| Q34595329 | "Candidatus Midichloria" endosymbionts bloom after the blood meal of the host, the hard tick Ixodes ricinus |
| Q35825354 | A histochemical study of the Nras/let-60 activity in filarial nematodes |
| Q34416898 | A murine macrofilaricide pre-clinical screening model for onchocerciasis and lymphatic filariasis |
| Q34675099 | A potential role for the interaction of Wolbachia surface proteins with the Brugia malayi glycolytic enzymes and cytoskeleton in maintenance of endosymbiosis |
| Q36377512 | A real-time PCR-based assay for detection of Wuchereria bancrofti DNA in blood and mosquitoes. |
| Q61450807 | AWZ1066S, a highly specific anti- drug candidate for a short-course treatment of filariasis |
| Q39565284 | Absence of Wolbachia endobacteria in Sri Lankan isolates of the nematode parasite of animals Setaria digitata |
| Q37714566 | Absence of Wolbachia endobacteria in the human parasitic nematode Dracunculus medinensis and two related Dracunculus species infecting wildlife |
| Q36932488 | Absence of Wolbachia endobacteria in the non-filariid nematodes Angiostrongylus cantonensis and A. costaricensis |
| Q44288385 | Albendazole and antibiotics synergize to deliver short-course anti-Wolbachia curative treatments in preclinical models of filariasis. |
| Q36446223 | Analysis of gene expression from the Wolbachia genome of a filarial nematode supports both metabolic and defensive roles within the symbiosis. |
| Q28294770 | Anti-Wolbachia drug discovery and development: safe macrofilaricides for onchocerciasis and lymphatic filariasis |
| Q34071384 | Anti-filarial activity of antibiotic therapy is due to extensive apoptosis after Wolbachia depletion from filarial nematodes. |
| Q28474923 | Asymmetric Wolbachia Segregation during Early Brugia malayi Embryogenesis Determines Its Distribution in Adult Host Tissues |
| Q36056638 | Autophagy regulates Wolbachia populations across diverse symbiotic associations |
| Q64268314 | Boron-Pleuromutilins as Anti- Wolbachia Agents with Potential for Treatment of Onchocerciasis and Lymphatic Filariasis |
| Q30528769 | Both asymmetric mitotic segregation and cell-to-cell invasion are required for stable germline transmission of Wolbachia in filarial nematodes |
| Q28476291 | Brugia malayi gene expression in response to the targeting of the Wolbachia endosymbiont by tetracycline treatment |
| Q28484257 | Characterization of transcription factors that regulate the type IV secretion system and riboflavin biosynthesis in Wolbachia of Brugia malayi |
| Q48309955 | Combinations of registered drugs reduce treatment times required to deplete Wolbachia in the Litomosoides sigmodontis mouse model. |
| Q40224972 | Competition for amino acids between Wolbachia and the mosquito host, Aedes aegypti |
| Q34897264 | Concurrent transcriptional profiling of Dirofilaria immitis and its Wolbachia endosymbiont throughout the nematode life cycle reveals coordinated gene expression |
| Q36328350 | Defining Brugia malayi and Wolbachia symbiosis by stage-specific dual RNA-seq |
| Q34632373 | Dirofilaria immitis and Wolbachia pipientis: a thorough investigation of the symbiosis responsible for canine heartworm disease |
| Q33283264 | Diversifying selection and host adaptation in two endosymbiont genomes |
| Q40421498 | Doxycycline treatment of Brugia malayi-infected persons reduces microfilaremia and adverse reactions after diethylcarbamazine and albendazole treatment |
| Q91655025 | Drug Repurposing of Bromodomain Inhibitors as Potential Novel Therapeutic Leads for Lymphatic Filariasis Guided by Multispecies Transcriptomics |
| Q57230426 | Effects of doxycycline on early infections of Dirofilaria immitis in dogs |
| Q41628204 | Effects of doxycycline on heartworm embryogenesis, transmission, circulating microfilaria, and adult worms in microfilaremic dogs |
| Q45886600 | Effects of gamma radiation on Brugia malayi infective larvae and their intracellular Wolbachia bacteria |
| Q34086072 | Endosymbiotic bacteria associated with nematodes, ticks and amoebae |
| Q34993097 | Extensively duplicated and transcriptionally active recent lateral gene transfer from a bacterial Wolbachia endosymbiont to its host filarial nematode Brugia malayi |
| Q33908223 | Genomic diversity in Onchocerca volvulus and its Wolbachia endosymbiont |
| Q35989879 | Glucose and Glycogen Metabolism in Brugia malayi Is Associated with Wolbachia Symbiont Fitness |
| Q61078227 | Growth kinetics of endosymbiont Wolbachia in the common bed bug, Cimex lectularius |
| Q42982359 | Heartworm and Wolbachia: therapeutic implications |
| Q37166605 | Heartworm disease in animals and humans |
| Q34165647 | Horizontal gene transfer between bacteria and animals |
| Q34327101 | Human and animal dirofilariasis: the emergence of a zoonotic mosaic |
| Q92416690 | In vivo kinetics of Wolbachia depletion by ABBV-4083 in L. sigmodontis adult worms and microfilariae |
| Q60922213 | Industrial scale high-throughput screening delivers multiple fast acting macrofilaricides |
| Q34492794 | Inflammatory responses to migrating Brugia pahangi third-stage larvae |
| Q37650412 | Integrated transcriptomic and proteomic analysis of the global response of Wolbachia to doxycycline-induced stress. |
| Q33969342 | Interaction of a Wolbachia WSP-like protein with a nuclear-encoded protein of Brugia malayi |
| Q36835654 | Interdomain lateral gene transfer of an essential ferrochelatase gene in human parasitic nematodes |
| Q34500870 | Live Brugia malayi microfilariae inhibit transendothelial migration of neutrophils and monocytes |
| Q30481947 | Macrofilaricidal activity after doxycycline only treatment of Onchocerca volvulus in an area of Loa loa co-endemicity: a randomized controlled trial |
| Q36708214 | Minocycline as a re-purposed anti-Wolbachia macrofilaricide: superiority compared with doxycycline regimens in a murine infection model of human lymphatic filariasis. |
| Q98306012 | Modeling the metabolic interplay between a parasitic worm and its bacterial endosymbiont allows the identification of novel drug targets |
| Q92290113 | Molecular Analysis of Canine Filaria and Its Wolbachia Endosymbionts in Domestic Dogs Collected from Two Animal University Hospitals in Bangkok Metropolitan Region, Thailand |
| Q46463593 | Molecular diversity of bacterial endosymbionts associated with dagger nematodes of the genus Xiphinema (Nematoda: Longidoridae) reveals a high degree of phylogenetic congruence with their host. |
| Q36430262 | Nematode-bacterium symbioses--cooperation and conflict revealed in the "omics" age. |
| Q89999742 | Novel anti-Wolbachia drugs, a new approach in the treatment and prevention of veterinary filariasis? |
| Q52691631 | Polar cell fate stimulates Wolbachia intracellular growth. |
| Q34705835 | Potential involvement of Brugia malayi cysteine proteases in the maintenance of the endosymbiotic relationship with Wolbachia |
| Q90375044 | Pyruvate produced by Brugia spp. via glycolysis is essential for maintaining the mutualistic association between the parasite and its endosymbiont, Wolbachia |
| Q93082813 | Quantitative methods for assessing local and bodywide contributions to Wolbachia titer in maternal germline cells of Drosophila |
| Q33607026 | Reciprocal Interactions between Nematodes and Their Microbial Environments |
| Q30377066 | Short-Course, High-Dose Rifampicin Achieves Wolbachia Depletion Predictive of Curative Outcomes in Preclinical Models of Lymphatic Filariasis and Onchocerciasis. |
| Q92209251 | Short-course quinazoline drug treatments are effective in the Litomosoides sigmodontis and Brugia pahangi jird models |
| Q33576552 | Significant heterogeneity in Wolbachia copy number within and between populations of Onchocerca volvulus |
| Q37153483 | Stage-specific Proteomes from Onchocerca ochengi, Sister Species of the Human River Blindness Parasite, Uncover Adaptations to a Nodular Lifestyle |
| Q30492130 | Symmetric and asymmetric mitotic segregation patterns influence Wolbachia distribution in host somatic tissue |
| Q28478176 | Targeting the Wolbachia cell division protein FtsZ as a new approach for antifilarial therapy |
| Q34054632 | The Wolbachia endosymbiont as an anti-filarial nematode target |
| Q96816158 | The shutting down of the insulin pathway: a developmental window for Wolbachia load and feminization |
| Q30354455 | The tripartite associations between bacteriophage, Wolbachia, and arthropods. |
| Q27306139 | Tissue and stage-specific distribution of Wolbachia in Brugia malayi |
| Q36314012 | Toll-like receptor 2 regulates CXC chemokine production and neutrophil recruitment to the cornea in Onchocerca volvulus/Wolbachia-induced keratitis |
| Q51644682 | Unravelling the Wolbachia evolutionary role: the reprogramming of the host genomic imprinting. |
| Q34460316 | Wolbachia bacterial endosymbionts of filarial nematodes |
| Q38064892 | Wolbachia filarial interactions |
| Q33776068 | Wolbachia infection and mitochondrial diversity in the canine heartworm (Dirofilaria immitis). |
| Q42009249 | Wolbachia- and Onchocerca volvulus-induced keratitis (river blindness) is dependent on myeloid differentiation factor 88 |
| Q37522724 | Wolbachia-induced neutrophil activation in a mouse model of ocular onchocerciasis (river blindness). |
| Q30352017 | Wolbachia: Can we save lives with a great pandemic? |