The use of antibiotics on Wolbachia as treatment for filarial diseases: Difference between revisions

Wolbachia is an endosymbiont that lives in many insects and arthropods. It also lives within Brugia malayi, a filarial nematode that can cause lymphatic filariasis, and Onchocerca volvulus, a different filarial nematode that causes onchocerciasis. These neglected tropical diseases are not life threatening, but greatly affect the quality of life for those infected. The diseases are mainly found in tropical climate areas and predominantly found in sub-Saharan Africa. Due to the symbiotic relationship that makes these nematodes' and Wolbachia's processes so specialized and heavily dependent on each other for survival, treatment of Wolbachia with antibiotics is a possible target for antifilarial activities. Thus, recent research looks for new modes of action for novel antibiotics to treat filarial caused diseases to possibly prevent Wolbachia from reaching antibiotic resistance. This field is a rapidly growing research area with many more discoveries to be made and questions to answer.

Transmission electron micrograph of Wolbachia within an insect cell.[1]

Symbiotic Relationship

Past research has shown that the removal of Wolbachia from the host filarial nematodes causes antifilarial effects.¹ To understand why this event occurs, the evolution of the symbiotic relationship between host and endosymbiont must be understood. This knowledge could lead to new antibiotic treatments as the mechanisms behind the proliferation and transmission of Wolbachia through the life cycle of the host can lead to novel targets for antibiotics.

Localization of Wolbachia

Wolbachia is found in stages of larval development in the hypodermal cells of the lateral cords as well as in the embryos of female filarial nematodes. ² Past studies dating back to the late 1990's and early 2000's have shown that Wolbachia is transmitted by female Drosophila melanogaster to offspring by localizing in the posterior female host oocytes, thus increasing its chance to be incorporated into the germline and be passed off to the offspring. More recent studies on Drosophila have determined the mechanism to be related to the bacteria’s ability to use Drosophila microtubules, kinesin and dynein in insects to properly segregate to the maternal hosts' posterior germline pole plasma area during oogenesis. ^{3 4}

Figure 1. (A) Proportion of A-P polarity defects in dividing two-cell B. malayi embryos in presence (WT) or absence of Wolbachia (Wb(-)). Class I, normal, asynchronous division patterns. Class II, abnormal synchronous divisions and P1 spindle rotation failure. Class III, abnormal synchronous divisions and AB spindle rotation. (B) Wild-type and (C) Wb(-) embryos, stained for DNA (red) and α-tubulin (green). Scale bar = 5 µm.. ⁵

Wolbachia uses a similar mechanism in both Drosophila and filarial nematodes. Wolbachia localizes to maternal centromeres during division. It is also found near the microtubules, which could be interpreted as a possible interaction between Wolbachia and the microtubules. ² A dynein-based mechanism is used to Wolbachia make localize to the posterior of the cell.

Removal of Wolbachia from the filarial nematode host leads to large scale occurrences of apoptosis in the adult germline, and in the somatic cells in certain stages of nematode development leading up to the adult stage.⁵ The apoptosis in the uterine area results in sterilization of the adult female worms, as the embryos in uterus undergo apoptosis. This considerably reduces the adult worms' ability to spread and cause filarial diseases. Microfilaria are able to remain motile and viable, but are limited in their ability to develop past the L4 larvae stage and thus be able to reach a reproductive age and help the proliferation of more nematodes, an effect caused by apoptosis from the removal of Wolbachia through antibiotics.⁵ It was also found that Wolbachia uses A-P polarity to localize to the posterior of the egg and thus the beginning of the germline. As seen in Figure 1, Wolbachia is needed for the proper A-P polarity in the filarial nematodes, showing the necessity of Wolbachia to localize in the filarial nematodes' oocytes for normal embryo development. ² Both of these findings could explain how the removal of Wolbachia leads to sterilization of female filarial nematodes.

Pathogenesis

Wolbachia can create a proinflammatory response with interaction with specific immunne cells. ¹ Wolbachia creates an ineffective neutrophil response by preventing the disperal of eosinophils.¹ The Wolbachia stimulate the production of chemotactic cytokines that determine the neutrophil recruitment. When these neutrophils engulf the Wolbachia containing filarial nematodes, it stimulates the production of more chemotactic cytokines and thus a greater neutrophil recruitment pull. The large numbers of neutrophils release toxins, resulting in detrimental effects to nearby cells that regulate corneal functions.⁶ This event shows how Wolbachia can contribute to onchocerciasis.

Effectiveness of Antibiotic Treatments

Antibiotics have been seen to affect filarial nematodes due to their symbiotic relationship with Wolbachia.¹ However, these treatments differ in efficacy, depletion of Wolbachia in the filarial nematode, and the duration and dosage of treatment.

The depletion of Wolbachia by the tetracycline class of antibiotics results in sterilization of the female filarial nematode. ¹ Another derivative of the tetracycline class, doxycycline, results in a block in development of the filarial nematodes in the host, preventing the parasites from reaching a reproductive age to proliferate the disease. ¹ Rifampicin, oxytetracycline, and chloromphenicol all affect the filarial nematodes’ abilities to move, thus inhibit it spreading as effectively.⁷

Doxycycline Treatments

Thus far, long dose treatments of doxycycline seem to be most effective in treating these tropical diseases: treatment of 100 mg/day for six weeks showed full Wolbachia depletion and sterilization of female filarial nematodes for 18 months, while 200 mg/day for 4 – 6 weeks showed detrimental effects towards filarial nematodes.⁸ However, the doxycycline can disrupt bone and teeth development, making it unsafe for children and pregnant women to use.⁹ Due to its long duration treatments and its inability to be safe for all people to use, doxycycline is unsuitable via mass drug administration.¹⁰ Therefore, other combinations of effective treatments are being evaluated as an alternative to doxycycline that are suitable for mass drug administration.

Rifampicin Treatments

Shorter treatments of rifampicin were tested to see if this antibiotic treatment would serve as an effective alternative for long duration and dose treatments of doxycycline. It was found that 10 mg/kg/day of rifampicin treatments for 2 weeks and 4 weeks on the Wolbachia inside O. volvulus, resulted in a decrease of filarial activity but not to the same degree seen from doxycycline treatments. Thus it might be more effective to looking into treatments that use both doxycycline and rifampicin.¹¹

It was tested to see whether combinations rifampicin and oxytetracycline would be effective treatments. The results showed that oxytetracycline treatments alone were the most effective in affecting the filarial nematodes, with a six month treatment with monthly dosing being the most effective, but 3 week and 6 week treatments also showing detrimental effects to filarial nematodes. However, rifampin alone and oxytetracycline-rifampin treatments showed at most borderline noticeable effects on the nematodes.¹² Therefore, it may be better to look into other treatments that do not include rifampicin. The antibiotic had shown promise as an effective treatment for these diseases.¹¹ However, it may be possible that those levels of efficacy are not replicable or the Wolbachia is already developing antibiotic resistance to rifampicin.

Corallopyronin A

Doxycycline is harmful to pregnant women and children. Rifampicin is used to treat tuberculosis and could result in cross-resistance occurring in Wolbachia. ¹³ Therefore, other antibiotics must be tested to see if they are effective in removing Wolbachia from the nematodes. Corallopyronin A is a noncompetitive inhibitor of bacterial DNA-dependent RNA polymerase. ¹³ This target for the Corallopyronin A is specific to prokaryotes and different enough from the mode of action of Rifampicin to prevent cross-resistance from occurring. Treatment of 35 mg/kg/day for 28 days showed removed more than 98% of the Wolbachia along with no adverse effects to the mammalian host. These results are equivalent to a treatment of high dose doxycycline for a short period of time and a longer duration treatment of rifampicin. ¹³ Treatment of Corallopyronin A resulted in shorter larvae and sterility of the female filarial nematodes. These results show the possibility of Corallopyronin A as a potential antibiotic for treatment of filarial caused diseases.¹³

Figure 2. Dynamics of cell and Wolbachia response to doxycycline over 21 days. Wolbachia growth was assessed by qPCR targeting the 16S rRNA gene (A). C6/36 cell growth was assessed by qPCR targeting the 18S rRNA gene of Aedes albopictus (B). Data was normalised using the ratio of 16S copies to 18S copies (C). ¹⁰

Other Treatments

The most recent find in effective antibiotic treatments may that there are many options for antibiotics. One group looked at repurposing antibiotics. They found that 69 out of 121 compounds that showed in vitro activity towards filarial nematodes were seen as possible effective targets for removing Wolbachia from these nematodes.¹⁰ Using this information, 4 out of 15 selected compounds were found to show in vivo activity. As seen in Figure 2, the effectiveness of these compounds was evaluated when by comparing the effects to doxycycline. These treatments came from the fluoroquinolone, tetracycline, and rifamycin classes.¹⁰ One of the most surprising results showed that ciprofloxacin from the fluoroquinolone class showed detrimental effects towards filarial activity. This finding is contradictory to earlier studies testing ciprofloxacin as an effective treatment for these tropical diseases.¹⁰ Thus it is possible that Wolbachia may have lost its antibiotic resistance towards this specific antibiotic and opens up possibilities to new research and more treatments that may have been overlooked to its inconsistencies in removing the Wolbachia. This particular study has shown that there is much more to learned about this phenomena and much more research to be done to fully understand the depth of the symbiotic relationship and treatments. Mechanisms of action for the identified 69 compounds that showed in vitro activity still have yet to be discovered. This area of research is rapidly evolving and expanding, with new questions popping up along the way.

Mechanisms of Action

Due to growing antibiotic resistance observed across many bacteria, it is beneficial to determine the mechanisms of action for antibiotic treatments as well as find targets for novel mechanisms of action to develop new antibiotics.

Heme Biosynthesis Pathway

The Heme Biosynthesis Pathway has been identified a possible target for antibiotics on Wolbachia. Although humans also synthesize heme enzymes, there is a significant evolutionary distance between the human and Wolbachia heme synthesis genes.¹⁴ Thus, for the most part, protein products of Wolbachia heme biosynthesis genes targeted by potentially new antibiotics, will not affect protein products of human heme biosynthesis genes human and have an adverse effect on the person taking the antibiotics. The reduction of this gene expression led to reduced adult filarial motility.¹⁴ Thus, preventing the nematodes’ ability to spread the filarial effects.

Figure 3. Inner circle corresponds to 7 d and outer circle to 14 d post-treatment data. The white junction ring between the 7 d and 14 d data allows a direct comparison of the proportions between both datasets. White spaces between colored boxes indicate missing GO categories in each of the datasets, or reduced numbers of genes belonging to that category in one of the datasets as compared to the other. doi:10.1371/journal.pntd.0000525.g004 ¹⁵

Gene Expression of B. malayi

Tests done on the gene expression of the host, B. malayi, when treated with antibiotics from the tetracycline class were done to see how the host copes after depletion of its endosymbiont. As seen in Figure 3, it was found that once the Wolbachia had been depleted, there was an upregulation of gene expression from genes that encode for amino acid synthesis and protein translation, and a downregulation of genes that encode for cuticle biosynthesis when looking at day 7 and day 14 of the antibiotic treatment.¹⁵ The upregulation of the specific genes suggest a stress response, as seen in other organisms, to a large depletion of nutrients. The Wolbachia may have been supplying the host with a great deal of nutrients and once they were removed from the host, the nematode had to make its own.¹⁵ At day 7, genes expression from genes encoding for energy metabolism pathways seemed downregulated as well.¹⁵ This could be interpreted as the filarial nematode saving energy for protein synthesis and be the reason for its reduced motility. Other downregulated genes included ones involved in cuticle biosynthesis, which could be interpreted as an interruption in the normal process of embryogenesis.¹⁵

FtsZ Pathway

FtsZ is a very highly conversed and essential cell division protein that is utilized in almost all bacteria and shows GTPase activity.¹⁶ Inhibition of the protein’s production was tested by evaluating GTPase activity. It was observed that FtsZ was found in all stages of development, and specifically observed to be most numerous in during the fourth larval stage and in adult females and least numerous during the third larval stage. Since the third larval stage signifies that the filarial nematode is infectious and the fourth larval stage occurs after infecting the host, these results suggest that there is a large amount of replication occurring right after the filarial nematode infects its host.¹⁶ B. malayi was treated with GTPase inhibitors and there was a decrease in motility and proliferation of the nematode. These results show that FtsZ is a potential target for antibiotics treating these tropical diseases, and open up the possibilities for other possible cell division proteins as targets for inhibitors.¹⁶

Previous studies have shown that antibiotics in the acyldepsipeptide class have been shown to prevent bacterial growth of bacteria by making the bacteria over stimulate the peptidase ClpP, a protease that cleaves certain proteins.¹⁷ Also other studies have showns that that acyldepsipeptide-activated CIpP degrades the cell division protein FtsZ, preventing bacterial cell division and helping induce death.¹⁷ Although acyldepsipeptides usually only effective on gram-positive bacteria, they can be effective on gram-negative bacteria if the membrane is permeablized, allowing the antibiotic to enter into the cell. However, Wolbachia does not have a typical gram-negative membrane and its membrane is actually permeable to this class of antibiotics.¹⁷ Thus tests have been done to see if acyldepsipeptides are effective in killing the Wolbachia and therefore the filarial nematodes. It was found that acyldepsipeptides are effective against recombinant Wolbachia ClpP. Once treated with the acyldepsipeptides, there was a decrease of Wolbachia, showing that that Wolbachial ClpP is a potential target for novel antibiotics in killing Wolbachia in filarial nematodes.¹⁷

Further Reading

The highly specialized and dependent symbiotic relationship between filarial nematodes and Wolbachia has just been uncovered as Wolbachia is seen as a possible antibiotic target for filarial caused diseases. This field is rapidly growing as more discoveries are being made about the symbiotic relationship, effectiveness of antibiotic treatments that are suitable for mass drug administration, and new mechanisms of action for possible future antibiotics to prevent against antibiotic resistance. This field has very relevant applications to the field of medicine and opens up the possibilities for further research into other bacteria in symbiotic relationships as antibiotic targets for vector control in the fight against infectious diseases.

According to the Bill & Melinda Gates foundation, more than 1 billion people in developing countries suffer from infectious diseases. These diseases bring in very little attention and donations, mainly because these infectious diseases are very uncommon in wealthier countries. For more information about getting involved in the eradication of these neglected tropical diseases, please look into the Carter Center Health Program and the Bill & Melinda Gates foundation.

For more information about these neglected tropical diseases, please look into:

Neglected tropical diseases - World Health Organization

Lymphatic Filariasis — Centers for Disease Control and Prevention

Onchoceriasis — Centers for Disease Control and Prevention

Other interesting topics surrounding Wolbachia include:

Biology of Wolbachia — John H. Werren Biology Department, University of Rochester, Rochester, New York 14627

Application of Wolbachia in Invertebrate Vector Control — Chinagozi Ugwu

References

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Edited by Nitin Kuppanda, a student of Suzanne Kern in BIOL168L (Microbiology) in The Keck Science Department of the Claremont Colleges Spring 2015.