Plasmids have found important applications in biotechnology especially in recombinant DNA technology. However, most antibiotic resistant genes are transferred from one organism to the other through horizontal transfer of gene via this vehicle.
2. Presentation outline
Introduction
Properties of plasmid
Antibiotic plasmid
Mechanisms of resistance specified by
plasmid
Conclusion
References
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3. Introduction
The rapid dissemination of antibiotic resistant (ART) pathogens
threatens human health and may have significant social and
financial impacts. It is well recognized that applications of
antibiotics in human clinical therapy, aquaculture, and food
animal production all contribute to the emergence and
amplification of ART pathogens due to selective pressure.
A broad spectrum of commensal bacteria, including lactic
acid bacteria, have been identified as being carriers of AR
genes and are able to horizontally transfer those genes to
other bacteria, leading to increased resistance in the
recipient organisms and Plasmids have been directly
implicated in the acquisition of resistance to many
antibiotics (Feld et al., 2009)
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4. Introduction cont’d
Plasmids are small
circular pieces of extra
chromosomal DNA
that replicate
independently from the
host's chromosomal
DNA (Bennett, 2008)
R-pasmid
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5. Properties of the R-Plasmid
Must carry the antibiotic resistance genes
Must have origin of replication and origin of transfer
Must be able to replicate it own DNA independently
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6. Classes of plasmids based on functions
R-plasmid
F plasmid
Virulence plasmid
Degradative plasmid
Col plasmid
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7. Antibiotic resistance
plasmid
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Genes conferring
antibiotic resistance are
commonly found on
elements known as
integrons and
transposons, which
facilitate movement
between different
replicons such as
between the bacterial
chromosome and a
plasmid
9. Mechanisms of antibiotic resistance
specified by plasmid
by carrying resistance genes which produces enzymes
that inactivate the antibiotic e.g β-Lactams where β-
lactamases are produced and chloramphenicol where
acetyl transferase inactivate the drug to 3ꞌ-acetoxy
chloramphenicol.
carrying a mutated gene which lead to impaired
transport across the membrane i.e causes decrease in
permeability of antibiotic e.g mutation on UNC gene
which impair transport of gentamicin.
Alteration of target site e.g MecA gene in
Staphylococcus aureus which produces penicillin
binding protein 2ꞌ that confer resistance to methicillin.
by pass mechanism is another way plasmid cause
antibiotic resistance
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10. Conclusions
Plasmid encoded resistance to antibiotic
by microbial cells is due to R-plasmid
carrying antibiotic resistance gene. A copy
of this plasmid is transferred to a recipient
through conjugation with all the resistance
gene and character which expresses the
resistance in the donor.
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11. References
Avison MB, Bennett PM (2005). Bacterial genetics. In: Borriello SP, Murray PR, Funke
G (eds), Topley & Wilson’s Microbiology & Microbial Infections 10th edn: Vol. 1,
Bacteriology. Hodder Arnold: London, pp 80–135.
Bennett P. M. (2008) Plasmid encoded antibiotic resistance: acquisition and transfer of
antibiotic resistance genes in bacteria. British Journal of Pharmacology 153, S347–
S357
Bergstrom CT, Feldgarden M (2008) The ecology and evolution of antibiotic resistant
bacteria. In Evolution in Health and Disease, 2 edition. Edited by: Stearns S, Koella
J. Oxford: Oxford University Press.
Duran, G. M., D. L. Marshall (2005) Ready-to-eat shrimp as an international vehicle of
antibiotic-resistant bacteria. J. Food Prot. 68:2395–2401.
Davies J and Davies D (2010) Origins and evolution of antibiotic resistance.
Microbiology and Molecular Biology Review 74: 417–433.
Fabian Svara and Daniel J Rankin (2011) The evolution of plasmid-carried antibiotic
resistance BMC Evolutionary Biology 11:130
Feld, L., E. Bielak, K. Hammer, A. Wilcks (2009) Characterization of a small
erythromycin resistance plasmid pLFE1 from the food-isolate Lactobacillus
plantarum M345. Plasmid 61:159–170.
Institute of food Technologist (2006). Antimicrobial resistance: implications for the food
system. Institute of food technologists, Chicago, IL. http://www.ift.org/knowledge-
center/read-ift-publications/science-reports/expert-reports/antimicrobial-
resistance.aspx. 6/15/2017 11