Intestinal Microflora and Antibiotic Resistance: Difference between revisions

Basic Attributes of Gut Microflora

The microflora of the human gastrointestinal (GI) tract is so extensive and integral to the proper functioning of the digestive system that it has been characterized as an additional organ of the human body (1). It is estimated that the microfloral community consists of 500 -1000 distinct species of bacteria in a single person; collectively, their population is 10 times the number of their host’s body cells (2). The intestine provides a suitable niche for many species of bacteria, as it remains at a stable temperature and is replete with bioavailable carbon, nitrogen, and solute sources of nutrition (7). The suite of microbes is acquired primarily during infancy, since the GI tract of a fetus is sterile during development. Bacteria are initially transferred to the infant during the delivery process, then continually from the immediate environment and from contact with its mother and other adults. Escherichia and Streptococcus are the first to colonize the GI tract, typically followed by bifidobacteria, staphylococci, lactobacilli, micrococci, and propionibacteria. As the infant matures, it is continually exposed to bacteria, principally by the digestion of food, and the makeup of its intestinal microbiome changes dramatically (2, 5). The dynamic nature of the microfloral community entails shifting of community species composition over time and variation in composition among individuals. However, the predominant taxa of bacteria in the gut are fairly consistent. Firmicutes and Bacteroidetes are the most prevalent phyla by far; populations of Proteobacteria, Actinobacteria, Fusobacteria, and Verrucobacteria are frequently established as well (2, 6). The functions performed by gut bacterial include regulation of intestine epithelial development, contributions to the innate immune system, improved absorption of nutrients from food, and maintenance of mucosol homeostasis and repair (1, 2, 3). These functions are all highly relevant to medicine, as a deeper understanding of how bacteria influence these systems will yield more sophisticated solutions to conditions affecting the body. An important factor to the effective functioning of the human microbiome is the movement of genetic material. Genes are exchanged both among bacteria species, via lateral gene transfer, and among bacteria and their host. The presence of 233 documented human proteins that have homologues only in bacteria hints at the extent to which human development and function has historically been strongly influenced by bacteria (2). The transfer of genetic material among bacterial species affects human hosts in more immediate and clinically relevant ways, including, notably, influencing response to antibiotics (4).

Studying Human Microflora

Characterizing the diversity and function of the microbiome is notoriously difficult. Most gut bacteria cannot be cultured due to their very particular nutritional requirements and the obligate anaerobic nature of bacteria in the distal regions of the gut (2); for this reason, previous studies that may be significantly biased in their analyses. The use of phenotypic characteristics to classify bacteria (which was utilized until only recently) also leads to an incomplete and oversimplified resolution of species. More modern techniques to evaluate bacterial communities and their evolutionary lineages involve whole-genome sequencing and a strong emphasis on rRNA (1, 4, 6). The ubiquity of 16S strands in prokaryotic lineages makes them a natural choice for elucidating diversity and evolutionary histories of gut microbiota. rRNA 16S, which is located on the 30S subunit of bacterial ribosomes, contains regions that are highly conserved, variable, and highly variable; the conserved “signature” sequences indicate evolutionary history of a particular taxonomic group with precision. A number of techniques have been employed to sequence 16S rRNA, including sequencing of cloned amplicons, direct sequencing, TRFLP, dot-blot hybridization, shotgun sequencing, and quantitative PCR (or real-time PCR) (9). Cloned amplicon sequencing is common, due to its moderately high resolution and ability to clone the full length of the 16S strand. The 16S sequences are treated with primers that bind to these conserved regions and amplified with standard PCR techniques, so that the resulting clones may be identified and catalogued (8). Though all of these sequencing techniques are powerful, they are inherently limited by the method of sampling. Fecal samples are commonly used to assess bacterial composition, but do not accurately represent the flora community. Mucosal tissue samples directly from the intestine are preferable, but are more invasive and expensive to obtain (1). Studies utilizing these molecular techniques consistently identify great numbers of novel species (with benchmark similarity values of 95% or greater), indicating efforts to characterize the gut flora have been insufficient. It is estimated in review literature that only 19% of the adult flora has been identified, and only 8% of the adult flora (9). Due to the density of the microbial system and the complex interactions among species and between bacteria and the host, many researchers consider the gut to be its own ecosystem. This perspective has influenced the analysis of the data output from these sequencing projects: many ecological measures of richness, abundance, and growth are used to predict bacterial dynamics (1, 17).

The Gut Microbiome and the Defenses of the Intestine

Since the intestine is such an attractive habitat for microbes, it must employ many types of defenses to protect the body from invasion of pathogen microbes. Many of these defense mechanisms are intricately related to a normal population of gut microflora. Microflora inhabit the mucosal layer of the intestine, which is a gel-like substance secreted by goblet cells onto the lumen-facing surface. Compared in function to a biofilm, this mucus layer can either trap or prevent the adhesion of potentially pathogenic organisms (depending on the pathogen's physiology and adaptive ability). The invasion of exogenous bacteria, both Gram-positive and Gram-negative, stimulates the secretion of mucus, strengthening this form of defense (16). Indigenous bacteria must be specially adapted to dwell in this layer. The intestine constantly “checks on” the population of microflora using toll-like receptors. Two pathways have been identified as ways TLRs protect microflora: either TLRs constitutively express protective factors in response to concentration of microbial products, or protection factors are produced in response to physical or chemical damage to the epithelium (15). Evidence that intestinal microbiota have a distinct and crucial effect on the stimulation of mucus production is presented in a study that compared goblet cells of germ-free mice to conventional mice. The size of the goblet cells were significantly augmented in conventional specimens, but more importantly the mucosal layer was up to two times as thick. The structural components of gut flora bacteria that trigger this thickening effect remain unknown (17). Resistance to antibiotics is a necessary attribute of bacterial populations dwelling in the human gut. The epithelium of the intestine expresses a variety of antimicrobial agents as a first-line defense of the immune system. These peptides are either expressed constitutively or induced by inflammatory mediators (10). Thus, in order to flourish in the human gut commensal bacteria must be recognized by toll-like receptors and other mediators as well as be resistant to these comparatively non-specific antimicrobial agents. Pathogenic bacteria are recognized by their structural attributes by means of complex pathways, then are destroyed by inflammation or the antimicrobial peptides (11). The ability to distinguish between commensal bacteria and potentially pathogenic bacteria is crucial to the continued function of the microflora “organ” as well as the immune system as a whole.

Effects of the Use of Antibiotics on Microbe Populations

The advent of broad-spectrum antibiotics has upset the delicate balance between commensal bacteria and the antimicrobial substances produced by the intestine. Antibiotics can be ingested either deliberately (in prescribed medications) or accidently (in meat from animals treated extensively with antibiotics in industrial farm settings). The prescription of antibiotics as the “first line” of defense for a wide range of symptoms that may not actually be bacterial in origin may lead to serious implications for gut flora. Since broad-spectrum antibiotics are generally manufactured to be non-specific, vast numbers of bacteria in the gut are destroyed following administration of the drug (12). The immediate effects of losing microflora function include, predictably, a decreased ability to metabolize certain carbohydrate and lipid structures that make up a significant portion of the diet (13), regulation of fat storage (14), and loss of antimicrobial structures expressed by many microflora species (2). Individuals vary in their response to antibiotic usage due to the variability of their bacterial colonies (further obscuring studies attempting to determine makeup of the gut microbiome); also, some taxa seem to be more vulnerable to antibiotic damage than others. Gut bacteria taxa that seem to suffer disproportionally include Firmicutes, Bifidobacteria, Collinsella, and Ruminococcus; Proteobacteria appears to be more resistant and shows transient dominance (4, 17). These results suggest that the spread of newly dominant species to utilize newly available nutrients may reduce the ability of normally distributed flora to regenerate. In addition, multiple treatment episodes for recurrent infections or, ironically, antibiotic-resistant pathogens may also influence the ability of gut flora to return to their pre-drug status.

The Gut as a Reservoir for Antibiotic Resistance

A regimen of antibiotic drugs introduces an artificial selection gradient in the human body for antibody resistance in microflora populations. Since antibiotic resistance genes tend to be encoded on transposable elements such as plasmids, they are readily transferred among populations via lateral gene transfer. The bacteria that receive the plasmids conferring resistance are at a distinct evolutionary advantage, regardless of other benefits they provide the host. Several studies have concluded that ermB and tetQ, which provide resistance to erythromycin and tetracycline, have increased substantially both in occurrence in the gut and the number of species in which they are present. This emphasis on resistance as a fitness factor represents a shift from historical means of keeping bacterial populations in balance. The “cocktail” application of several antibiotics at once to treat conditions such as stomach ulcers (caused by pathogenic bacteria Helicobacter pylori) may exacerbate the selection gradient as well.

Sommer, et al. (2009) studied fecal samples to determine the abundance and distribution of antibiotic resistance factors in microflora. They extracted DNA directly from bacteria from the guts of people who had not been treated with antibiotics for a year, then inserted these sequences into E. coli via expression vectors. The bacteria were cultured and divided onto antibiotic-laden plates, such that each group was subjected to one of thirteen antibiotics. The researchers sequenced those bacteria that contained resistance factors to all thirteen drugs. In all, 95 new resistance inserts were identified. Phylogenetic analysis revealed the most likely origin of antibiotic resistance factors to be Bacteroides and Firmicutes; this is unsurprising considering their dominance in the gut. Of principle interest to this study was how closely related the inserts were to previous entries in GenBank, since the genetic distance between sequences might indicate rate of transfer (assuming a moderately regular rate of mutation). The average similarity factors extracted from human flora and the closest known gene was 69.5% on the nucleotide level, and 65.3% on the amino acid level. Only 22% had >90% similarity to benchmark factors. When they narrowed their perspective and compared resistance sequences of intestinal flora and pathogenic bacteria, they found that nearly half of the factors were identical in sequence to human pathogen genes. Though a direct means of transmission of genetic material from pathogens to human floral cells has not yet been demonstrated, these results have important implications for the human immune system and the effectiveness of antibiotics (4). If pathogens that invade the body transfer plasmids containing resistance factors to floral cells, even if they are destroyed by the immune systems the factor will remain. This may be beneficial to conserving and regenerating flora after being treated with an antibiotic regimen, but transfer occurs in both directions. If genes conferring resistance are transferred to pathogenic species, different cocktails of antibiotics at higher concentrations will be prescribed to fight off the infection, damaging the flora in novel ways.

The data of Sommer, et al. are supported and expanded upon by the recent work of Jakobsson, et al., who studied antibiotic resistance in human microflora in the context of time. This team utilized TRFLP methods to “fingerprint” floral DNA and determine short- and long-term changes in species composition over time. They found the community composition shifts radically after exposure to clarithromycin and metronidazole (another common combination for H. pylori), favoring some taxa over others. Intriguingly, their results indicated that at after four full years since treatment, the original bacterial composition of the gut was not replenished. Of equal importance is the persistence of ermB, the resistance factor to erythromycin. The factor had clearly remained and spread among multiple populations; the authors propose that Enterococci survived the antibiotics and distributed the factor by both asexual reproduction and lateral transfer (18).

Conclusions

The incredible diversity and richness of bacteria in the human gut is invaluable to our survival and, arguably, success as a species. Without the significant benefits to digestion and immune function conferred by bacteria, humans would be markedly less efficient and far more vulnerable to uncontrolled growth of pathogenic bacteria. Though the means to assess the specific types of bacteria and the benefits each population contributes is somewhat lacking, research has indubitably illustrated the significance of bacteria and the potentially harmful long-term effects of antibiotic drugs on microflora. The persistence of resistance in pathogenic bacteria is devastating in a hospital setting; the relatively recent phenomenon of gut bacteria acting as a source for resistance factors could have extremely harmful repercussions. Hopefully, future studies adding to the library of floral species and providing evidence for the destructive influence of over-prescribing antibiotics will convince practitioners to use antibiotics more judiciously.

Sources Cited

1) Eckburg, Paul B. et al. 2005. Diversity of the human intestinal microbial flora. Science 308: 1635-1638.

2) Sears, Cynthia L. 2005. A dynamic partnership: celebrating our gut flora. Science 11(5): 247-251.

3) Tsai, Franklin and Walter J. Coyle. 2009. The microbiome and obesity: Is obesity linked to our gut flora? Current Gastroenterology Reports 11(4): 307-314.

4) Sommer, O.A. Morten, et al. 2009. Functional characterization of the antibiotic resistance reservoir in the human microflora. Science 325(5944): 1128-1131.

5) Mackie, Roderick I. et al. 1999. Development microbial ecology of the neonatal gastrointestinal tract. American Journal of Clinical Nutrition 69(5): 1035-1045.

6) Limdi, J.K., et al. Do probiotics have a therapeutic role in gastroenterology? World Journal of Gastroenterology 12(34): 5447-5457.

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