Phages were discovered
independently in 1915 by the British microbiologist Felix Twort and in 1917 by
French-Canadian microbiologist Felix d’Herelle. Responsible for the systematic
investigation of the nature of bacteriophages, d’Herelle in 1921 first utilized
phages for the treatment of dysentery in Paris, France [1]. This treatment
resulted in the rapid recovery of patients and brought relevance to phage
therapy as a clinical treatment method. Continued study and clinical use led to
d’Herelle becoming the leading expert on phage therapy in this period.
Throughout the early 20th century d’Herelle and other microbiologist isolated
phages for the treatment of pathogenic bacteria such as Shigella dysenteriae, Salmonella typhi, Escherichia coli, Pasteurella
multocida, Vibrio cholerae, Yersinia pestis, Pseudomonas aeruginosa, Neisseria
meningitis and various strains of Streptococcus [2]. By 1931 d’Herelle had
established phage therapy centers across the world, in the United States,
France, and Soviet Georgia. While phage therapy showed promise, it was weighed
down by a few major problems. These problems included host range, genetic
variation, and the inability to consolidate the value of phage in prevention of
infectious disease. These problems eventually led to the fall of phage therapy.
In this time period, phage therapy was poorly incorporated into the field of
medicine, lacking theories that could be integrated with other notions of
conventional medicine [3]. The discovery of antibiotics as an efficacious treatment
method against bacterial infections led to a decreased interest in the
development of phage therapy. While phage therapy maintained some traction in
the Eastern world, it was all but forgotten in the Western world. At the turn
of the 21st century the field of medicine faced a new challenge. The overuse
and eventual abuse of antibiotics over the span of the 20th century led to the
prevalence of antibiotic-resistant bacterial strains [4-6]. The inability to
treat these bacterial infections with standard antibiotics makes them a
significant threat to public health. The continued prevalence of
antibiotic-resistant bacterium has led to the need for new novel antimicrobial
agents, renewing interest in phage therapy as a potential novel therapeutic
treatment. When considering phage therapy in this modern era there are three
major characteristics of phages that lead to their consideration as a potential
treatment method: 1) Host specificity: Phage targets bacteria with high
specificity. This characteristic ensures that phage treatment would only infect
the target bacteria while natural micro biota is unaffected. 2) Genetic
engineering: In the early stages of phage therapy genetic engineering was not
an available option. With current advances in science, we are now able to
engineer phages to express traits of potential value. 3) Phages are ideal
candidates for co-therapy with antibiotics: Co-therapy involves the use of both
antibiotics and phage therapy for the treatment of multidrug resistant
bacteria. The advancement of science since the discovery of phages in the early
20th century has led to a greater understanding of phages and an increased
ability to utilize them for the benefit of public health [7-11]. As we now
enter the 21st century, the prevalence of antimicrobial resistance
(AMR) in bacteria has increased on account of the massive and sometimes
inappropriate use of antibiotics. Antibiotic-resistant bacterial infections
account for over 2.8 million infections and 35,000 deaths annually in the
United States alone [5]. The continued occurrence and prevalence of
antibiotic-resistant bacterial strains is considered a serious threat to global
health and the economy [12-18]. The Institutes of Medicine estimates that the
annual cost of antibiotic-resistant bacterial infections in the United States
is approximately 4 to 5 billion USD [19,20]. Increased prevalence of
antibiotic-resistant bacterial strains as well as a decrease in antibiotic
development is a critical issue in the field of medicine [21,22]. Estimates from
the United Kingdom project that antibiotic-resistant bacteria could result in
losses to approximately 100 trillion USD worldwide by 2050, with a potential
death toll up to 10 million per year [19]. Considering this, development of
novel treatment methods for antibiotic-resistant bacterial infections is
crucial for the preservation of international health and economy. In recent
research into antibiotic alternatives, bacteriophages and their components have
gained relevance as potential novel therapeutic treatment methods [7-11]. Phage
therapy utilizes phage particles that specifically infect and lyse bacterial
cells. A major benefit of phage therapy is host specificity; phages only infect
prokaryotic cells and cannot infect eukaryotic cells. The development of new
alternative treatment methods for bacterial infections are subject to technical
and regulatory challenges. Challenges of alternative treatment methods such as
phage therapy include activity spectrum, pharmacokinetics, immune response,
manufacturing logistics, regulation, quality control, and market acceptance
[23]. While these alternative treatments may not be able to replace antibiotics
completely, it has been suggested that use in unison with antibiotics could be
a potentially viable method for treatment of multidrug resistant bacterial
strains [24-26]. This review will focus on the development of phage therapy
specifically against methicillin-resistant Staphylococcus aureus (MRSA), a
serious threat to public health (Table 1).
Table 1: Distinguishing features
between CA-MRSA and HA-MRSA.
|
Feature
|
CA-MRSA
|
HA-MRSA
|
|
At-Risk
Population
|
Young,
healthy individuals with no exposure to healthcare facilities
|
Individuals
with previous contact to healthcare facilities. (e.g., Hospitals, Nursing
Homes)
|
|
Risk Factors
|
Frequent
skin-to-skin contact, use of intravenous drugs, HIV, crowded or unsanitary
living conditions
|
Long hospital
stays, frequent antibiotic usage, intravenous tubing, compromised immune
system, invasive procedures, devices, and surgery
|
|
Infection
Type
|
Mild to
moderate skin and soft tissue infections
|
Severe,
invasive disease in patients or individuals in frequent contact with
healthcare facilities
|
|
Infection
Locations
|
Skin and soft
tissues, lung
|
Bloodstream,
lung, surgical site, prosthetic implant
|
|
Antibiotic
Resistance Pattern
|
Susceptible
to many antibiotics except Beta-lactams
|
Multi-resistant
to several antibiotics
|
Methicillin-resistant S.
aureus (MRSA) is one of the most common and clinically relevant examples of an
antibiotic resistant bacteria [5,27]. MRSA is the result of a S. aureus
infection that has developed resistance to antibiotics commonly used for the
treatment of these infections. MRSA is the result of misappropriate use of
antibiotics over the span of the 20th century. MRSA is categorized into two
general types, healthcare associated MRSA (HA-MRSA) and community associated
MRSA (CA-MRSA). Most MRSA cases fall under HA-MRSA infections associated with
invasive procedures or devices such as surgeries, intravenous tubing, or
artificial joints. Contamination of these devices can lead to deadly MRSA
infections and outbreaks in healthcare facilities. In general, those exposed to
MRSA in the healthcare setting are typically more susceptible to adverse
outcomes as a result of acquiring this infection due to the compromised state
of their health [5,27]. CA-MRSA is not as a common and occurs in healthy
communities. CA-MRSA infections are commonly associated with skin-to-skin
contact among individuals. Conditions that can place individuals at risk for acquiring
these infections are group sports that induce skin-to-skin contact, working in
child-care, intravenous drug use, or crowded living conditions. The ability of
S. aureus to develop resistance paired with the inappropriate use of
antibiotics of has created a potentially deadly pathogen (Figure 1).

Figure 1: A chronological map
outlining several important aspects of S. aureus treatment, evolution, and
impact.
Figure 2: Diagrammatic
illustration of the mechanism of inhibition of antibiotic resistance of MRSA.
Figure 1 outlines several
notable timepoints in the history of S. aureus of the mid-20th to early 21st
centuries. In 1940, the discovery of penicillin as a miracle drug offered an
unlimited hope to bacterial control, however, within the space of two years, S.
aureus developed resistance to penicillin [7,28-30]. By 1960 over 80% of S.
aureus strains had developed resistance to penicillin [28,30]. Methicillin was
introduced in 1961 as an alternative treatment of S. aureus. Only a year later,
S. aureus developed resistance to this antibiotic as well [29]. The first
outbreak of MRSA was recorded in 1968, this was followed with the second and
third outbreaks between 1970 and 1980 [29]. By 1980 MRSA had spread worldwide.
In 1990, vancomycin became the drug of choice against MRSA, however there was
an observed rise in intermediate vancomycin resistance, leading to the
occurrence of complete vancomycin resistance in 2002 [29,31]. Since 2002, MRSA
prevalence coupled with a decrease in antibiotic development created a serious
risk for public health. Several researchers have delved into antibiotics
against MRSA; however, none have reached clinical applicability [32,33]. In
2009, a group of researchers set out to examine the safety of
bacteriophage-based formulations for the treatment of wounds caused by S.
aureus [34]. In a phase I clinical trial they reported that there were no
safety concerns with the use of bacteriophage treatment, nonetheless, they
encouraged a vigorous test for efficacy of the phage preparations in a phase II
trial [34]. As we continue to discuss MRSA and the significant hazard it
possesses to public health, it is essential that we discuss and explain what
makes this pathogenic bacterium so difficult to treat on a molecular level.