ABSTRACT
Streptomyces species was isolated from soil samples using spread plate method on Streptomyces agar while Streptomyces broth was used for fermentation and optimization. The varied culture conditions evaluated were pH, Mineral salt concentration, speed of agitation and nutritional components tested were Carbon and Nitrogen sources. The production of antimicrobial metabolite was authenticated by antimicrobial activity against Staphylococcus aureus and Pseudomonas aeruginosa. Amongst the carbon sources, maximum production of antimicrobial metabolite was observed with the medium containing Galactose anhydride evident by high inhibition zone of 32mm and 23mm (Staphylococcus aureus and Pseudomonas aeruginosa) respectively. This was followed closely by the medium incorporated with glycerol and glucose. Maximum productivity of antimicrobial metabolite was also achieved with the medium containing malt extracts evident with an inhibition zone of 30mm and 27mm for Staphylococcus aureus and Pseudomonas aeruginosa. This was also followed by the medium containing yeast extract. For pH, maximum metabolite production was attained in the medium adjusted to 10, with an inhibition zone of 30mm and 33mm for Staphylococcus aureus and Pseudomonas aeruginosa respectively, which was closely followed by pH 9. For the medium incorporated with additional mineral salts, best metabolite production was obtained at a concentration of 0.30mol/ml evident by an inhibition diameter of 30mm and 27mm for the respective test organisms. Best antimicrobial metabolite production was also observed with the medium whose agitation speed was 250rpm. This gave an inhibition diameter of 26mm and 23mm respectively against the test organisms. Finally, for better productivity of antimicrobial metabolite by Streptomyces species, carbon source such as Galactose anhydride, Nitrogen source such as malt extract, mineral concentration of 0.30mol/ml, pH of 10 and agitation speed of 250rpm, should be used.
TABLE
OF CONTENTS
Certification ii
Dedication iii
Acknowledgements iv
Table of Contents v
List of Tables viii
List
of Figures ix
Abstract x
Chapter
One
1.0.
Introduction 1
1.1 Aim 3
1.2 Objective 4
Chapter Two
2.0
Literature review 5
2.1 Antimicrobial metabolites produced by Streptomyces species 5
2.1.1 History 5
2.1.2 Synthesis 6
2.1.3 Composition 6
2.1.4 Spectrum of activity 7
2.1.5 Mechanism of action 7
2.1.6 Clinical uses 8
2.2. Streptomycetes 9
2.2.1 Habitat and
reproduction 12
2.2.2 Genome 14
2.2.3 Ecology 14
2.2.4. Streptomyces as human pathogens 16
Chapter Three
3.0 Materials and method 17
3.1 Collection of samples 17
3.2 Sterilization of apparatuses and
equipment 17
3.3. Preparation of culture and fermentative
media 17
3.4. Isolation of Streptomyces 18
3.5 Test organisms used in screening 18
3.6 Confirmation of the test isolates 18
3.7. Antimicrobial metabolites extraction 18
3.8. Antimicrobial screening of the metabolites 19
3.9. Determination of the effect of varied
nutritional requirements on metabolite Production 19
3.9.1. Carbon sources 19
3.9.2. Nitrogen sources 19
3.10. Determination of the effect of varied
culture condition on metabolite production. 20
3.10.1. pH 20
3.10.2. Sodium chloride concentration 20
3.10.3. Speed of agitation 20
Chapter Four
4.0. Results 29
Chapter Five
5.0. Discussion and
Conclusion 30
5.1. Discussion 32
5.2. Conclusion 33
REFERENCE 37
APPENDIX
LIST OF
TABLES
TABLE TITLE
PAGE
Table 1: Colours of substrate mycelium and soluble pigment occurring
in Streptomycetes. 11
Table 2: Isolation and identification of streptomyces species from the different
soil samples that were collected. 23
Table 3: Confirmation of the test organisms Staphylococcus aureus and Pseudomonas aeruginosa. 24
LIST OF FIGURES
FIGURE TITLE PAGE
Figure 1: Showing the effects of varied carbon sources on the production
of Antimicrobial metabolite by Streptomyces species. 25
Figure 2: Showing the effects of varied nitrogen sources in the
production of antimicrobial metabolites by Streptomyces species. 26
Figure 3: Showing the effects of varied pH condition in the production
of Antimicrobial metabolites by Streptomyces species. 27
Figure 4: Showing the effects of varied mineral salt concentration in the production of antimicrobial metabolites by Streptomyces species. 28
Figure 5: Showing the effects of varied speeds of rotation in the
production of antimicrobial metabolites by Streptomyces species. 29
CHAPTER ONE
INTRODUCTION
The search for isolating novel antibiotics, effective against
pathogenic and resistant pathogenic microorganisms from unexplored habitats
around the world, continues to be an important sector of research. The discovery and development of antibiotics has
played a major role in clinical medicine, agricultural research works and
generally all works of life (Moses, 2015).
Antibiotics are chemical substances with a molecular weight generally below 2
kilo Dalton (Moses, 2015) that either inhibits or kills viruses, bacteria or
fungi. If the antibiotic kill, it is referred to as cidal (Bactericidal,
viricidal and fungicidal) and if it inhibits, it is referred to as static
(Bacteristatic, viristatic and fungistatic).
Antibiotics are grouped into three groups, based on their
source. This includes:
a)
Synthetic antibiotics
This includes all antibiotics produced purely from chemical
processes which involves no microorganism in its production procedures. This
group of antibiotics are not produced as antimicrobial metabolites or products
of microorganisms but instead are produced by chemical processes. Examples
include amoxicillin and all its derivatives, oxytetracycline, chloramphenicol,
chlortetracycline, minocycline etc.
b)
Semisynthetic antibiotics
This includes antibiotics that are produced by microorganisms
but their side chains have been modified so as to improve their efficacy. This
entails chemical modification of their side chains to improve the spectrum
activity of the antibiotics. Examples includes Penicillin derivatives;
Penicillin G, Penicillin V, Methicillin, Ampicillin, Ticarcillin etc.
c)
Non- Synthetic antibiotics
This group of antibiotics are purely direct products of
microorganisms. They are direct microbial antimicrobial metabolites without any
modifications attached to them. Examples includes Streptomycin produced by Streptomyces species and penicillin
Produced by Penicillum notatum.
Most
antibiotics are antimicrobial metabolites of microorganisms. Antimicrobial
metabolites are produced by microorganisms in a closed system cultivation, when
they have exhausted all the nutrients available for their growth. Since in a
close system cultivation of microorganisms, there is no replacement of spent
nutrients, the microorganisms are then forced to produce these metabolites
which in some cases, may even be toxic to the producer microorganism.
Streptomycetes have been the most and generally evaluated source
of antibiotics since the discovery of actinomycin D, grisein, streptothricin, and
streptomycin in the 1940s by Waksman and co-workers (Waksman, 1948).
Streptomycetes synthesize a large variety of chemically different but stable
compounds, many of them acting as antibiotics, cytostatics, fungicides, or as
modulators of immune responses (Wolfbang et
al., 2015). Consequently, the study of Streptomyces, are very
numerous in number and each of this genus member produces one or more
antibiotics.
They produce these antibiotics as antimicrobial metabolites. These
antimicrobial metabolites production is controlled by genes. Many of these gene
sets are present in one genome, but not in others. At times, the clusters may
be in same position in different species but can be occupied by different
secondary metabolism. This is the sole reason why these group of microorganisms
produce a vast range of antimicrobial metabolites (Waksman, 1948). For example,
the pks1 cluster of Streptomyces avermitilis MA-4680T is replaced
in Streptomyces ambofaciens ATCC 23877T by a different secondary
metabolism cluster of 28 genes and in Streptomyces coelicolor A3 (2) by
a 31-gene insertion (Wolfbang et al.,
2015). The subtelomeric chromosome arms often contain gene clusters for
secondary metabolism, especially those that are species-specific. The more
abundant genes for secondary metabolism, such as those for the production of
pentalenolactone, different siderophores, and the odour compound geosmin, typically
fall in syntenous locations within the central core region. It is interesting that
the genes for the biosynthesis of antibiotics are frequently located near one
or more genes mediating resistance to the corresponding antibiotic. Asides the
production of streptomycin, and the other pre-listed antibiotics, the following
antibiotics are also produced by Streptomyces
species. They include Actinorhodin, Daunorubicin, Frenolicin, Granaticin, Griseusin
B, Jadomycin B, Mithramycin, Tetracycline, Macrolides, Peptide
antibiotics, Cyclopentenoid antibiotics, Aminoglycosides
These antibiotics produced by the genus
Streptomyces cannot be categorized into one group of antibiotics, due to
the vast the nature of the antibiotics produced. Their spectrum of activity is broad ranged
and their mode of action ranges from cell wall synthesis inhibition to protein
synthesis inhibition (50s and 30s ribosomal distortion). The various physical
and chemical appearance and representation of these antibiotics depends on the
group of antibiotics they fall into (Nzubechi, 2015).
1.1
AIM
The
aim of the study was:
· To
evaluate the effect of varied culture condition and nutritional requirement in
the production of secondary metabolite by Streptomyces
species.
1.2 OBJECTIVES
The
objectives of the study was:
· To
isolate Streptomyces species from
soil samples.
· To
determine the effect of varied carbon sources in the production of antimicrobial
metabolites by Streptomyces species.
· To
ascertain the effect of varied nitrogen sources on antimicrobial metabolites
production by Streptomyces species.
· To
determine the effect of varied pH values in the production of antimicrobial
metabolites by Streptomyces species.
· To
evaluate the effect of varied mineral salts concentration in the production of antimicrobial
metabolites by Streptomyces species.
· To
ascertain the effect of varied speed of agitation on antimicrobial metabolites
production by Streptomyces species.
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