Industrial Media and the Nutrition of Industrial Organisms PDF

Summary

This chapter discusses industrial media and the nutrition of microorganisms used in industrial microbiology. It details the basic nutrient requirements, including carbon, nitrogen, minerals, growth factors, and water, essential for microbial growth. It also considers various raw materials, and methods of preparation or pretreatment of complex materials for industrial purposes.

Full Transcript

54 Modern Industrial Microbiology and Biotechnology

CHAPTER 4
Industrial Media and the
Nutrition of Industrial
Organisms

The use of a good, adequate, and industrially usable medium is as important as the
deployment of a suitable microorganism in industrial microbiology. Unless the medium
is adequate, no matter how innately productive the organism is, it will not be possible to
harness the organism’s full industrial potentials. Indeed not only may the production of
the desired product be reduced but toxic materials may be produced. Liquid media are
generally employed in industry because they require less space, are more amenable to
engineering processes, and eliminate the cost of providing agar and other solid agents.

4.1 THE BASIC NUTRIENT REQUIREMENTS OF
INDUSTRIAL MEDIA
All microbiological media, whether for industrial or for laboratory purposes must satisfy
the needs of the organism in terms of carbon, nitrogen, minerals, growth factors,
and water. In addition they must not contain materials which are inhibitory to growth.
Ideally it would be essential to perform a complete analysis of the organism to be grown
in order to decide how much of the various elements should be added to the medium.
However, approximate figures for the three major groups of heterotrophic organisms
usually grown on an industrial scale are available and may be used in such calculations
(Table 4.1).
Carbon or energy requirements are usually met from carbohydrates, notably (in laboratory
experiments) from glucose. It must be borne in mind that more complex carbohydrates
such as starch or cellulose may be utilized by some organisms. Furthermore, energy
sources need not be limited to carbohydrates, but may include hydrocarbons, alcohols, or
even organic acids. The use of these latter substrates as energy sources is considered in
Chapters 15 and 16 where single cell protein and yeast productions are discussed.
In composing an industrial medium the carbon content must be adequate for the
production of cells. For most organisms the weight of organism produced from a given
weight of carbohydrates (known as the yield constant) under aerobic conditions is about
 Industrial Media and the Nutrition of Industrial Organisms 55

Table 4.1 Average composition of microorganisms (% dry weight)

Component Bacteria Yeast Molds
Carbon 48 (46-52) 48 (46-52) 48 (45-55)
Nitrogen 12.5 (10-14) 7.5 (6-8.5) 6 (4-7)
Protein 55 (50 –60) 40 (35-45) 32 (25-40)
Carbohydrates 9 (6-15) 38 (30-45) 49 (40-55)
Lipids 7 (5-10) 8 (5-10) 8 (5-10)
Nucleic Acids 23 (15-25) 8 (5-10) 5 (2-8)
Ash 6 (4-10) 6 (4-10) 4 (4-10)
Minerals (same for all three organisms)
Phosphorus 1.0 - 2.5
Sulfur, magnesium 0.3 - 1.0
Potassium, sodium 0.1 - 0.5
Iron 0.01 - 0.1
Zinc, copper, manganese 0.001 – 0.01

0.5 gm of dry cells per gram of glucose. This means that carbohydrates are at least twice
the expected weight of the cells and must be put as glucose or its equivalent compound.
Nitrogen is found in proteins including enzymes as well as in nucleic acids hence it is a
key element in the cell. Most cells would use ammonia or other nitrogen salts. The
quantity of nitrogen to be added in a fermentation can be calculated from the expected cell
mass and the average composition of the micro-organisms used. For bacteria the average
N content is 12.5%. Therefore to produce 5 gm of bacterial cells per liter would require
about 625 mg N (Table 4.1).
Any nitrogen compound which the organism cannot synthesize must be added.
Minerals form component portions of some enzymes in the cell and must be present in the
medium. The major mineral elements needed include P, S, Mg and Fe. Trace elements
required include manganese, boron, zinc, copper and molybdenum.
Growth factors include vitamins, amino acids and nucleotides and must be added to the
medium if the organism cannot manufacture them.
Under laboratory conditions, it is possible to meet the organism’s requirement by the
use of purified chemicals since microbial growth is generally usually limited to a few
liters. However, on an industrial scale, the volume of the fermentation could be in the
order of thousands of liters. Therefore, pure chemicals are not usually used because of
their high expense, unless the cost of the finished material justifies their use. Pure
chemicals are however used when industrial media are being developed at the laboratory
level. The results of such studies are used in composing the final industrial medium,
which is usually made with unpurified raw materials. The extraneous materials present
in these unpurified raw materials are not always a disadvantage and may indeed be
responsible for the final and distinctive property of the product. Thus, although alcohol
appears to be the desired material for most beer drinkers, the other materials extraneous
56 Modern Industrial Microbiology and Biotechnology

to the maltose (from which yeasts ferment alcohol) help confer on beer its distinctive
flavor (Chapter 12).

4.2 CRITERIA FOR THE CHOICE OF RAW MATERIALS
USED IN INDUSTRIAL MEDIA
In deciding the raw materials to be used in the production of given products using
designated microorganism(s) the following factors should be taken into account.
(a) Cost of the material
The cheaper the raw materials the more competitive the selling price of the final product
will be. No matter, therefore, how suitable a nutrient raw materials is, it will not usually
be employed in an industrial process if its cost is so high that the selling price of the final
product is not economic. Thus, although lactose is more suitable than glucose in some
processes (e.g. penicillin production) because of the slow rate of its utilization, it is
usually replaced by the cheaper glucose. When used, glucose is added only in small
quantities intermittently in order to decelerate acid production. Due to these economic
considerations the raw materials used in many industrial media are usually waste
products from other processes. Corn steep liquor and molasses are, for example, waste
products from the starch and sugar industries, respectively. They will be discussed more
fully below.
(b) Ready availability of the raw material
The raw material must be readily available in order not to halt production. If it is seasonal
or imported, then it must be possible to store it for a reasonable period. Many industrial
establishments keep large stocks of their raw materials for this purpose. Large stocks help
beat the ever rising cost of raw materials; nevertheless large stocks mean that money
which could have found use elsewhere is spent in constructing large warehouses or
storage depots and in ensuring that the raw materials are not attacked during storage by
microorganisms, rodents, insects, etc. There is also the important implication, which is
not always easy to realize, that the material being used must be capable of long-term
storage without concomitant deterioration in quality.
(c) Transportation costs
Proximity of the user-industry to the site of production of the raw materials is a factor of
great importance, because the cost of the raw materials and of the finished material and
hence its competitiveness on the market can all be affected by the transportation costs.
The closer the source of the raw material to the point of use the more suitable it is for use,
if all other conditions are satisfactory.
(d) Ease of disposal of wastes resulting from the raw materials
The disposal of industrial waste is rigidly controlled in many countries. Waste materials
often find use as raw materials for other industries. Thus, spent grains from breweries
can be used as animal feed. But in some cases no further use may be found for the waste
from an industry. Its disposal especially where government regulatory intervention is
rigid could be expensive. When choosing a raw material therefore the cost, if any, of
treating its waste must be considered.
 Industrial Media and the Nutrition of Industrial Organisms 57

(e) Uniformity in the quality of the raw material and ease of standardization
The quality of the raw material in terms of its composition must be reasonably constant in
order to ensure uniformity of quality in the final product and the satisfaction of the
customer and his/her expectations. In cases where producers are plentiful, they usually
compete to ensure the maintenance of the constant quality requirement demanded by the
user. Thus, in the beer industry information is available on the quality of the barley malt
before it is purchased. This is because a large number of barley malt producers exist, and
the producers attempt to meet the special needs of the brewery industry, their main
customer. On the other hand molasses, which is a major source of nutrient for industrial
microorganisms, is a by product of the sugar industry, where it is regarded as a waste
product. The sugar industry is not as concerned with the constancy of the quality of
molasses, as it is with that of sugar. Each batch of molasses must therefore be chemically
analyzed before being used in a fermentation industry in order to ascertain how much of
the various nutrients must be added. A raw material with extremes of variability in
quality is clearly undesirable as extra costs are needed, not only for the analysis of the
raw material, but for the nutrients which may need to be added to attain the usual and
expected quality in the medium.
(f) Adequate chemical composition of medium
As has been discussed already, the medium must have adequate amounts of carbon,
nitrogen, minerals and vitamins in the appropriate quantities and proportions necessary
for the optimum production of the commodity in question. The demands of the
microorganisms must also be met in terms of the compounds they can utilize. Thus most
yeasts utilize hexose sugars, whereas only a few will utilize lactose; cellulose is not easily
attacked and is utilized only by a limited number of organisms. Some organisms grow
better in one or the other substrate. Fungi will for instance readily grow in corn steep
liquor while actinomycetes will grow more readily on soya bean cake.
(g) Presence of relevant precursors
The raw material must contain the precursors necessary for the synthesis of the finished
product. Precursors often stimulate production of secondary metabolites either by
increasing the amount of a limiting metabolite, by inducing a biosynthetic enzyme or
both. These are usually amino acids but other small molecules also function as inducers.
The nature of the finished product in many cases depends to some extent on the
components of the medium. Thus dark beers such as stout are produced by caramelized
(or over-roasted) barley malt which introduce the dark color into these beers. Similarly for
penicillin G to be produced the medium must contain a phenyl compound. Corn steep
liquor which is the standard component of the penicillin medium contains phenyl
precursors needed for penicillin G. Other precursors are cobalt in media for Vitamin B12
production and chlorine for the chlorine containing antibiotics, chlortetracycline, and
griseofulvin (Fig. 4.1).
(h) Satisfaction of growth and production requirements of the microorganisms
Many industrial organisms have two phases of growth in batch cultivation: the phase of
growth, or the trophophase, and the phase of production, or the idiophase. In the first
phase cell multiplication takes place rapidly, with little or no production of the desired
58 Modern Industrial Microbiology and Biotechnology

Left: Vitamin B12. Please note that cobalt is highlighted. It must be present in the medium in which organisms
producing the vitamin are grown
Right: Top; The general structure of tetracyclines. Bottom; The structure of 7-Chlortetracycline; a chlorine
atom is present in position 7. Chlorine must be present in the medium for producing chlortetracyline; note that
chlorine is highlighted in position 7 in chlortetracycline.
Fig. 4.1 Vitamin B12 and Chlortetracycline Showing Location of Components Present as
Precursors in the Medium

material. It is in the second phase that production of the material takes place, usually
with no cell multiplication and following the elaboration of new enzymes. Often these
two phases require different nutrients or different proportions of the same nutrients. The
medium must be complete and be able to cater for these requirements. For example high
levels of glucose and phosphate inhibit the onset of the idiophase in the production of a
number of secondary metabolites of industrial importance. The levels of the components
added must be such that they do not adversely affect production. Trophophase-
idiophase relationship and secondary metabolites are discussed in detail in Chapter 5.

4.3 SOME RAW MATERIALS USED IN COMPOUNDING
INDUSTRIAL MEDIA
The raw materials to be discussed are used because of the properties mentioned above:
cheapness, ready availability, constancy of chemical quality, etc. A raw material which is
 Industrial Media and the Nutrition of Industrial Organisms 59

cheap in one country or even in a different part of the same country may however not be
cheap in another, especially if it has already found use in some other production process.
In such cases suitable substitutes must be found if the goods must be produced in the new
location. The use of local substitutes where possible is advantageous in reducing the
transportation costs and even creating some employment in the local population. Prior
experimentation may however be necessary if such new local materials differ
substantially in composition from those already being used. Some well-known raw
materials will now be discussed. In addition, some of potential useability will also be
examined.
(a) Corn steep liquor
This is a by-product of starch manufacture from maize. Sulfur dioxide is added to the
water in which maize is steeped. The lowered pH inhibits most other organisms, but
encourages the development of naturally occurring lactic acid bacteria especially
homofermentative thermophilic Lactobacillus spp. which raise the temperature to
38-55°C. Under these conditions, much of the protein present in maize is converted to
peptides which along with sugars leach out of the maize and provide nourishment for
the lactic acid bacteria. Lactic fermentation stops when the SO2 concentration reaches
about 0.04% and the concentration of lactic acid between 1.0 and 1.5%. At this time the
pH is about 4. Acid conditions soften the kernels and the resulting maize grains mill
better while the gel-forming property of the starch is not hindered. The supernatant
drained from the maize steep is corn steep liquor. Before use, the liquor is usually filtered
and concentrated by heat to about 50% solid concentration. The heating process kills the
bacteria.
As a nutrient for most industrial organisms corn steep liquor is considered adequate,
being rich in carbohydrates, nitrogen, vitamins, and minerals. Its composition is highly
variable and would depend on the maize variety, conditions of steeping, extent of boiling
etc. The composition of a typical sample of corn steep liquor is given in Table 4.2. As corn
steep liquor is highly acidic, it must be neutralized (usually with CaCO3) before use.
(b) Pharmamedia
Also known as proflo, this is a yellow fine powder made from cotton-seed embryo. It is
used in the manufacture of tetracycline and some semi-synthetic penicillins. It is rich in

Table 4.2 Approximate composition of corn steep liquor (%)

Lactose 3.0-4.0
Glucose 0.-0.5
Non-reducing carbohydrates (mainly starch) 1.5
Acetic acid 0.05
Glucose lactic acid 0.5
Phenylethylamine 0.05
Amino aids (peptides, mines) 0.5
Total solids 80-90
Total nitrogen 0.15-0.2%
60 Modern Industrial Microbiology and Biotechnology

protein, (56% w/v) and contains 24% carbohydrate, 5% oil, and 4% ash, the last of which
is rich in calcium, iron, chloride, phosphorous, and sulfate.
(c) Distillers solubles
This is a by-product of the distillation of alcohol from fermented grain. It is prepared by
filtering away the solids from the material left after distilling fermented cereals (maize or
barley) for whiskey or grain alcohol. The filtrate is then concentrated to about one-third
solid content to give a syrup which is then drum-dried to give distillers soluble. It is rich
in nitrogen, minerals, and growth factors (Table 4.3).

Table 4.3 Composition of maize distillers soluble

%
Moisture 5
Protein 27
Lipid 9
Fibre 5
Carbohydrate 43
Ash (mainly K, Na, Mg, CO3, and P) 11

(d) Soya bean meal
Soya beans (soja) (Glycine max), is an annual legume which is widely cultivated
throughout the world in tropical, sub-tropical and temperate regions between 50°N and
40°S. The seeds are heated before being extracted for oil that is used for food, as an anti-
foam in industrial fermentations, or used for the manufacture of margarine. The resulting
dried material, soya bean meal, has about 11% nitrogen, and 30% carbohydrate and may
be used as animal feed. Its nitrogen is more complex than that found in corn steep liquor
and is not readily available to most microorganisms, except actinomycetes. It is used
particularly in tetracycline and streptomycin fermentations.
(e) Molasses
Molasses is a source of sugar, and is used in many fermentation industries including the
production of potable and industrial alcohol, acetone, citric acid, glycerol, and yeasts. It
is a by-product of the sugar industry. There are two types of molasses depending on
whether the sugar is produced from the tropical crop, sugar cane (Saccharum officinarum)
or the temperate crop, beet, (Beta alba).
Four stages are involved in the manufacture of cane sugar. After crushing, a clear
greenish dilute sugar solution known as ‘mixed juice’ is expressed from the canes.
During the second stage known as clarification the mixed juice is heated with lime.
Addition of lime changes the pH of the juice to alkaline and thus stops further hydrolysis
(or inversion) or the cane sugar (sucrose), while heating coagulates proteins and other
undesirable soluble portions of the mixed juice to form ‘mud’. The supernatant juice is
then concentrated (in the third stage) by heating under high vacuum and increasing low
pressures in a series of evaporators. In the fourth and final stage of crystallization, sugar
crystals begin to form with increasing heat and under vacuum, yielding a thick brown
 Industrial Media and the Nutrition of Industrial Organisms 61

syrup which contains the crystals, and which is known as ‘massecuite’. (In the beet
industry it is known as ‘fillmass’.) The massecuite is centrifuged to remove the sugar
crystals and the remaining liquid is known as molasses. The first sugar so collected is ‘A’
and the liquid is ‘A’ molasses. ‘A’ molasses is further boiled to extract sugar crystals to
yield ‘B’ sugar and ‘B’ molasses. Two or more boilings may be required before it is no
longer profitable to attempt further extractions. This final molasses is known as
‘blackstrap molasses’.
The sugar yielded with the production of black strap molasses is low-grade and
brown in color, and known as raw sugar, cargo sugar, or refining sugar. This raw sugar
is further refined, in a separate factory, to remove miscellaneous impurities including the
brown color (due to caramel) to yield the white sugar used at the table. The heavy liquid
discarded from the refining of sugar is known in the sugar refining industry as ‘syrup’
and corresponds to molasses in the raw sugar industry.
The above description has been of cane sugar molasses. In the beet sugar industry the
processes used in raw refined sugar manufacture are similar, but the names of the
different fractions recovered during purification differ. Cane and beet molasses differ
slightly in composition (Table 4.4). Beet molasses is alkaline while cane molasses is acid.

Table 4.4 Average composition of beet and cane molasses

Beet Molasses Cane Molasses
% (W/W) % (W/W)
Water 16.5 20.0
Sugars: 53.0 64.0
Sucrose 51.0 32.0
Fructose 1.0 15.0
Glucose - 14.0
Raffinose 1.0 -
Non-sugar (nitrogeneous
Materials, acids, gums, etc.) 19.0 10.0
Ash 11.5 8.0

Even within same type of molasses – beet or cane – composition varies from year to
year and from one locality to another. The user industry selects the batch with a suitable
composition and usually buys up a year’s supply. For the production of cells the
variability in molasses quality is not critical, but for metabolites such as citric acid, it is
very important as minor components of the molasses may affect the production of these
metabolites.
‘High test’ molasses (also known as inverted molasses) is a brown thick syrup liquid
used in the distilling industry and containing about 75% total sugars (sucrose and
reducing sugars) and about 18% moisture. Strictly speaking, it is not molasses at all but
invert sugar, (i.e reducing sugars resulting from sucrose hydrolysis). It is produced by the
hydrolysis of the concentrated juice with acid. In the so-called Cuban method, invertase
is used for the hydrolysis. Sometimes ‘A’ sugar may be inverted and mixed with ‘A’
molasses.
62 Modern Industrial Microbiology and Biotechnology

(f) Sulfite liquor
Sulfite liquor (also called waste sulfite liquor, sulfite waste liquor or spent sulfite liquor)
is the aqueous effluent resulting from the sulfite process for manufacturing cellulose or
pulp from wood. Depending on the type, most woods contain about 50% cellulose, about
25% lignins and about 25% of hemicelluloses. During the sulfite process, hemicelluloses
hydrolyze and dissolve to yield the hexose sugars, glucose, mannose, galactose, fructose
and the pentose sugars, xylose, and arabinsoe. The acid reagent breaks the chemical
bonds between lignin and cellulose; subsequently they dissolve the lignin. Depending on
the severity of the treatment some of the cellulose will continue to exist as fibres and can
be recovered as pulp. The presence of calcium ions provides a buffer and helps neutralize
the strong lignin sulfonic acid. The degradation of cellulose yields glucose. Portions of
the various sugars are converted to sugar sulfonic acids, which are not fermentable.
Variable but sometimes large amounts of acetic, formic and glactronic acids are also
produced.
Sulfite liquor of various compositions are produced, depending on the severity of the
treatment and the type of wood. The more intense the treatment the more likely it is that
the sugars produced by the more easily hydrolyzed hemicellulose will be converted to
sulfonic acids; at the same time the more intense the treatment the more will glucose be
released from the more stable cellulose. Hardwoods not only yield a higher amount of
sugar (up to 3% dry weight of liquor) but the sugars are largely pentose, in the form of
xylose. Hardwood hydrolyzates also contains a higher amount of acetic acid. Soft woods
yield a product with about 75% hexose, mainly mannose.
Sulfite liquor is used as a medium for the growth of microorganisms after being
suitably neutralized with CaCO3 and enriched with ammonium salts or urea, and other
nutrients. It has been used for the manufacture of yeasts and alcohol. Some samples do
not contain enough assaimilable carbonaceous materials for some modern
fermentations. They are therefore often enriched with malt extract, yeast autolysate, etc.
(g) Other Substrates
Other substrates used as raw materials in fermentations are alcohol, acetic acid,
methanol, methane, and fractions of crude petroleum. These will be discussed under
Single Cell Protein (Chapter 15). Barley will be discussed in the section dealing with the
brewing of beer (Chapter 12).

4.4 GROWTH FACTORS
Growth factors are materials which are not synthesized by the organism and therefore
must be added to the medium. They usually function as cofactors of enzymes and may be
vitamins, nucleotides etc. The pure forms are usually too expensive for use in industrial
media and materials containing the required growth factors are used to compound the
medium. Growth factors are required only in small amounts. Table 4.5 gives some
sources of growth factors.

4.5 WATER
Water is a raw material of vital importance in industrial microbiology, though this
importance is often overlooked. It is required as a major component of the fermentation
 Industrial Media and the Nutrition of Industrial Organisms 63

Table 4.5 Some sources of growth factors

Growth factor Source
Vitamin B Rice polishing, wheat germ, yeasts
Vitamin B2 Cereals, corn steep liquor
Vitamin B6 Corn steep liquor, yeasts
Nicotinamide Liver, penicillin spent liquor
Panthothenic Acid Corn steep liquor
Vitamin B12 Liver, silage, meat

medium, as well as for cooling, and for washing and cleaning. It is therefore used in
rather large quantities, and measured in thousands of liters a day depending on the
industry. In some industries such as the beer industry the quality of the product depends
to some extent on the water. In order to ensure constancy of product quality the water
must be regularly analyzed for minerals, color, pH, etc. and adjusted as may be necessary.
Due to the importance of water, in situations where municipal water supplies are likely to
be unreliable, industries set up their own supplies.

4.6 SOME POTENTIAL SOURCES OF COMPONENTS OF
INDUSTRIAL MEDIA
The materials to be discussed are mostly found in the tropical countries, including those
in Africa, the Caribbean, and elsewhere in the world. Any microbiological industries to
be sited in these countries must, if they are not to run into difficulties discussed above, use
the locally available substrates. It is in this context that the following are discussed.

4.6.1 Carbohydrate Sources
These are all polysaccharides and have to be hydrolyzed to sugar before being used.
(a) Cassava (manioc)
The roots of the cassava-plant Manihot esculenta Crantz serve mainly as a source of
carbohydrate for human (and sometimes animal) food in many parts of the tropical
world. Its great advantage is that it is high yielding, requires little attention when
cultivated, and the roots can keep in the ground for many months without deterioration
before harvest. The inner fleshy portion is a rich source of starch and has served, after
hydrolysis, as a carbon source for single cell protein, ethanol, and even beer. In Brazil it is
one of the sources of fermentation alcohol (Chapter 13) which is blended with petrol to
form gasohol for driving motor vehicles.
(b) Sweet potato
Sweet potatoes Ipomca batatas is a warm-climate crop although it can be grown also in sub
tropical regions. There are a large number of cultivars, which vary in the colors of the
tuber flesh and of the skin; they also differ in the tuber size, time of maturity, yield, and
sweetness. They are widely grown in the world and are found in South America, the USA,
Africa and Asia. They are regarded as minor sources of carbohydrates in comparison
with maize, wheat, or cassava, but they have the advantage that they do not require much
64 Modern Industrial Microbiology and Biotechnology

agronomic attention. They have been used as sources of sugar on a semi-commercial
basis because the fleshy roots contain saccharolytic enzymes. The syrup made from
boiling the tubers has been used as a carbohydrate (sugar) source in compounding
industrial media. Butyl alcohol, acetone and ethanol have been produced from such a
syrup, and in quantities higher than the amounts produced from maize syrup of the same
concentration. Since sweet potatoes are not widely consumed as food, it is possible that it
may be profitable to grow them for use, after hydrolysis, in industrial microbiology media
as well as for the starch industry. It is reported that a variety has been developed which
yields up to 40 tonnes per hectare, a much higher yield than cassava or maize.
(c) Yams
Yams (Dioscorea spp) are widely consumed in the tropics. Compared to other tropical
roots however, their cultivation is tedious; in any case enough of this tuber is not
produced even for human food. It is therefore almost inconceivable to suggest that the
crop should be grown solely for use in compounding industrial media. Nevertheless
yams have been employed in producing various products such as yam flour and yam
flakes. If the production of these materials is carried out on a sufficiently large scale it is to
be expected that the waste materials resulting from peeling the yams could yield
substantial amounts of materials which on hydrolysis will be available as components of
industrial microbiological media.
(d) Cocoyam
Cocoyam is a blanket name for several edible members of the monocotyledonous (single
seed-leaf) plant of the family Araceae (the aroids), the best known two genera of which are
Colocasia (tano) and Xanthosoma (tannia). They are grown and eaten all over the tropical
world. As they are laborious to cultivate, require large quantities of moisture and do not
store well they are not the main source of carbohydrates in regions where they are grown.
However, this relative unimportance may well be of significance in regions where for
reasons of climate they can be suitably cultivated. Cocoyam starch has been found to be of
acceptable quality for pharmaceutical purposes. Should it find use in that area, starchy
by-products could be hydrolyzed to provide components of industrial microbiological
media.
(e) Millets
This is a collective name for several cereals whose seeds are small in comparison with
those of maize, sorghum, rice, etc. The plants are also generally smaller. They are
classified as the minor cereals not because of their smaller sizes but because they
generally do not form major components of human food. They are however hardy and
will tolerate great drought and heat, grow on poor soil and mature quickly. Attention is
being turned to them for this reason in some parts of the world. It is for this reason also
that millets could become potential sources of cereal for use in industrial microbiology
media. Millets are grown all over the world in the tropical and sub-tropical regions and
belong to various genera: Pennisetum americanum (pearl or bulrush millet), Setaria italica
(foxtail millet), Panicum miliaceum (yard millet), Echinochloa frumentacea (Japanese yard
millet) and Eleusine corcana (finger millet). Millet starch has been hydrolyzed by malting
for alcohol production on an experimental basis as far back as 50 years ago and the
 Industrial Media and the Nutrition of Industrial Organisms 65

available information should be helpful in exploiting these grains for use as industrial
media components.
(f) Rice
Rice, Oryza sativa is one of the leading food corps of the world being produced in all five
continents, but especially in the tropical areas. Although it is high-cost commodity, it has
the advantage of ease of mechanization, storability, and the availability of improved
seeds through the efforts of the International Rice Research Institute, Philippines and
other such bodies. The result is that this food crop is likely in the near future to displace,
as a carbohydrate source, such other starch sources as yams, and to a lesser extent
cassava in tropical countries. The increase in rice production is expected to become so
efficient in many countries that the crop would yield substrates cheap enough for
industrial microbiological use. Rice is used as brewing adjuncts and has been malted
experimentally for beer brewing.
(g) Sorghum
Sorghum, Sorghum bicolor, is the fourth in term of quantity of production of the world’s
cereals, after wheat, rice, and corn. It is used for the production of special beers in various
parts of the world. It has been mechanized and has one of the greatest potential among
cereals for use as a source of carbohydrate in industrial media in regions of the world
where it thrives. It has been successfully malted and used in an all-sorghum lager beer
which compared favorably with barley lager beer (Chapter 12)
(h) Jerusalem artichoke
Jerusalem artichoke, Helianthus tuberosus, is a member of the plant family compositae,
where the storage carbohydrate is not starch, but inulin (Fig. 4.2) a polymer of fructose
into which it can be hydrolyzed. It is a root-crop and grows in temperate, semi-tropical
and tropical regions.

4.6.2 Protein Sources
(a) Peanut (groundnut) meal
Various leguminous seeds may be used as a source for the supply of nitrogen in
industrial media. Only peanuts (groundnuts) Arachis hypogea will be discussed. The nuts
are rich in liquids and proteins. The groundnut cake left after the nuts have been freed of
oil is often used as animal feed. But just as is the case with soya bean, oil from peanuts
may be used as anti-foam while the press-cake could be used for a source of protein. The
nuts and the cake are rich in protein.
(b) Blood meal
Blood consists of about 82% water, 0.1% carbohydrate, 0.6% fat, 16.4% nitrogen, and 0.7%
ash. It is a waste product in abattoirs although it is sometimes used as animal feed.
Drying is achieved by passing live steam through the blood until the temperature reaches
about 100°C. This treatment sterilizes it and also causes it to clot. It is then drained,
pressed to remove serum, further dried and ground. The resulting blood-meal is
chocolate-colored and contains about 80% protein and small amounts of ash and lipids.
66 Modern Industrial Microbiology and Biotechnology

Fig. 4.2 Structure of Inulin. This Polymer of Fructose Replaces Starch in some Plants

Where sufficient blood is available blood meal could form an important source of
proteins for industrial media.
(c) Fish Meal
Fish meal is used for feeding farm animals. It is rich in protein (about 65%) and, minerals
(about 21% calcium 8%, and phosphorous 3.5%) and may therefore be used for industrial
microbiological media production. Fish meal is made by drying fish with steam either
aided by vacuum or by simple drying. Alternatively hot air may be passed over the fish
placed in revolving drums. It is then ground into a fine powder.

4.7 THE USE OF PLANT WASTE MATERIALS IN
INDUSTRIAL MICROBIOLOGY MEDIA:
SACCHARIFICATION OF POLYSACCHARIDES
The great recommendation of plant agricultural wastes as sources of industrial
microbiological media is that they are not only plentiful but that in contrast with
petroleum, a major source of chemicals, they are also renewable. Serious consideration
has therefore been given, in some studies, to the possibility of deriving industrial
microbiological raw materials not just from wastes, but from crops grown deliberately for
the purpose. However, plant materials in general contain large amounts of
polysaccharides which are not immediately utilizable by industrial microorganisms and
which will therefore need to be hydrolyzed or saccharified to provide the more available
sugars. Thereafter the sugars may be fermented to ethyl alcohol for use as a chemical feed
 Industrial Media and the Nutrition of Industrial Organisms 67

stock. The plant polysaccharides whose hydrolysis will be discussed in this section are
starch, cellulose and hemicelluloses.

4.7.1 Starch
Starch is a mixture of two polymers of glucose: amylose and amylopectin. Amylose is a
linear (1 ® 4) µ – D glucan usually having a degree of polymerization (D.P., i.e. number
of glucose molecules) of about 400 and having a few branched residues linked with (1 ®
6) bondings. Amylopectin is a branched D glucan with predominantly µ – D (1 ® 4)
linkages and with about 4% of the µ – D (1 ® 6) type (Fig. 4.3). Amylopectin consists of
amylose – like chains of D. P. 12 – 50 linked in a number of possible manners of which 3
in Fig. 4.4 seems most generally accepted. A comparison of the properties of amylose and
amylopectin is given in Table 4.6.

Table 4.6 Some properties of amylose and amylopectin

Property Amylose Amylopectin
Structure Linear Branched
Behavior in water Precipitates
Irreversibly Stable
Degree of polymerization 103 104 -105
Average chain length 103 20-25
Hydrolysis to maltose (%)
(a) b - amylase 87 54
(b) b - amylase and
debranching enzyme 98 79
Iodine Complex max (nm) 650 550

Starches from various sources differ in their proportion of amylopectin and amylose.
The more commonly grown type of maize, for example, has about 26% of amylose and
74% of amylopectin (Table 4.7). Others may have 100% amylopectin and still others may
have 80 – 85% of amylose.

4.7.1.1 Saccharification of starch
Starch occurs in discrete crystalline granules in plants, and in this form is highly
resistant to enzyme action. However when heated to about 55°C – 82°C depending on the
type, starch gelatinizes and dissolves in water and becomes subject to attack by various
enzymes.
Before saccharification, the starch or ground cereal is mixed with water and heated to
gelatinize the starch and expose it to attack by the saccharifying agents. The
gelatinization temperatures of starch from various cereals is given in Table 12.1. The
saccharifying agents used are dilute acids and enzymes from malt or microorganisms.

4.7.1.1.1 Saccharification of starch with acid
The starch-containing material to be hydrolyzed is ground and mixed with dilute
hydrochloric acid, sulfuric acid or even sulfurous acid. When sulfurous acid is used it
can be introduced merely by pumping sulfur dioxide into the mash.
68 Modern Industrial Microbiology and Biotechnology

Top: a – D (1 ® 4) (left) and a – D (1 ® 6) (right)
Bottom: Part structure of amylose (a) and amylopectin (b)
0 = glucose units joined by a – D (I ® 4) linkages
® = a – D (1-6) linkages

Fig. 4.3 Linkages of D-glucose
 Industrial Media and the Nutrition of Industrial Organisms 69

Table 4.7 Amylose contents of some starches

Source Amylose Content %
Potato 20-22
Corn 20-27
Wheat 18-26
Oat 22-24
Waxymaize 0-5
Cassava 17-20
Sorghum 25-28
Rice 16-18

o = Terminal non-reducing end – groups
l = Reducing end group
® = a - D - (1 ® 6) linkage
— = Chain of 20 to 25 a - D - (1 ® 4) linked D-glucose residues

Fig. 4.4 Diagrams Representing Three Proposed Structures of Amylopectin

The concentrations of the mash and the acid, length of time and temperature of the
heating have to be worked out for each starch source. During the hydrolysis the starch is
broken down from starch (about 2,000 glucose molecules) through compounds of
decreasing numbers of glucose moieties to glucose. The actual composition of the
hydrolysate will depend on the factors mentioned above. Starch concentration is
particularly important: if it is too high, side reactions may occur leading to a reduction in
the yield of sugar.
At the end of the reaction the acid is neutralized. If it is desired to ferment the
hydrolysate for ethanol, yeast or single cell production, ammonium salts may be used as
they can be used by many microorganisms.
70 Modern Industrial Microbiology and Biotechnology

4.7.1.1.2 Use of enzymes
Enzymes hydrolyzing starch used to be called collectively diastase. With increased
knowledge about them, they are now called amylases. Enzymatic hydrolysis has several
advantages over the use of acid: (a) since the pH for enzyme hydrolysis is about neutral,
there is no need for special vessels which must stand the high temperature, pressure, and
corrosion of acid hydrolysis; (b) enzymes are more specific and hence there are fewer side
reactions leading therefore to higher yields; (c) acid hydrolysis often yields salts which
may have to be removed constantly or periodically thereby increasing cost; (d) it is
possible to use higher concentrations of the substrates with enzymes than with acids
because of enzyme specificity, and reduced possibility of side reactions.

4.7.1.1.3 Enzymes involved in the hydrolysis of starch
Several enzymes are important in the hydrolysis of starch. They are divisible into six
groups.
(i) Enzymes that hydrolyse a – 1, 4 bonds and by-pass a – I, 6 bonding: The typical
example is a - amylase. This enzyme hydrolyses randomly the inner (1 ® 4) - a -
D - glucosidic bonds of amylose and amylopectin (Fig. 4.3). The cleavage can occur
anywhere as long as there are at least six glucose residues on one side and at least
three on the other side of the bond to be broken. The result is a mixture of branched
a - limit dextrins (i.e., fragments resistant to hydrolysis and contain the a - D (1 6)
linkage (Fig. 4.4) derived from amylopectin) and linear glucose residues especially
maltohexoses, maltoheptoses and maltotrioses. a - Amylases are found in virtually
every living cell and the property and substrate pattern of a - amylases vary
according to their source. Thus, animal a - amylases in saliva and pancreatic juice
completely hydrolyze starch to maltose and D-glucose. Among microbial a -
amylases some can withstand temperatures near 100°C.
(ii) Enzymes that hydrolyse the a – 1, 4 bonding, but cannot by-pass the a – 1,6 bonds: Beta
amylase: This was originally found only in plants but has now been isolated from
micro-organisms. Beta amylase hydrolyses alternate a – 1,4 bonds sequentially
from the non-reducing end (i.e., the end without a hydroxyl group at the C – 1
position) to yield maltose (Figs. 4.3 and 4.5). Beta amylase has different actions on
amylose and amylopectin, because it cannot by-pass the a – 1:6 – branch points in
amylopectin. Therefore, while amylose is completely hydrolyzed to maltose,
amylopectin is only hydrolyzed to within two or three glucose units of the a – 1.6 -
branch point to yield maltose and a ‘beta-limit’ dextrin which is the parent
amylopectin with the ends trimmed off. Debranching enzymes (see below) are able
to open up the a – 1:6 bonds and thus convert beta-limit dextrins to yield a mixture
of linear chains of varying lengths; beta amylase then hydrolyzes these linear
chains. Those chains with an odd number of glucose molecules are hydrolyzed to
maltose, and one glucose unit per chain. The even numbered residues are
completely hydrolyzed to maltose. In practice there is a very large population of
chains and hence one glucose residue is produced for every two chains present in
the original starch.
 Industrial Media and the Nutrition of Industrial Organisms 71

o = glucose units joined by a-D-(1 ® 4) bonds
l = non-reducing ends of chains
— = point of attack by enzyme

Fig. 4.5 Pattern of Attack of Alpha Amylase and Beta-amylase on Amylose and Amylopectin
Respectively
72 Modern Industrial Microbiology and Biotechnology

(iii) Enzymes that hydrolyze (a —1, 4 and a — 1:6 bonds: The typical example of these
enzymes is amyloglucosidase or glucoamylase. This enzyme hydrolyzes a - D - (1
® 4) -D – glucosidic bonds from the non-reducing ends to yield D – glucose
molecules. When the sequential removal of glucose reaches the point of branching
in amylopectin, the hydrolysis continues on the (1 ® 6) bonding but more slowly
than on the (1 ® 4) bonding. Maltose is attacked only very slowly. The end product
is glucose.
(iv) De-branching enzymes: At least two de-branching enzymes are known: pullulanase
and iso-amylase.
Pullulanase: This is a de-branching enzyme which causes the hydrolysis of a — D
– (1 ® 6) linkages in amylopectin or in amylopectin previsouly attacked by alpha-
amylase. It does not attack a - D (1 ® 4) bonds. However, there must be at least two
glucose units in the group attached to the rest of the molecules through an a -D- (1
® 6) bonding.
Iso-amylase: This is also a de-branching enzyme but differs from pullulanase in that
three glucose units in the group must be attached to the rest of the molecules
through an a - D – (1 ® 6) bonding for it to function.
(v) Enzymes that preferentially attack a - 1, 4 linkages: Examples of this group are
glucosidases. The maltodextrins and maltose produced by other enzymes are
cleaved to glucose by a - glucosidases. They may however sometime attack
unaltered polysaccharides but only very slowly.
(vi) Enzymes which hydrolyze starch to non-reducing cyclic D-glucose polymers known as
cyclodextrins or Schardinger dextrins: Cyclic sugar residues are produced by Bacillus
macerans. They are not acted upon by most amylases although enzymes in
Takadiastase produced by Aspergillus oryzae can degrade the residues.

4.7.1.1.4 Industrial saccharification of starch by enzymes
In industry the extent of the conversion of starch to sugar is measured in terms of dextrose
equivalent (D.E.). This is a measure of the reducing sugar content, expressed in terms of
dextrose, determined under defined conditions involving Fehling’s solution. The D.E is
calculated as percentage of the total solids.
For the saccharification of starch in industry acid is being replaced more and more by
enzymes. Sometimes acid is used only initially and enzymes employed at a later stage.
Acid saccharification has a practical upper limit of 55 D.E. Beyond this, breakdown
products begin to accumulate. Furthermore, with acid hydrolysis reversion reactions
occur among the sugar produced. These two deficiencies are avoided when enzymes are
utilized. Besides, by selecting enzymes specific sugars can be produced.
Starch-splitting enzymes used in industry are produced in germinated seeds and by
micro-organisms. Barley malt is widely used for the saccharification of starch. It contains
large amounts of various enzymes notably b-amylase and a - glucosidase which further
split saccharides to glucose.
All the enzymes discussed above are produced by different micro-organisms and
many of these enzymes are available commercially. The most commonly encountered
organisms producing these enzymes are Bacillus spp, Streptomyeces spp, Aspergillus spp,
Penicillium spp, Mucor spp and Rhizopus spp.
 Industrial Media and the Nutrition of Industrial Organisms 73

4.7.2 Cellulose, Hemi-celluloses and Lignin in Plant Materials
4.7.2.1 Cellulose
Cellulose is the most abundant organic matter on earth. Unfortunately it does not exist
pure in nature and even the purest natural form (that found in cotton fibres) contains
about 6% of other materials. Three major components, cellulose, hemi-cellulose and
lignin occur roughly in the ratio of 4:3:3 in wood. Before looking more closely at cellulose,
the other two major components of plant materials will be briefly discussed.

4.7.2.2 Hemicelluloses
These are an ill-defined group of carbohydrates whose main and common characteristic
is that they are soluble in, and hence can be extracted with, dilute alkali. They can then be
precipitated with acid and ethanol. They are very easily hydrolyzed by chemical or
biological means. The nature of the hemicellulose varies from one plant to another. In
cotton the hemicelluloses are pectic substances, which are polymers of galactose. In
wood, they consist of short (DP less than 200) branched heteropolymers of glucose,
xylose, galactose, mannose and arabinose as well as uronic acids of glucose and
galactose linked by 1 – 3, 1 – 6 and 1 – 4 glycosidic bonding.

4.7.2.3 Lignin
Lignin is a complex three-dimensional polymer formed from cyclic alcohols. (Fig. 4.6). It
is important because it protects cellulose from hydrolysis.
Cellulose is found in plant cell-walls which are held together by a porous material
known as middle lamella. In wood the middle lamella is heavily impregnated with lignin
which is highly resistant and thus protects the cell from attack by enzymes or acid.

4.7.2.4 Pretreatment of cellulose-containing materials
before saccharification
In order to expose lignocellulosics to attack, a number of physical and chemical methods
are in use, or are being studied, for altering the fine structure of cellulose and/or breaking
the lignin-carbohydrate complex.
Table 4.8 Various pretreatment methods used in lignocellulose substrate preparation

Pretreatment type Specific method
Mechanical Weathering and milling-ball, fitz, hammer, roller
Irradiation Gamma, electron beam, photooxidation
Thermal Autohydrolysis, steam explosion, hydrothermolysis,
boiling, pyrolysis, moist or dry heat expansion
Alkali Sodium hydroxide, ammonium hydroxide
Acids Sulfuric, hydrochloric, nitric, phosphoric, maleic
Oxidizing agents Peracetic acid, sodium hypochlorite, sodium chlorite,
hydrogen peroxide
Solvents Ethanol, butanol, phenol, ethylamine, acetone, ethylene glycol
Gases Ammonia, chlorine, nitrous oxide, ozone, sulfur dioxide
Biological Ligninolytic fungi
74 Modern Industrial Microbiology and Biotechnology

Fig. 4.6 Generalized Structure of Lignin

Chemical methods include the use of swelling agents such a NaOH, some amines,
concentrated H2SO4 or HCI or proprietary cellulose solvents such as ‘cadoxen’ (tris
thylene-diamine cadmium hydroxide). These agents introduce water between or within
the cellulose crystals making subsequent hydrolysis, easier. Steam has also been used as
a swelling agent. The lignin may be removed by treatment with dilute H2SO4 at high
temperature.
Physical methods of pretreatment include grinding, irradiation and simply heating
the wood.

4.7.2.5 Hydrolysis of cellulose
Following pretreatment, wood may be hydrolyzed with dilute HCI, H2SO4 or sulfites of
calcium, magnesium or sodium under high temperature and pressure as described for
sulfite liquor production in paper manufacture see section 4. above). When, however, the
aim is to hydrolyze wood to sugars, the treatment is continued for longer than is done for
paper manufacture.
A lot of experimental work has been done recently on the possible use of cellulolytic
enzymes for digesting cellulose. The advantage of the use of enzymes rather than harsh
chemicals methods have been discussed already. Fungi have been the main source of
cellulolytic enzymes. Trichoderma viride and T. koningii have been the most efficient
cellulase producers. Penicillicum funiculosum and Fusarium solani have also been shown
to possess equally potent cellulases. Cellulase has been resolved into at least three
components: C1, Cx, and b-glucosidases. The C1 component attacks crystalline cellulose
and loosens the cellulose chain, after which the other enzymes can attack cellulose. The
 Industrial Media and the Nutrition of Industrial Organisms 75

Cx enzymes are b - (1 ® 4) glucanases and hydrolyse soluble derivatives of cellulose or
swoollen or partially degraded cellulose. Their attack on the cellulose molecule is
random and cellobiose (2-sugar) and cellotroise (3-sugar) are the major products of their
actions. There is evidence that the enzymes may also act by removing successive glucose
units from the end of a cellulose molecule. b-glucosidases hydrolyze cellobiose and short-
chain oligo-saccharides derived from cellulose to glucose, but do not attack cellulose.
They are able to attack cellobiose and cellotriose rapidly. Many organisms described in
the literature as ‘cellulolytic’ produce only Cx and b-glucosidases because they were
isolated initially using partially degraded cellulose. The four organisms mentioned
above produce all three members of the complex.

5
4.7.2.4.1 Molecular structure of cellulose
Cellulose is a linear polymer of D-glucose linked in the Beta-1, 4 glucosidic bondage. The
bonding is theoretically as vulnerable to hydrolysis as the one in starch. However,
cellulose – containing materials such as wood are difficult to hydrolyze because of (a) the
secondary and tertiary arrangement of cellulose molecules which confers a high
crystallinity on them and (b) the presence of lignin.
The degree of polymerization (D. P.) of cellulose molecule is variable, but ranges from
about 500 in wood pulp to about 10,000 in native cellulose. When cellulose is hydrolyzed
with acid, a portion known as the amorphous portion which makes up 15% is easily and
quickly hydrolyzed leaving a highly crystalline residue (85%) whose DP is constant at
100-200. The crystalline portion occurs as small rod-like particles which can be
hydrolyzed only with strong acid. (Fig. 4.7)

A = Original cellulose fibril
B = Initial attack on amorphous region
C = Residue crystalline region
D = Attack on crystalline region

Fig. 4.7 Diagram Illustrating Breakdown of Crystalline Cellulose
76 Modern Industrial Microbiology and Biotechnology

SUGGESTED READINGS
Barnes, A.C. 1974. The Sugar cane. Wiley, New York, USA.
Dahod, S.K. 1999. Raw Materials Selection and Medium Development for Industrial
Fermentation Processes. In: Manual of Industrial Microbiology and Biotechnology. A. L.
Demain and J. E. Davies (eds) American Society for Microbiology Press. 2nd Ed, Washington
DC.
Demain, A.L. 1998. Induction of microbial secondary Metabolism International Microbiology 1,
259–264.
Flickinger, M.C., Drew, S.W. (eds) 1999. Encyclopedia of Bioprocess Technology - Fermentation,
Biocatalysis, and Bioseparation, Vol 1-5. John Wiley, New York.
Ward, W.P., Singh, A. 2004. Bioethanol Technology: Developments and Perspectives Advance in
Applied Microbiology, 51, 53 – 80.