudates.

Perhaps the most important benefit plants receive from soil bacteria are what Krasilnikov dubbed “phytamins,” a word play on vitamins plus phyta or “plant” in Greek.  Helpful bacteria exude complex water-soluble organic molecules that plants uptake through their roots and use much like humans need certain vitamins.  When plants are deprived of phytamins they are less than optimally healthy, have lowered disease resistance, and may not grow as large because some phytamins act as growth hormones.

Keep in mind that beneficial microorganisms clustering around plant roots do not primarily eat root exudates; exudates merely optimize environmental conditions to encourage certain species.  The main food of these soil organisms is decaying organic matter and humus.  Deficiencies in organic matter or soil pH outside a comfortable range of 5.75-7.5 greatly inhibit beneficial microorganisms.

For a long time it has been standard “chemical” ag science to deride the notion that plant roots can absorb anything larger than simple, inorganic molecules in water solution.  This insupportable view is no longer politically correct even among adherents of chemical usage.  However, if you should ever encounter an “expert” still trying to intimidate others with these old arguments merely ask them, since plant roots cannot assimilate large organic molecules, why do people succeed using systemic chemical pesticides?  Systemics are large, complex poisonous organic molecules that plants uptake through their roots and that then make the above-ground plant material toxic to predators.  Ornamentals, like roses, are frequently protected by systemic chemical pesticides mixed into chemical fertilizer and fed through the soil.

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Project Gutenberg
Organic Gardener's Composting from Project Gutenberg. Public domain.