R-factor, or resistance factor, are plasmids that allow specific bacteria to gain resistance against antibiotics. They are mostly available in a set of genetic codes which can transfer themselves from one cell to another of a bacterium via means of conjugation or non-conjugation. Through bacterial conjugation, many r-factors can pass from bacterium to another.
R factor is accountable for coding of antimicrobial resistance against specific drugs. Moreover, they often code restriction for more than a single antibiotic, up to eight different resistances at times. The standard means of spreading antimicrobial resistance among various bacterial species, chromosomes, etc. occur via conjugation.
Define Plasmid
Plasmids are small, extra-chromosomal structure found in bacteria that can replicate itself. These circular molecules of DNA have a double-stranded format, and they are also found in multi-cellular organisms and archaea.
R plasmid is a DNA molecule that grants bacterial resistivity to one antibiotic or more. It comprises of two components primarily – a resistance transfer factor (RTF) and resistance determinants. RTF is a necessary factor responsible for the transmission of plasmids among bacteria, and r-determinants are genetic codes promoting antibiotic resistivity.
What are the Types of Plasmids?
Resistance or R Plasmid: These allow antimicrobial resistance against drugs. They have self-replication capabilities and can be resistant to multiple drugs. It comprises of two types – narrow and broad host range group. The narrow group enables replication within a species, whereas broad one allows transmission among different bacteria.
F-Plasmids: The fertility factor enables genetic coding transmission from one bacterium to another through conjugation. It is a form of a large plasmid and available mostly in Escherichia coli. The ones that contain F factor are termed as F+, and those lacking it are known as F-.
Virulence: They help bacteria to adapt efficiently with their surroundings. Similar to other plasmids, they can also travel from one bacterium to another.
Col Plasmids: They grant the bacteria a capacity to produce venomous proteins called colicines. Specific bacteria use these toxins to destroy other bacteria, thereby thriving in hostile environments.
Degradative: In contrast to other plasmids, they allow the host bacterium to decay xenobiotic components.
Structure of Resistance Plasmid
The resistance plasmid can be said to resemble a circular structure of DNA fragments, and its length varies in the spectrum of 80-95 kb and constitutes of the larger segment of a factor known as the R-RTF or Resistance Transfer Factor molecules. This plasmid is known to be majorly homologous to the F factor and contains quite like genes. It also constitutes a gene known as the fin 0 gene that restrains the task of transferring of the operon. These R factors come in varying sizes and also the kinds of resistance they offer to drugs. The R determinant is smaller in size as compared to the RTF. The RTF as well as the R determinants bind to develop a single unit and are split up from one another by the presence of IS 1 elements on both the sides. The presence of these IS 1 elements encourages the interchange of R determinant amongst the variants of R-RTF units present.
Functions of Resistance Plasmid
Following are the functions of the resistance plasmid -
The resistance plasmids are extremely important in playing a significant part in the transferral of the MDR genes in the bacteria.
The Resistance plasmids are also a part of the gene carrier process for the self-multiplication procedure, uniting and offering resistance against ampicillin.
Resistance is also built to offer against the antibiotics and encourage bacteria to manufacture Pilli, by the resistance plasmids which contain a specific gene which promotes the above-mentioned function
Horizontal Gene Transfer
Bacteria which consists of the F factors, can build a sex pilus which encourages the transmission of the horizontal gene between the bacteria, which is the donor and the bacteria, which is the recipient. The resistance to an antibiotic can quickly and without much hassle and expand amongst the rest of the bacterial community as well. This is because the F factor is present in several R factors too. Due to the presence of the gene known as the RTF or the Resistance Transfer Factor, several R factors can also be consumed by the DNA through the process of transduction or transformation.
Fun Fact
There are more than 100 types of antibiotic drugs! Some most commonly used antibiotics are amoxicillin, azithromycin, penicillin, streptomycin, etc.
Wrack Your Brains
Here are specific questions on r factor and its functioning. Use your knowledge to crack them.
What does fertility plasmids grant to a host bacterium?
Antimicrobial resistance
Ability to conjugate
Multi-drug resistance ability
None of the above
For being able to exist simultaneously in a single cell, non-identical plasmids require
Compatibility
Conjugation
Stability
High in numbers
None of them
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FAQs on R-Factor
1. What exactly is an R-factor in microbiology?
An R-factor, which stands for Resistance Factor, is a type of plasmid found inside bacterial cells. These plasmids are small, circular pieces of DNA that carry specific genes providing the bacteria with resistance to one or more antibiotics.
2. What are the main parts of an R-factor?
An R-factor is typically made of two key components:
- The Resistance Transfer Factor (RTF), which contains the genes that enable the plasmid to be transferred from one bacterium to another.
- The r-determinants, which are the actual genes that provide resistance to specific antibiotics. A single R-factor can have several r-determinants.
3. How does the R-factor spread between different bacteria?
R-factors spread through a natural process called bacterial conjugation. During conjugation, a bacterium with an R-factor forms a physical connection (called a pilus) with another bacterium and transfers a copy of the plasmid. This allows resistance to spread very quickly through a bacterial population.
4. Why are R-factors considered a major problem in medicine?
R-factors are a significant medical concern because they are a primary cause of antibiotic resistance. When harmful bacteria acquire R-factors, they can survive antibiotic treatments, leading to infections that are very difficult to cure. This contributes to the rise of 'superbugs' that are resistant to multiple drugs.
5. Is the 'R factor' in a liver function test (LFT) the same as the one in biology?
No, they are completely unrelated concepts. The R-factor in microbiology is a plasmid conferring antibiotic resistance. In contrast, the 'R factor' in a medical liver function test is a calculated value used by doctors to help diagnose the type of liver injury. They just happen to share the same name.
6. How is an R-factor different from an F-factor (fertility plasmid)?
Both are bacterial plasmids, but their primary roles differ. The F-factor (Fertility factor) mainly carries genes for conjugation, allowing the bacterium to transfer genetic material. The R-factor is more complex; it contains genes for conjugation (the RTF part) as well as genes for antibiotic resistance (the r-determinants part).
7. Can bacteria gain resistance to multiple antibiotics from a single R-factor?
Yes, and this is what makes them so dangerous. A single R-factor can carry multiple r-determinant genes, with each gene providing resistance to a different antibiotic. When a bacterium receives this plasmid, it can become resistant to several drugs all at once, making it a multi-drug resistant organism.
