Streptomycin is an antibiotic discovered in 1944 that is produced through fermentation of Streptomyces griseus bacteria. It is used to treat infections caused by gram-positive and gram-negative bacteria as well as tuberculosis. Production occurs over 3 phases, beginning with rapid bacterial growth and ending with cell lysis and harvest. Streptomycin is recovered through adsorption onto activated carbon or ion exchange resins before precipitation and purification. It functions by binding to the bacterial ribosome and inhibiting protein synthesis.
2. Introduction
• Streptomycin is an antibiotic
• It was discovered by Schatz,Bugie and Waksman (1944) in
one of the soil isolates Streptomyces griseus
• Most of the industry used this parent strain for streptomycin
production today also.
• Mutation and selection employed to increase yields to the
present day levels.
• But,nowadays also Streptomycin is produced by streptomyces
griseus and only a few strains of this organism have the
ability to produce reasonable yields of the antibiotic
• It is active against gram Positive and Negative bacteria and
against the tuberculosis organism Mycobacterium tuberculi
3. Uses
It has been used therapeutically in the treatment of
infections caused by organisms resistant to Penicillin
It is also used in the treatment of plant diseases
caused by bacteria
It is used in the treatment of tuberculosis caused by
Mycobacterium tuberculi.
4. Disadvantage
In man, prolonged streptomycin treatment
at high dosage can produce neuro toxic
reactions
particularly problems in balance
maintenance and partial hearing loss
Chemical reduction of streptomycin to
dihydrostreptomycin decreases this
neurotoxicity.
5. Some microorganisms gain resistance
relatively easily to streptomycin and
streptomycin therapy.
So, it is carried out in conjuction with para
aminosalicyclic acid or isoniazid
(isonicotinic acid hydrazide) to decrease
this resistance build up in sensitive
microorganisms
6. Chemical structure
• Streptomycin and dihydrostreptomycin are basic
compounds
• They are usually prepared as salts
• Streptomycin is available as the hydrochloride
C21H39N2O12.3HCL as a crystalline hydrochlroide
double salt with calcium chloride or as the
phosphate or sulfate
• Dihydrostreptomycin as the hydrochloride or
sulfate
7. Depending on the strain of this organism
being used or on the production of medium,
small amounts of mannosidostreptomycin
or hydroxy streptomycin are accumulated in
addition to streptomycin
Some mannosido streptomycin is produced
early in the fermentation, but this antibiotic
is largely enzymatically degraded by
Streptomyces griseus to sterptyomycin at the
time of harvest
The mannosidostreptomycin is not desired
because of its low antibiotic activity
8. The use of precursors does not increase yields of
streptomycin
Most of the carbon of the streptomycin molecule
has shown to originate from glucose and not from
the more complex carbon compounds of the
medium , although some of the carbon molecule
originate from carbon di oxide
The carbonyl function on the streptose moiety is
involved in the antibiotic activity of streptomycin.
Most chemical additions to the carbonyl group
destroy the antibiotic activity.
9. Chemical Structure of Streptomycin
Streptomycin is characterised chemically as an
aminoglycoside antibiotic.
It consists of three components linked glycosidically
(by ether bonds):
(i) Streptidine (inositol with two guanido groups),
(ii) Streptose (methyl pentose), and
(iii)Streptoscamine (N-methyl-L-glycosamine) as shown
in Fig. 1
Both guanido groups of streptidine are essential for the
antibiotic activity and removal of one group reduces
antibiotic activity upto 90%.
Dihydrostreptomycin is produced by reduction of
carbonyl group on the streptose moiety
11. Mechanism of Action of Streptomycin:
Streptomycin, like other aminoglycosidic antibiotics (e.g.,
gentamycin, neomycin, kanamycin, tobramycin), inhibits protein
synthesis in bacterial cells by binding to the 30S subunit of
ribosomes.
Streptomycin is a protein synthesis inhibitor. It binds to the small
16S rRNA of the 30S subunit of the bacterial ribosome, interfering
with the binding of formyl -methionyl tRNA to the 30S subunit.
This leads to codon misreading, eventual inhibition of protein
synthesis and ultimately death of microbial cells through
mechanisms that are still not understood. Speculation on this
mechanism indicates that the binding of the molecule to the 30S
subunit interferes with 50S subunit association with
the mRNA strand. This results in an unstable ribosomal-mRNA
complex, leading to a frame shift mutation and defective protein
synthesis; leading to cell death. The mechanism of inhibition of
protein synthesis by streptomycin is schematically shown in Fig. 2
12. Fig 2: Schematic representation of protein
synthesis inhibition streptomycin
13. Production –medium
Two types of medium were used
1.Woodruff and Mc. Daniel (1954)
1% soyabean meal
1% glucose
0.5% sodium chloride
2.Hockenhull (1963)
2.5% glucose
4% soyabean meal
0.5% distillers dried soluble
0.25% sodium chloride
pH -7.3 to 7.5 before sterilization
14. Inoculum preparation
High yielding mutated strains of streptomyces
griseus are genetically unstable , a fact to be
considered in maintenance of stock cultures.
Because of this consideration, spores of the
organism usually are maintain soil stocks or are
lyophilized in a carrier such as sterile skim milk .
Spores from these stock cultures are then
transferred to a sporulation medium to sporulated
growth to initiate liquid culture buildup of
mycelial inoculum in flasks or inoculum tanks
15. Factors to be consider during production
Streptomycin yields in production fermentors
respond strongly to agitation and aeration. The
optimum temperature in the range of 25oC to 30 o
C ,probably closer to 28o C
The optimum pH for streptomycin production
occurs between pH 7 & 8, high production occur in
the range of pH7.6 to 8
The fermentation production approximately 5-6
days and provides streptomycin yields probably
exceeds of 1200 micrograms per mililiter
17. Biosynthesis of Streptomycin
Streptomycin is directly derived from glucose. Though the
enzymes involved in the synthesis of N-methyl
glucosamine are not yet known, it is expected that about 28
enzymes take part in the conversion of glucose into
streptomycin as précised in Fig. 3
Fig 3. Biosynthetic pathway from D-glucose to Streptomycin
18. Commercial streptomycin fermentation passes through
three phases:
I phase:
lasts approximately 24hours
With rapid growth of the mycelium
Proteolytic activity of streptomyces griseus releases
ammonia to the medium from the soyabean meal
Carbon nutrients of the medium utilized for the growth
Glucose of the medium is utilized slowly during this
period
Only slight streptomycin production occurs
During this period, the pH of the medium rises from
approximately 6.7 or 6.8 to 7.5 or slightly higher
STREPTOMYCIN PRODUCTION
19. II phase
Streptomycin is produced at high rate
Lasts approximately 24 hours to 6 or7 days of
incubation
Almost, no mycelium growth, weight of the mycelium
remains constant
The ammonia is utilized and the pH remains fairly
constant in a range of approximately about 7.6-8
Glucose and oxygen are required in a large quantity.
20. III phase
Sugar has been depleted from the medium
Streptomycin production ceases
Mycelium undergoes autolysis, releasing
ammonia and the pH value rises
The fermentation , however usually is harvested
before cell lysis.
21. Harvest and Recovery of streptomycin
After completion of fermentation the mycelium is
separated from the broth by filtration. Streptomycin is
recovered by several methods. The choice of procedure
depending on the industrial concern.
In one procedure,
The streptomycin is adsorbed from the broth onto the
activated carbon and then eluted from the carbon with
dilute acid. The eluted streptomycin is precipitated by
acetone, filtered and dried before further purification.
22. In an alternative procedure,
The fermentation broth is acidified, filtered
and neutralized. It is then passed through a
column containing a cation exchange resin to
adsorb the streptomycin from the broth.
The column is then washed with water and the
antibiotic is eluted with hydrochloric acid or
cyclohexanol or phosphoric acid. It is then
concentrated at about 60°C under vacuum
almost to dryness.
23. The streptomycin is then dissolved in methanol
and filtered and acetone is added to the filtrate to
precipitate the antibiotic. The precipitate is again
washed with acetone and vacuum dried. It is purified
further by dissolving in methanol. The streptomycin in
pure form is extracted as calcium chloride complex.
Byproduct Vitamin B12
Vitamin B12 is produced as a byproduct which will not
affect adversely the yield of streptomycin.
24. Fig 4.Flow chart of Streptomycin production by
submerged fermentation