USE OF VIRUSES AND VIRUS-RESISTANT MICROORGANISMS FOR CONTROLLING MICROORGANISM POPULATIONS
A lytic virus specific for a target strain of a microorganism and substantially free of undesirable genes may be utilized in processes including control of populations of microorganisms. The virus may include a host-range mutant, or “h-mutant.” A method for generating virus includes growing virus-resistant variants of a target strain of a microorganism in the presence of viruses that are specific for the target strain. Only h-mutant viruses will proliferate. Wild-type virus-resistant and virus-resistant variants of a microorganism are also disclosed, as are methods generating such variants. Methods for controlling target strain microorganisms include introducing virus into a treatment site where control of a population of a target strain microorganism is desired or introducing virus-resistant variants of a microorganism into treatment sites where the presence of the microorganism is desired.
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This application is a divisional of application Ser. No. 11/033,022, filed Jan. 10, 2005, pending. The disclosure of the previously referenced U.S. patent application is hereby incorporated by reference in its entirety.
BACKGROUND OF THE INVENTION Technical FieldThe invention relates to viruses which control and prevent growth of harmful microorganisms and to processes which employ such viruses. It also relates to protection of helpful microorganisms from virus attack. In particular, the viruses of the present invention lack genes for virulence factors, toxins, antibiotic resistance, and other undesirable genes, and include host-range (h-mutant) viruses which are specific for wild-type virus-resistant strains of targeted microorganisms. More specifically, viruses of the present invention are lytic, thus they control and prevent further growth of harmful microorganisms that infect animals or plants by destroying these microorganisms. Such viruses may also be employed to develop and select strains of beneficial microorganisms which are resistant to wild-type and h-mutant viruses.
Viruses are known to alter populations of microorganisms, such as bacteria, fungi, algae, and protozoa. It has been estimated that, in nature, as many as one-third of all bacteria may be attacked by viruses each day. The destruction of microorganisms by viruses results in fluctuations of microbial populations in the environment, which is referred to as “cycling” of microbial populations. For example, populations of microorganisms increase in concentration until viruses contact and infect susceptible microorganisms, which are referred to as host microorganisms or “hosts.” Viral infections of microorganisms decrease the number of available susceptible host microorganisms, and correspondingly increase the number of viruses. Without hosts to infect, many viruses are eventually destroyed by exposure to natural elements, such as ultraviolet light from the sun and enzymes in the environment. Thus, virus numbers decline, while host microorganism populations consequently increase. Such cycling of microbial populations in nature is common. Although it is somewhat difficult to detect and study viruses that attack microorganisms other than bacteria, those of skill in the art are aware that all populations of microorganisms (e.g., algae, rickettsiae, fungi, mycoplasmas, protozoas) are controlled and cycled in a similar manner by viruses that are capable of infecting and destroying such microorganisms.
Bacterial viruses, which are also referred to as “bacteriophages” or “phages,” are ubiquitous and can be isolated from all bacterial populations where hosts can be cultivated and used for isolation. Phages are naturally-occurring entities that are found in or on animals (including humans), plants, soil, and water. Viruses which infect algae, molds, mycoplasmas, protozoa, rickettsiae, yeasts, and other microorganisms are also known.
Two methods are typically employed in order to determine the concentration, which is also referred to as “quantification,” of viruses in natural environments. First, electron microscopy may be used to visualize and count total viral particles in a sample of known size. Second, viable viruses may be cultured, or grown, and counted. An exemplary method of quantification by culturing and counting includes a technique which is typically referred to as a plaque assay. In plaque assays, the viruses that are to be quantified are mixed with a predetermined concentration of host cells and transferred to a liquid (e.g., buffer, mineral salts diluent, or broth). The mixture is then transferred to a semisolid growth medium. The concentration of host cells must be sufficiently great to form a confluent layer, which is typically referred to as a “lawn,” in the semisolid growth medium as the cells grow. During incubation of the phage-host mixture, many of the viable viruses infect host cells. Subsequently, new viruses are produced within infected host cells, which are eventually destroyed, or “lysed,” so that new viruses may be released therefrom. The new viruses then attack and eventually lyse cells that are adjacent to host cells from which the new viruses were released. This spread of infection, which continues as long as host cells are metabolizing, results in formation of clear areas, which are typically referred to as “plaques,” in the host cell lawn. The number of viruses that were present in the original mixture is determined by counting the number of plaques that are formed in the host cell lawn. Accordingly, viruses that are quantified by this method are referred to as plaque-forming units (“PFU”).
In order to quantify all of the various types of viruses in an environmental sample by culturing host cells and counting PFUs, host cells for each of the different viruses in the sample must be cultured. Many types of microorganisms in a given environmental sample are not known. Some of the known microorganisms cannot be cultivated. Therefore, the number of viruses that are present in a given environment may be underestimated when quantified by culturing and counting. Although it is estimated that one gram of soil includes as many as 108 to 109 microorganisms, quantification techniques such as direct plate counting, selective isolation, microscopy, and reassociation kinetics of total DNA isolated from soil suggest that only a very small percentage of these microorganisms can be cultured. Thus, the development and application of direct electron microscopic counting methods have provided a better understanding of the number of viruses that are present in various environments, as well as the impact that viruses have in reducing microbial populations.
Phages have been quantified in water. Bergh et al. (1989), High abundance of viruses found in aquatic environments, Nature 340:467, used electron microscopy to determine the total concentration of bacterial viruses in a natural, unpolluted Norwegian lake. Phage concentrations of up to about 2.5×108 phages/ml were found in the water. Bacterial counts were as high as about 1.5×107 cells/ml. From these relative concentrations of phage and bacteria, it was estimated that as many as one-third of the bacterial population experiences one or more phage attacks each day. Similarly, Demuth et al. (1993) Direct electron microscopy study on the morphological diversity of bacteriophage populations in Lake Plussee, Appl. Environ. Microbiol. 59:3378, determined that phage levels in a German lake without sewage influences were as high as about 108 phages/ml of lake water. As many as eleven morphologically different phages were identified in the water samples.
Phages have also been quantified in soil. Using the culturing and counting method, with Bacillus stearothermophilus as the host cell, Reanny, D. C. and Marsh S. C. N. (1973). The ecology of viruses attacking Bacillus stearothermophilus in soil, Soil. Biol. Biochem. 5:399, reported that, on average, about 4.0×107 PFUs that would infect B. stearothermophilus were present in a gram of soil. Only phages against a single host were, however, quantified in the Reanny and Marsh study. Thus, had other bacterial hosts been tested along with B. stearothermophilus, or had electron microscopy quantification techniques been employed, phage counts would probably have been much higher.
Phages are also present in foods. Kennedy et al. (1986) Distribution of coliphages in various foods, J. Food Protect. 49:944, found Escherichia coli and phages that attack E. coli (“coliphages”), in 11 of 12 tested foods, each of which are available in many retail markets. For example, all ten ground beef samples tested by Kennedy et al. were contaminated with coliphages. Coliphages were also present in samples of fresh chicken, fresh pork, fresh oysters, fresh mushrooms, lettuce, chicken pot pie, biscuit dough, deli loaf, deli roasted turkey and packaged roasted chicken. Similarly, Gautier et al. (1995) Occurrence of Propionibacterium freudenreichii bacteriophages in Swiss cheese, Appl. Environ. Microbiol. 61:2572, detected Propionibacterium freudenreichii phage concentrations of about 7×105 PFU/g in Swiss cheese.
Both undesirable and beneficial microorganisms are present in the environment. Viruses infect and destroy both beneficial and undesirable microorganisms. Soil microorganisms that enhance plant growth and microorganisms that degrade toxic substances are exemplary of beneficial microorganisms in the environment. Undesirable microorganisms include pathogenic microorganisms and algae that cause algal blooms and fish kills.
In addition to naturally-occurring microbial populations, in recent decades disease-causing microorganisms resistant to antibiotics have become epidemic in many hospitals, and have been notoriously difficult to control. During the past fifty or more years, the widespread use of antibiotics has resulted in the selection of antibiotic-resistant bacterial strains. Staphylococcus aureus, Streptococcus pneumoniae, Streptococcus pyogenes, Enterococcus faecalis, Salmonella typhi, Hemophilus ducreyi, Hemophilus influenzae, Mycobacterium tuberculosis, Neisseria gonorrhoeae, Pseudomonas aeruginosa, various Shigella species, members of the Enterobacteriaceae and Pseudomonas families, and other bacterial species are resistant to many of the conventionally-employed antibiotics. Infections that are acquired during hospitalization, which are typically referred to as nosocomial infections, cause an estimated 60,000 deaths per year, and require treatment, which has been estimated to cost about $4.5 billion per year recently.
Statistics from the Centers for Disease Control and Prevention (CDC) indicate that the majority of nosocomial infections are caused by E. coli, S. aureus, coagulase-negative staphylococci, enterococci, pneumococci, and pseudomonads. In addition, according to the 1996 World Health Organization (WHO) annual report, “drug-resistant strains of microbes have evaded common treatments for tuberculosis, cholera, and pneumonia.”
Consequently, the occurrence of infections that are caused by antibiotic-resistant bacteria has steadily increased in hospitals, localized communities, and at-risk populations worldwide since the 1940s, shortly after antibiotics were first used for treating bacterial infections. For example, in 1941 practically all strains of S. aureus throughout the world were susceptible to penicillin G. By 1944 however, some strains of S. aureus were capable of making penicillinase, which is also typically referred to as β-lactamase, which degrades penicillin. In 1996, some strains of S. aureus were not only resistant to various forms of penicillin, but also to six of the seven other antibiotics that are conventionally used to treat S. aureus (“staph”) infections.
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- 1) Since 1988, the potential for selection of vancomycin-resistant mutants was a concern in that such resistance had been identified in Gram-positive bacteria, such as vancomycin-resistant E. faecalis, or faecium (“VREF”); VREF are also of great concern to health care professionals due to their deadly combination of antibiotic resistance, rapid spread, and high mortality rates in patients with VREF-associated infections.
- 2) Infections by methicillin-resistant S. aureus (“MRSA”) pose an especially serious public health threat. MRSA typically display various patterns of multiple-drug resistance (i.e., are resistant to multiple types of antibiotics). Many strains of MRSA are susceptible only to the antibiotic vancomycin.
- 3) Although new and alternative drugs for treating infections of antibiotic-resistant strains of bacteria have been developed and discovered, many bacteria also develop resistance to such new and alternative drugs. For example, certain MRSA strains quickly developed resistance to the antibiotic ciprofloxacin. Moreover, in 1997, a strain of S. aureus was isolated from an infection that resisted 29 days of vancomycin treatment. To put the threat posed by this S. aureus strain in perspective, this S. aureus strain was categorized by the CDC as having intermediate resistance somewhat short of full resistance, and was labeled a medical red alert. It was reported that if MRSA strains which have resistance to vancomycin develop, death rates for all surgeries, including elective surgeries, may increase.
- 4) In 2001 the isolation of MRSA from three heart patients at McKay-Dee Hospital in Ogden, Utah, resulted in closure of its cardiac surgical units to all but emergency surgeries. Subsequently, vancomycin-resistant S. aureus (VRSA) have been isolated from clinical patients in Michigan (2002), Pennsylvania (2003) and New York (2004).
Similarly, about half of the known strains of S. pneumoniae are resistant to penicillins, which have conventionally been employed as the initial and primary treatment for S. pneumoniae infections. Some S. pneumoniae strains are resistant to cephalosporin antibiotics, which have conventionally been employed as a secondary treatment for S. pneumoniae infections. Penicillin and cephalosporin-resistant S. pneumoniae strains may be treated with vancomycin. The use of vancomycin, however, is undesirable because of severe side effects that vancomycin has on many patients and the possibility that vancomycin-resistant strains of S. pneumoniae may emerge.
The problem of antibiotic resistance is further compounded by the fact that microorganisms may transfer genetic information, which is referred to as “genes,” or “DNA” for simplicity. Methods by which microorganisms, such as bacteria, can transfer DNA, and even entire genes, include conjugation, transformation, and transduction. Various genes, including genes that impart bacteria with resistance to antibiotic drugs, may be transferred from a first, or donor, microorganism to a second, or recipient, microorganism. In addition to transferring genes for antibiotic resistance, microorganisms may transfer genes that enable a microorganism to produce toxins, which are typically harmful to an infected host. Virulence factors, which determine the types of hosts and host cells that a microorganism can infect may also be transferred from one microorganism to another.
In conjugation, plasmid or chromosomal DNA is transferred directly from a donor microorganism to a recipient microorganism by means of specialized pili or “sex pili,” which are small, hollow, filamentous appendages, which bind to and penetrate the cell membrane of recipient microorganisms. Conjugation is a process by which genes that code for antibiotic resistance in the “donor” microorganism pass to a recipient microorganism, transforming the recipient into an antibiotic-resistant microorganism.
Transformation is the transfer of DNA that has been released into the environment by a donor microorganism and incorporated by a recipient microorganism. Transformation experiments have been conducted in sterile soil that was inoculated with two parental strains of Bacilus subtilis with differentially marked, or tagged, DNA. Bacteria were isolated which carried the markers of both parental strains. Even under the best laboratory conditions, however, transformation is relatively inefficient and requires high densities of donor DNA and recipient cells. Conditions that would permit transformation in many microorganisms are typically not present in a natural, or uncontrolled, environment. Consequently, transformation is typically perceived as a laboratory phenomenon.
Transduction is the transfer of host genes to recipient microorganisms by viruses, such as phages. There are two kinds of phages, virulent, or lytic, and temperate. When a host cell is infected with a virulent phage, new phages, which are typically referred to as progeny, are grown in the host cell, and the host cell is subsequently lysed, or destroyed, so that the progeny may be released. In contrast, temperate phages typically infect host cells without destroying their host. Following infection of a host cell, temperate phages typically incorporate their genetic information into the DNA of the host cell. Many temperate phage-infected host cells can be subsequently induced, by ultraviolet light, mutagens, or otherwise, to enter a lytic cycle, wherein genetic information of the temperate phage produces progeny which then lyse the host cell.
Transduction of host DNA may be either “specialized” or “generalized.” In specialized transduction, a temperate phage's genome is integrated into the chromosome of a host donor microorganism without lysing the host. The phage genome that was inserted into the host chromosome, is referred to as a “provirus,” or “prophage,” and is passively replicated as the host cell and its chromosome replicate. Bacteria that carry proviruses are said to be lysogenic. Certain events, such as exposing the host microorganism and the provirus to ultraviolet light, may cause the provirus to act as a virulent phage, whereby the provirus is excised from the bacterial chromosome. Such excised proviruses may carry bacterial genes, or “donor” genes, with them. Upon infecting a new host, or recipient microorganism, these “donor” genes may be expressed, which may alter the phenotype, or physical gene expression, of the recipient microorganism.
Temperate and, possibly, some virulent phages may effect generalized transduction. During viral replication, a section of DNA of the donor microorganism, which is referred to as a “donor” gene, rather than the phage genome, may be enclosed inside a phage head. Phages that include only DNA of a host microorganism are referred to as transducing particles. A typical phage is only capable, however, of containing about one percent of the chromosome of a host, or “donor,” microorganism. Thus, the simultaneous transfer of more than one gene by a single transducing particle is unlikely. Since transducing particles do not include a phage genome, transducing particles cannot produce progeny upon infecting a recipient microorganism. Instead, the donor gene has to be incorporated into the chromosome of the recipient microorganism. If the recipient microorganism is infected with only one transducing particle, it will survive and its phenotype may be altered by the integrated donor gene. It is very important to remember if the multiplicity of infection (“MOI”) of transducing particles per recipient microorganism is high, the cell will probably be destroyed, which is typically referred to as “lysis from without.”
The transfer of genetic information from one microorganism to another may have beneficial or undesirable effects. For example, a beneficial transfer of genetic information was disclosed by Chakrabarty, A. M. (1996) Microbial degradation of toxic chemicals: Evolutionary insights and practical considerations, ASM News 62:130. Microorganism-rich soil was introduced into a chemostat which contained a single industrial pollutant as a nutrient. In less than a year, pseudomonads which had acquired all of the enzymes needed to degrade the pollutant were isolated from the soil.
Similarly, genes that exhibit undesirable traits may also be transferred. Examples of such detrimental gene transfer include transfer of genes carrying resistance to antibiotics, and genes that code for production of toxins, such as shiga, diphtheria, and botulism toxins. Outbreaks of toxin-related diseases, such as toxic shock syndrome in 1980, the “flesh-eating streptococci” of 1994, and illnesses caused by E. coli 0157:H7 in undercooked hamburger, have been traced to the transfer of toxin genes by temperate phages. Genes that code for cholera toxin are also reported to have been transmitted by a temperate phage, which created yet another epidemic strain, Vibrio cholerae 0139.
Viruses have been isolated and employed in treating various types of bacterial infections. U.S. Pat. No. 4,375,734, which issued to Kozloff et al. on Mar. 8, 1983 (“Kozloff”), discloses use of a wild-type phage, Erh1, for protecting plants against frost injury caused by an ice nucleation-promoting bacterium, Erwinia herbicola. The treatment of corn plants with Erh 1 reduced the incidence of ice nucleation damage by about 20% to 25%. Kozloff et al. also discloses that Erh1 killed only about 90% of cultured E. herbicola, which suggests that some of the remaining 10% were resistant to wild-type Erh1.
U.S. Pat. No. 4,828,999, which issued to Jackson, one of the present inventors, on May 9, 1989 (“Jackson”), discloses host range, or “h-mutant,” phages which attack phage-resistant strains of various plant bacteria, and methods of treating bacterially infected plants. The h-mutant phages, compositions containing such phages, and methods of treatment that are disclosed in Jackson are, however, limited to phages for plant bacteria and the treatment of plants infected with such bacteria.
Similarly, some measures have been taken to address the problem of bacterial diseases in humans, and to otherwise control and prevent bacterial growth. Patent application Ser. No. 08/222,956 (the “'956 application”), which was published on Oct. 12, 1995 as WO 95/27043, discloses a type of phage therapy whereby mutant phage strains are introduced into a bacterially infected host. The mutant phages, which are thought to be resistant to degradation by the bacterially infected host's defense systems, particularly organs of the reticulo endothelial system, are believed to attack the harmful bacteria with which the host is infected. Thus, phages of the '956 application are believed to act as an in vivo antibacterial agent, and may be used either alone or as an adjunct to antibiotic therapy.
Although phages disclosed in the '956 application are introduced into bacterially infected hosts for the purpose of attacking undesirable bacteria, these phages included not only lytic, but also temperate viruses which are able to transfer pieces of donor bacterial DNA to recipient bacteria. Further, the '956 application lacks any disclosure that phages disclosed therein are able to attack, and thereby prevent or otherwise control the further growth of, phage-resistant bacterial strains.
Shortly after the discovery of phages as lytic agents of bacteria by Twort in 1915 and by d'Herelle in 1917, the investigation of their use for treating bacterial infections, which is typically referred to as phage therapy, began. Various phages are active against bacteria of many diseases in plants and animals, such as mammals. Phages that are active against bacteria which cause human diseases, such as anthrax, bronchitis, diarrhea, scarlet fever, typhus, cholera, diphtheria, gonorrhea, paratyphus, bubonic plague, osteomyelitis, and other bacterially induced diseases, are known. While many in the art were initially convinced of the efficacy of phage therapy, particularly in controlling cholera, many phages were ineffective for in vivo treatment. It was believed that such ineffectiveness was due to the inactivation of phage by the host's immune system when administered parenterally, denaturation by gastric juices when taken orally, and the rapid emergence of phage-resistant bacterial mutants.
With the introduction and use of antibiotics, and their initial effectiveness in controlling bacterial diseases, much of the research for using phages as therapeutic agents ceased. Recently, phage therapy was successfully employed to treat nosocomial infections caused by antibiotic-resistant bacteria and certain opportunistic pathogens, namely, pyogenic infections and septicemias, especially staphylococcal, but also pseudomonads, enterobacteria (E. coli, Klebsiella, Proteus, Providencia, Serratia), injuries (infected wounds and burns, postoperative infections, osteomyelitis), diseases of the skin and subcutaneous tissue (furunculosis, abscesses, acute lymphangitis, decubitus ulcers), urinary infections (chronic cystitis and pyelonephritis), respiratory diseases (sinusitis, mucopurulent bronchitis, pleuritis) and other diseases, for example, infantile diarrhea caused by enteropathogenic E. coli (7,8). In treating bacterial infections, phages may be administered orally in liquids, tablets and capsules, topically by aerosols and direct application, and intravenously. Phage therapy was conducted alone and in combination with antibiotics. Phages were also used as antiseptics, including uses such as disinfecting operating rooms, surgical instruments and lesions on patients, and medical care professionals.
Microorganisms such as bacteria can develop phage-resistant strains, however. Thus, phage therapy (or virus therapy for non-bacterial microorganisms) is somewhat undesirable from the standpoint that virus-resistant strains of a target strain of microorganism may persist in an infected host that is being treated, or in any other treated environment.
Conversely, many beneficial microorganism populations are threatened by viruses that will interfere with the beneficial properties of such microorganisms. Exemplary beneficial processes that are facilitated by microorganisms include industrial fermentation (e.g. in making food products), bioremediation of toxic chemicals, pollutants, and other undesirable substances, leaching of metals from low grade ores, extraction of petroleum and related products from shale, and drug manufacture. The efficiency of many beneficial processes is degraded by the ubiquitous nature of many viruses that will attack the microorganisms that facilitate these processes.
Thus, a need exists for an alternative method of controlling, reducing, or eliminating microorganism populations, which method addresses the ever-increasing emergence of antimicrobial resistance and the virus-resistance of microorganisms. A need also exists for a treatment which selects and destroys undesirable microorganisms while permitting beneficial microorganisms to survive. A need also exists for providing virus-resistant beneficial microorganisms.
BRIEF SUMMARY OF THE INVENTIONAlthough viruses have been used to control populations of microorganisms as previously described, many microorganisms can readily develop resistance to infection by viruses. Moreover, the use of temperate viruses in controlling populations of microorganisms is often ineffective since temperate viruses do not always proliferate in and lyse the infected host microorganisms.
“Wild-type” is defined herein as those viruses isolated from the wild or nature which display the most frequently observed phenotype, or physical characteristic, and is typically referred to as “normal,” in contrast to “mutant.” “Wild-type viruses” exhibit normal host-range virulence. “Wild-type microorganisms” do not resist infection by wild-type viruses specific for the particular target strain of microorganism.
“Host-range mutant viruses,” which are also referred to as “h-mutant viruses,” are defined herein as viruses which exhibit broader than normal host-range virulence. H-mutant viruses infect both wild-type microorganisms and virus-resistant variants of the target strain of microorganisms.
The invention thus includes one or more viruses which do not carry unwanted genes and are specific for one or more target strains of microorganisms. The viruses are lytic viruses which may be employed in processes including the control, reduction, or elimination of populations of a target strain of a microorganism. Preferably, a virus or virus mixture according to the present invention includes one or more h-mutant viruses. A mixture of one or more h-mutant viruses and one or more wild-type viruses is also within the scope of the present invention. Wild-type and h-mutant viruses “recognize” receptors on the surfaces of target strains, including one or more virus-resistant variant thereof, and infect these virus-resistant variants. Since the viruses of the present invention comprise lytic viruses, infected host cells will be lysed by the viruses. Viruses which are able to infect the wild-type of the target strain as well as a variety of virus-resistant variants of the target strain are preferred.
The h-mutant viruses of the present invention may be generated by isolating a wild-type of a target strain of a microorganism and growing this wild-type in the presence of a wild-type virus which is specific for the target strain. Virus-resistant variants of the target strain will grow in the presence of the wild-type virus. The virus-resistant variants of the target strain are isolated and then grown in the presence of wild-type virus in order to generate h-mutant viruses. H-mutant virus-resistant variants of the target strain may then be obtained in a similar manner to the generation of virus-resistant variants of the target strain. These h-mutant virus-resistant variants may then be grown in the presence of h-mutant viruses in order to generate secondary h-mutants which will infect one or more virus-resistant variants of the target strain, imparting these h-mutants with a broader host range than their predecessors.
The invention also includes the virus-resistant and h-mutant virus-resistant variants of the microorganism, which are generated as described previously, and as hereinafter further described.
The viruses of the present invention may then be employed in a method of controlling, reducing, or eliminating populations of target strain microorganisms. The method includes introducing lytic viruses that are substantially devoid of undesirable genes into an environment where an undesirable target strain microorganism is present. As the target strain microorganism is exposed to the viruses, it is infected and eventually lysed. Since h-mutant viruses preferably infect wild-type and virus-resistant variants of the target strain, depending upon the concentration of h-mutant viruses, the preferred use of h-mutant viruses in the inventive method may effectively control, reduce, or eliminate the target strain microorganisms from the environment into which viruses are introduced.
In another aspect of the method of controlling populations of microorganisms includes introducing virus-resistant or h-mutant virus-resistant variants of a microorganism into an environment where the presence of the microorganism is desired. The introduction of such virus-resistant and h-mutant virus-resistant microorganisms is desirable in situations where the microorganism facilitates a beneficial process.
DETAILED DESCRIPTION OF THE INVENTIONThe present invention preferably includes host range-mutant lytic viruses, which are also referred to as h-mutant virulent viruses, or simply as h-mutant viruses, that infect and destroy virus-resistant strains of microorganisms. The present invention may also include wild-type lytic, or virulent, viruses, which are collectively referred to as “viruses” for simplicity. The viruses are preferably substantially free of undesirable genes. The present invention also includes a process for generating h-mutant viruses or mixtures of h-mutant and wild-type viruses that lack undesirable genes, such as genes that impart the virus with the ability to infect multicellular organisms, the ability to transfer undesirable genes to infected host microorganisms, and the ability to convert from a lytic state to a temperate state; a process for reducing, eliminating or otherwise controlling the growth of microorganism populations with h-mutant viruses or mixtures of h-mutant and wild-type viruses; and a process that utilizes h-mutant viruses or mixtures of h-mutant and wild-type viruses to generate virus-resistant and h-mutant virus-resistant strains of microorganisms. The virus-resistant and h-mutant virus-resistant strains of microorganisms that are generated by the inventive process are also within the scope of the present invention.
H-Mutant Viruses
The h-mutant viruses of the present invention are lytic, or virulent, viruses, which infect host microorganisms, utilize the various components of the host microorganisms to replicate and assemble progeny, and destroy the host, target strain microorganisms. Preferably, the h-mutant viruses of the present invention lack undesirable characteristics, including, without limitation, the ability to infect multicellular organisms, the ability to transfer undesirable genes to infected host microorganisms, and the ability to convert from a lytic state to a temperate state.
The viruses include an outer protein coat, or “capsid,” which is capable of “recognizing” a receptor, or receptor site, on the outer surface of a target strain microorganism, including some receptors which have been altered, or “mutated,” to impart the target strain microorganism with resistance to wild-type viruses or resistance to one or more h-mutant viruses. The ability of h-mutant viruses to recognize mutated receptors of the target strain microorganism enables h-mutant viruses to infect virus-resistant variations of the target strain microorganism.
Due to their ability to “recognize” receptors on the target strain microorganism, viruses of the present invention specifically infect the target strain, and do not infect other, non-targeted strains of a same species of microorganism, other non-targeted microorganisms, or other non-targeted cells. Thus, the inventive viruses are not as likely to inhibit the activity of beneficial microorganisms as antimicrobial drugs, which lack the specificity of viruses for a target microorganism.
When employed in a treatment method according to the present invention, as more fully described below, the inventive viruses proliferate as they destroy target strain microorganisms, reducing the need for repeated dosing in treatment which include the administration of viruses. In contrast, antimicrobial therapies require repeated doses since antimicrobial concentrations decrease during treatment.
After target strain microorganism populations are reduced or eliminated such that target strains are no longer present for the viruses to infect, the viruses become inactive, and will eventually be degraded. Following their degradation, the various components of the viruses may be utilized by other organisms as nutrients.
The process of generating h-mutant viruses of the present invention includes isolating virus-resistant microorganisms, and growing the virus-resistant microorganisms in the presence of wild-type viruses in order to generate and isolate h-mutant viruses.
A target strain of a microorganism is isolated by techniques which are known in the art. The target strain may then be identified or otherwise analyzed by known processes. Virus-resistant members of the target strain are then isolated by culturing the target strain in a medium that facilitates growth, or proliferation, of the target strain. Preferably, target strain microorganisms are grown on a sterilized, semi-solid medium, such as an agar. The target strain is grown in the presence of a wild-type virus that is capable of infecting the former. The concentration of the wild-type virus depends upon the desired MOI. Preferably, the relative concentrations of target strain microorganisms to wild-type viruses are about one-to-one, for an MOI of about one. Due to their ability to resist infection by the wild-type virus or otherwise survive a virus infection, some of the target strain microorganisms will grow in the presence of the wild-type virus. Such microorganisms are referred to as wild-type virus-resistant microorganisms, and will grow on the agar as “colonies.” Thus, wild-type virus-resistant microorganisms may be isolated in the form of colonies by culturing target strain microorganisms in the presence of a wild-type virus that will infect, or is specific for, the target strain.
H-mutant viruses may then be generated and isolated by transferring a sample of the wild-type virus-resistant microorganism from a “colony” on agar, to a liquid or semi-solid growth medium that includes a high concentration of wild-type viruses. Thus, the MOI is preferably greater than one. The concentration of wild-type virus-resistant microorganisms will preferably facilitate growth of a confluent layer, which is also typically referred to as a “lawn,” in a semi-solid growth medium. Although many of the viruses will have no effect on wild-type virus-resistant microorganisms, some mutants will infect and lyse the virus resistant microorganisms. These viruses are the h-mutants, and are isolated within substantially transparent areas of the lawn, which are typically referred to as “plaques.”
The processes of isolating virus-resistant target strain microorganisms and generating, selecting, and isolating h-mutant viruses may be repeated in order to increase the range of virus-resistant microorganisms of a target strain that the h-mutant viruses will infect. Such a process may be performed by growing virus-resistant microorganisms in the presence of h-mutant viruses rather than wild-type viruses. Alternatively, various h-mutants with different host ranges may be generated and isolated by conducting these processes several different times.
Screening for Undesirable Genes
After the viruses have been isolated, the presence or absence of undesirable genes (e.g., genes for virulence factors, toxins, and antibiotic resistance) may be determined by comparison techniques that are known to those in the art, such as conventional agarose gel electrophoresis, pulsed-field gel electrophoresis, or use of nucleic acid hybridization probes. Such techniques include hybridization of any undesirable genes with complementary polymerase chain reaction (PCR)-amplified strands of DNA which include known undesirable genes (e.g., genes that impart the virus with the ability to infect multicellular organisms, the ability to transfer undesirable genes to infected host microorganisms, and the ability to convert from a lytic state to a temperate state). Hybrids may then be detected by known techniques, such as radio-assays.
As an example of such comparative screening, since the viruses of the present invention include only lytic viruses, temperate viruses will be screened by comparing the genes of these viruses to known genes that impart viruses with temperate characteristics. Temperate h-mutant viruses may then be excluded from virus mixtures of the present invention and from use in treatment methods of the present invention.
Temperate wild-type viruses may be screened and excluded in similar fashion from viruses and virus mixtures of the present invention. As previously identified, temperate viruses may transfer undesirable characteristics to a host target strain of a microorganism. Moreover, temperate viruses do not readily destroy the target strain microorganism. Thus, the use of temperate viruses in controlling, reducing or eliminating microorganism populations is not as desirable as the use of lytic viruses for these purposes.
The virus-resistant microorganisms that are generated in the foregoing process may be screened for other undesirable characteristics, such as antibiotic resistance, in a similar fashion.
Following screening for undesirable genes, viruses of the present invention which lack undesirable characteristics may then be proliferated and utilized in virus mixtures of the present invention, and in accordance with methods of the present invention.
Proliferating H-Mutant and Wild-Type Viruses
A process for proliferating the viruses of the present invention includes growing large quantities of the target strain microorganisms, including one or more virus-resistant variations thereof. The desired virus or viruses, such as one or more h-mutant variations or one or more wild-type variations of each desired virus, are then introduced into the presence of the target strain of microorganism at a desired MOI. An exemplary growth chamber comprises a bioreactor, into which nutrients may be continually introduced and from which microorganisms and/or viruses may be continually removed. The virus or viruses may also be proliferated in sterilized liquid growth medium in large flasks, or otherwise as known in the art.
Concentrating and Storage of H-Mutant Viruses, Wild-Type Viruses and Virus-Resistant Microorganisms
The viruses or virus mixtures may be concentrated by methods that are known in the art, such as chemical precipitation and ultrafiltration. Another method of concentrating h-mutant viruses includes isolating and concentrating infected, non-lysed target strain host microorganisms, which are referred to as “carriers.” The use of carriers is desirable because a single carrier will eventually be lysed by viruses growing therein, and during lysis release a large number of viruses. In addition, it is easier to concentrate carrier microorganisms by conventional methods, such as centrifugation, than it is to concentrate viruses by many conventional methods. Preferably, carriers are avirulent variations of the target strain microorganism, so that little or no risk exists of introducing a virulent target strain into a virus treatment site.
Viruses and carrier microorganisms of viruses may be stored as known in the art (e.g., by refrigeration at about 4° C., freezing or lyophilization processes) prior to use in the process of the invention. Alternatively, the viruses and carriers including the viruses of the present invention may be employed in accordance with a process of the present invention and/or concentration thereof.
The virus-resistant microorganisms of the present invention may be concentrated and/or stored in a manner that is similar to the processes for concentrating and storing the viruses.
Stored or unstored viruses and virus mixtures, and virus-resistant microorganisms may then be utilized in accordance with the microorganism population control processes of the present invention, examples of which are set forth in detail below.
Methods of Microorganism Population Control
A. Use of Virulent Viruses to Control Microorganism Populations
A first embodiment of the inventive method includes employing viruses or virus mixtures of the present invention to control populations of target strain microorganisms. This first embodiment includes introducing the inventive viruses into a treatment site in order to lyse target strain microorganisms.
Foods or food products, such as raw meat and poultry, are exemplary treatment sites. The undesirable microorganisms that are typically present in raw meat and poultry treatment sites include, without limitation, the genera Salmonella, Campylobacter, and Escherichia (e.g., E. coli.) An exemplary target strain of E. coli is the infamous strain designated O157:H7. Introducing viruses that will infect and lyse undesirable microorganisms into raw meat and poultry treatment sites includes, but is not limited to, introducing the viruses into food and water of live animals, applying viruses to the living spaces of such animals, applying and otherwise introducing viruses to animal carcasses, meat, and surfaces in meat packing plants, storage and transportation containers, markets, and homes. Applying viruses to meat and poultry reduces or eliminates populations of undesirable microorganisms, which are thought to reduce or eliminate the incidences of disease and food spoilage caused by such microorganisms. Similarly, vegetation and other food products may be treated with the inventive viruses to control an increase in populations of undesirable microorganisms thereon.
Another exemplary treatment site into which the viruses may be introduced includes living animals (such as mammals, e.g., humans), or “subjects.” The inventive viruses may be employed in the prevention (i.e., prophylaxis) or treatment (i.e., therapy) of diseases that are caused by a target strain of microorganism. Treatment and prophylaxis both include introducing the viruses into the subject by a known method. The viruses are preferably orally administered by a known enteral dosage form. The viruses may be topically administered in various known forms, such as aerosols, liquids, creams, lotions, soaps, powders, and salves. The viruses of the present invention may also be administered in accordance with processes that are known in the art, such as those disclosed in WO95/27043, the disclosure of which is hereby incorporated by reference in its entirety.
While being used in therapy of microbial infections, the viruses of the present invention may be introduced alone or in combination with one or more antibiotics, which are also referred to herein as “antimicrobial agents” or “bacteriocins.” The term “bacteriocin” was coined for antibacterial agents that are synthesized by bacteria and require specific receptors on the target microorganism. Various antibiotics and other antimicrobial agents are known in the art (see, e.g., Handbook of Antimicrobial Therapy, The Medical Letter (1984), the disclosure of which is hereby incorporated by reference in its entirety). The viruses of the present invention are especially useful for preventing infection by and treating antibiotic-resistant strains of bacteria.
The inventive viruses may also be employed to disinfect a target strain of a microorganism from an object. In disinfection, a composition including the viruses is applied to the object and the viruses lytically infect the target strain. Exemplary objects which may be disinfected in this manner include, but are not limited to, infected areas of healthcare facilities, operating rooms and treatment rooms in healthcare facilities, and equipment that is used by healthcare professionals.
Plant diseases that are caused by microorganisms may also be treated in accordance with this first embodiment of the method. The viruses that will infect target strains of plant disease-causing or harmful, e.g., ice-nucleation, microorganisms may be applied to infected or contaminated plants, seedlings, seeds, or soil or other matter which supports the foregoing by spraying or introduction into the plant's water supply. As an example of the treatment of plants, legume seed may be treated with a virus or virus mixture that will infect and lyse undesirable strains of rhizobia that are present in soil, and that will not infect beneficial strains of rhizobia. The virus, which preferably includes an h-mutant virus, will reduce or eliminate undesirable rhizobia strains, while the desirable rhizobia strains will benefit the plant as the plant grows.
The first embodiment of the method of the present invention may also be employed to control microorganism populations that are detrimental to the environment. As an example, the inventive viruses may be employed to reduce populations of microorganisms which deplete oxygen from bodies of water, and permit an increase of oxygen levels in these waters. Nutrients from sewage and fertilizer that are introduced into pond water, river water, or sea water can create algal blooms. The algae eventually die and are then decomposed by various microorganisms, which proliferate and continue decomposing the dead algae. During proliferation of such microorganisms, oxygen is depleted from the water, which inhibits growth of most other organisms therein. The introduction of viruses that infect and lyse specific algae species which may form blooms at a particular site would control the populations of such algae microorganisms and, therefore, the formation of algal blooms, thereby permitting oxygen levels in the water to increase, and facilitating reintroduction of other types of life into these previously oxygen-depleted treatment sites.
As another example of this method, viruses of the present invention may be employed to reduce the occurrence of “acid mine drainage,” which is an environmental problem associated with coal mining. Thiobacillus ferrooxidans, a bacterial species that oxidizes iron sulfide, is a major cause of acid mine drainage. As acidic mine drainage pollutes the water in nearby lakes, rivers and streams, the quality of these waters deteriorates. Acid and metals that are dissolved in acid mine drainages are toxic to aquatic life and render the water unsafe for consumption and human activity. The introduction of viruses that will infect and lyse T. ferrooxidans would therefore be useful in reducing or eliminating this type of bacteria from coal mines, and reduce the occurrence of acid mine drainage.
The control, reduction, and elimination of pathogenic agents is another example of this method of the invention. Exemplary pathogenic agents include, but are not limited to, various types of bacterial (e.g., Bacillus anthracis, Salmonella typhi, Vibrio cholerae, Yersina pestis, Xanthomonas albilineans, A. campestris pv. citri, and X. campestris pv. oryzae) rickettsial (e.g., Coxiella burnetii and Rickettsia prowazeki), and fungal organisms. The dissemination of inventive viruses that infect and lyse such pathogenic agents into treatment sites where such pathogenic agents are present would control, reduce, and potentially eliminate populations of such pathogenic agents.
The first embodiment of the process of the present invention may also be employed to selectively control, reduce or eliminate populations of undesirable microorganisms that inhibit the ability of beneficial microorganisms to perform beneficial processes. As those of skill in the art are aware, several types of microorganisms, which are referred to as beneficial microorganisms or beneficial agents, benefit their hosts. The ability of a beneficial microorganism to benefit its host may, however, be interfered with by an undesirable microorganism. A preferred virus or virus mixture that would be useful in treating a target strain of undesirable microorganisms in accordance with the first embodiment of the process would infect and lyse the target strain, and would not infect or lyse any of the beneficial microorganisms.
Similarly, the bioremediation of toxic chemicals by beneficial microorganisms may be interfered with by undesirable target strains of microorganisms. For example, pseudomonads, which produce a variety of antimicrobial substances, may be present in a mixture of bioremediating microorganisms. The presence of antimicrobial substances in such mixtures, however, is undesirable since it may destroy the ability of many of the microorganisms to bioremediate toxic chemicals. Accordingly, the viruses of the present invention would be useful in the present method for controlling the number of undesirable antimicrobial-producing microorganisms in such a mixture.
Other microorganisms are beneficial for some purposes, but may be detrimental in other regards. One such microorganism, P. aeruginosa occurs naturally in soil, and is useful in the bioremediation of many environmental pollutants. P. aeruginosa, however, also causes various diseases in plants and animals. Thus, this method of the invention would be useful for controlling, reducing, or eliminating the population of P. aeruginosa after that microorganism has performed its beneficial task.
Populations of genetically engineered microorganisms may be controlled, reduced, or eliminated in a similar manner. Since many people fear that the use of genetically engineered microorganisms for beneficial purposes may also have adverse effects, the elimination of such genetically engineered microorganisms may be desirable. Thus, viruses that infect and lyse a target strain of genetically engineered microorganism may be utilized in accordance with this embodiment of the invention to control, reduce, or eliminate populations of genetically engineered target strain microorganisms from a treatment site following their use for beneficial purposes.
B. Methods of Using Virus-Resistant Microorganisms to Control Microorganism Populations
As described previously, many beneficial microorganisms, or “beneficial agents,” perform beneficial processes. Such microorganisms, however, are susceptible to being infected and lysed by viruses. Accordingly, a second embodiment of the method of the present invention includes the use of virus-resistant strains of beneficial microorganisms in beneficial processes.
Virus-resistant microorganisms are generated, as previous described, by growing a target strain of microorganism in the presence of wild-type and/or h-mutant viruses that will infect and lyse the target strain microorganism. Virus-resistant microorganisms may then be isolated as discussed previously, and proliferated in a growth medium under otherwise substantially sterile and preferably controlled conditions.
As an example of the use of the second embodiment of the process, virus-resistant Pantoea ananus, which is parasitic for the rust fungi, Puccinia spp., is useful for controlling the growth of rust fungus on wheat. Phages which attack P. ananus are, however, also present in proximity to the rust fungus, and have a detrimental effect on the ability of P. ananus to control rust fungus. Accordingly, the application of virus-resistant strains of P. ananus to wheat would be useful in controlling the growth of rust fungus on the wheat. Similarly, the application of virus-resistant P. ananus to rust fungus-infected wheat would be useful for preventing the spread of rust fungus to other wheat plants, and for treating the rust fungus-infected wheat plants.
Similarly, some bacteria, such as Serratia entomophilia, control the proliferation and spread of insect populations, such as New Zealand grass grub, or Costelytra zealandica, and may be applied to treat plants or to prevent the spread of such insects to other plants. Other virus-resistant bacteria used for biological pest control, such as Enterobacter aerogenes for locusts, are also useful in the second embodiment of the process of the present invention.
Other beneficial microorganisms are useful for performing processes which include, without limitation, leaching in order to oxidize the sulfide of sulfide-rich minerals to sulfuric acid so as to liberate and concentrate valuable minerals, such as copper and uranium, from low-grade ores (i.e., T. ferrooxidans and Acidiphilium spp.); releasing petroleum and related substances from bituminous shale (e.g., Rhodococcus spp., Sulfobus spp., and/or Thiobacillus spp.); acidifying sulfur or other matter to acidify alkaline soils that have been selected for agricultural uses (e.g., Rhodococcus spp., Suljobus spp., and/or Thiobacillus spp.); decomposing tires and other rubber products for recycling (e.g., Rhodococcus spp., Sulfobus spp., and/or Thiobacillus spp.); bioremediation of hazardous chemicals and pollutants (e.g., Rhodococcus spp., Sulfobus spp., and/or Thiobacillus spp.); treatment of wastewater discharges and sludges in which other microorganisms produce foul-smelling odors (e.g., from dairy and hog farms, kennels, farms, etc.); and in industrial fermentation processes (e.g., lactic acid bacteria for the production of cheese). The use of virus-resistant microorganisms in such processes in accordance with the second embodiment of the process of the present invention reduces the likelihood that the beneficial microorganisms will be infected or lysed by viruses specific therefor.
Although the invention has been described with regard to certain preferred embodiments, the scope of the invention is to be defined by the appended claims and their legal equivalents.
Claims
1. A composition for controlling a population of a beneficial microorganism, comprising a virus-resistant variation of the beneficial microorganism.
2. The composition of claim 1, wherein the virus-resistant variation comprises resistance to a wild-type of a virus specific for the beneficial microorganism.
3. The composition of claim 1, wherein the virus-resistant variation comprises resistance to an h-mutant virus specific for the beneficial microorganism.
4. The composition of claim 1, further comprising:
- an h-mutant virus specific for an undesirable microorganism.
5. The composition of claim 1, wherein the beneficial microorganism comprises at least one of Pantoea annanus, Serratia entomophilia, Enterobacter aerogenes, T. ferroxidans, a member of the genus Acidiphilium, a member of the genus Rhodococcus, a member of the genus Sulfobus, and a member of the genus Thiobacillus.
6. A method of controlling a population of a beneficial microorganism, comprising introducing a virus-resistant variation of the beneficial microorganism into a treatment site.
7. The method according to claim 6, wherein introducing comprises exposing a toxic chemical or other pollutant to the virus-resistant variation of the beneficial microorganism.
8. The method according to claim 6, wherein introducing comprises introducing at least one of Pantoea ananus, Serratia entomophilia, Enterobacter aerogenes, T. ferroxidans, a member of the genus Acidiphilium, a member of the genus Rhodococcus, a member of the genus Sulfobus, and a member of the genus Thiobacillus into the treatment site.
9. The method according to claim 6, wherein introducing is effected to control growth of fungi.
10. The method according to claim 6, wherein introducing is effected to control the proliferation or spread of an insect population.
11. The method according to claim 10, wherein introducing is effected to control the proliferation or spread of insect populations as exemplified by New Zealand grass grub and locusts.
12. The method according to claim 10, wherein introducing includes applying the virus-resistant variation of the beneficial microorganism to a plant.
13. The method according to claim 6, wherein introducing is effected to oxidize sulfide to sulfuric acid.
14. The method according to claim 6, wherein introducing is effected to release petroleum and petroleum-related substances from bituminous shale.
15. The method according to claim 6, wherein introducing is effected to acidify sulfur.
16. The method according to claim 6, wherein introducing effects at least one of acidifying alkaline soil, decomposing rubber products, bioremediating hazardous chemicals or pollutants, treating sewage or wastewater, treating odors or sources of odors, fermentation processes.
17. A method of generating a virus-resistant variant of a microorganism, comprising:
- isolating an h-mutant virus by exposing a wild-type microorganism to a virus specific for the wild-type microorganism;
- isolating a virus-resistant variant of the microorganism by exposing the wild-type microorganism to the h-mutant virus;
- isolating at least one second h-mutant virus by exposing the virus-resistant variant of the microorganism to the at least one h-mutant virus; and
- isolating at least one second virus-resistant variant of the microorganism by exposing at least one of the wild-type microorganism and at least one type of virus-resistant variant of the microorganism to the at least one second h-mutant virus.
18. The method according to claim 17, wherein at least one of isolating the virus-resistant variant and isolating the at least one second virus-resistant variant comprises growing at least one of the wild-type microorganism and the virus-resistant variant in the presence of an h-mutant virus specific for the microorganism.
19. The method according to claim 18, wherein isolating the at least one second virus-resistant variant comprises isolating at least one second virus-resistant variant having resistance to infection by a plurality of h-mutant viruses.
20. A composition for controlling populations on food products of a microorganism that is pathogenic to a mammal, comprising an h-mutant virus specific for and capable of infecting a virus-resistant variation of a target strain of the microorganism.
21. The composition of claim 20, wherein the microorganism are enteric pathogens, as exemplified by Salmonella, Campylobacter, or E. coli.
22. The composition of claim 20, wherein the target strain comprises E. coli 0157:H7.
Type: Application
Filed: Jul 31, 2007
Publication Date: Dec 20, 2007
Applicant: OMNILYTICS INCORPORATED (Salt Lake City, UT)
Inventors: Lee Jackson (Layton, UT), Rex Spendlove (Millville, UT)
Application Number: 11/831,813
International Classification: C12N 1/20 (20060101); A61K 35/00 (20060101); C12N 7/00 (20060101);