Assessing the anthelmintic activity of pyrazole-5-carboxamide derivatives against Haemonchus contortus
- Jiao, Yaqing, Preston, Sarah, Song, Hongjian, Jabbar, Abdul, Liu, Yuxiu, Baell, Jonathan, Hofmann, Andreas, Hutchinson, Dana, Wang, Tao, Koehler, Anson, Fisher, Gillian, Andrews, Katherine, Laleu, Benoit, Palmer, Michael, Burrows, Jeremy, Wells, Timothy, Wang, Qingmin, Gasser, Robin
- Authors: Jiao, Yaqing , Preston, Sarah , Song, Hongjian , Jabbar, Abdul , Liu, Yuxiu , Baell, Jonathan , Hofmann, Andreas , Hutchinson, Dana , Wang, Tao , Koehler, Anson , Fisher, Gillian , Andrews, Katherine , Laleu, Benoit , Palmer, Michael , Burrows, Jeremy , Wells, Timothy , Wang, Qingmin , Gasser, Robin
- Date: 2017
- Type: Text , Journal article
- Relation: Parasites and Vectors Vol. 10, no. 1 (2017), p. 1-7
- Full Text:
- Reviewed:
- Description: Background: In this study, we tested five series of pyrazole-5-carboxamide compounds (n = 55) for activity against parasitic stages of the nematode Haemonchus contortus (barber’s pole worm), one of the most pathogenic parasites of ruminants. Methods: In an optimised, whole-organism screening assay, using exsheathed third-stage (xL3) and fourth-stage (L4) larvae, we measured the inhibition of larval motility and development of H. contortus. Results: Amongst the 55 compounds, we identified two compounds (designated a-15 and a-17) that reproducibly inhibit xL3 motility as well as L4 motility and development, with IC50 values ranging between ~3.4 and 55.6 μM. We studied the effect of these two ‘hit’ compounds on mitochondrial function by measuring oxygen consumption. This assessment showed that xL3s exposed to each of these compounds consumed significantly less oxygen and had less mitochondrial activity than untreated xL3s, which was consistent with specific inhibition of complex I of the respiratory electron transport chain in arthropods. Conclusions: The present findings provide a sound basis for future work, aimed at identifying the targets of compounds a-15 and a-17 and establishing the modes of action of these chemicals in H. contortus. © 2017 The Author(s).
- Authors: Jiao, Yaqing , Preston, Sarah , Song, Hongjian , Jabbar, Abdul , Liu, Yuxiu , Baell, Jonathan , Hofmann, Andreas , Hutchinson, Dana , Wang, Tao , Koehler, Anson , Fisher, Gillian , Andrews, Katherine , Laleu, Benoit , Palmer, Michael , Burrows, Jeremy , Wells, Timothy , Wang, Qingmin , Gasser, Robin
- Date: 2017
- Type: Text , Journal article
- Relation: Parasites and Vectors Vol. 10, no. 1 (2017), p. 1-7
- Full Text:
- Reviewed:
- Description: Background: In this study, we tested five series of pyrazole-5-carboxamide compounds (n = 55) for activity against parasitic stages of the nematode Haemonchus contortus (barber’s pole worm), one of the most pathogenic parasites of ruminants. Methods: In an optimised, whole-organism screening assay, using exsheathed third-stage (xL3) and fourth-stage (L4) larvae, we measured the inhibition of larval motility and development of H. contortus. Results: Amongst the 55 compounds, we identified two compounds (designated a-15 and a-17) that reproducibly inhibit xL3 motility as well as L4 motility and development, with IC50 values ranging between ~3.4 and 55.6 μM. We studied the effect of these two ‘hit’ compounds on mitochondrial function by measuring oxygen consumption. This assessment showed that xL3s exposed to each of these compounds consumed significantly less oxygen and had less mitochondrial activity than untreated xL3s, which was consistent with specific inhibition of complex I of the respiratory electron transport chain in arthropods. Conclusions: The present findings provide a sound basis for future work, aimed at identifying the targets of compounds a-15 and a-17 and establishing the modes of action of these chemicals in H. contortus. © 2017 The Author(s).
Screening of the ‘Open Scaffolds’ collection from Compounds Australia identifies a new chemical entity with anthelmintic activities against different developmental stages of the barber's pole worm and other parasitic nematodes
- Preston, Sarah, Jiao, Yaqing, Baell, Jonathan, Keiser, Jennifer, Crawford, Simon, Koehler, Anson, Wang, Tao, Simpson, Moana, Kaplan, Ray, Cowley, Karla, Simpson, Kaylene, Hofmann, Andreas, Jabbar, Abdul, Gasser, Robin
- Authors: Preston, Sarah , Jiao, Yaqing , Baell, Jonathan , Keiser, Jennifer , Crawford, Simon , Koehler, Anson , Wang, Tao , Simpson, Moana , Kaplan, Ray , Cowley, Karla , Simpson, Kaylene , Hofmann, Andreas , Jabbar, Abdul , Gasser, Robin
- Date: 2017
- Type: Text , Journal article
- Relation: International Journal for Parasitology: Drugs and Drug Resistance Vol. 7, no. 3 (2017), p. 286-294
- Full Text:
- Reviewed:
- Description: The discovery and development of novel anthelmintic classes is essential to sustain the control of socioeconomically important parasitic worms of humans and animals. With the aim of offering novel, lead-like scaffolds for drug discovery, Compounds Australia released the ‘Open Scaffolds’ collection containing 33,999 compounds, with extensive information available on the physicochemical properties of these chemicals. In the present study, we screened 14,464 prioritised compounds from the ‘Open Scaffolds’ collection against the exsheathed third-stage larvae (xL3s) of Haemonchus contortus using recently developed whole-organism screening assays. We identified a hit compound, called SN00797439, which was shown to reproducibly reduce xL3 motility by ≥ 70%; this compound induced a characteristic, “coiled” xL3 phenotype (IC50 = 3.46–5.93 μM), inhibited motility of fourth-stage larvae (L4s; IC50 = 0.31–12.5 μM) and caused considerable cuticular damage to L4s in vitro. When tested on other parasitic nematodes in vitro, SN00797439 was shown to inhibit (IC50 = 3–50 μM) adults of Ancylostoma ceylanicum (hookworm) and first-stage larvae of Trichuris muris (whipworm) and eventually kill (>90%) these stages. Furthermore, this compound completely inhibited the motility of female and male adults of Brugia malayi (50–100 μM) as well as microfilariae of both B. malayi and Dirofilaria immitis (heartworm). Overall, these results show that SN00797439 acts against genetically (evolutionarily) distant parasitic nematodes i.e. H. contortus and A. ceylanicum [strongyloids] vs. B. malayi and D. immitis [filarioids] vs. T. muris [enoplid], and, thus, might offer a novel, lead-like scaffold for the development of a relatively broad-spectrum anthelmintic. Our future work will focus on assessing the activity of SN00797439 against other pathogens that cause neglected tropical diseases, optimising analogs with improved biological activities and characterising their targets. © 2017 The Authors
- Authors: Preston, Sarah , Jiao, Yaqing , Baell, Jonathan , Keiser, Jennifer , Crawford, Simon , Koehler, Anson , Wang, Tao , Simpson, Moana , Kaplan, Ray , Cowley, Karla , Simpson, Kaylene , Hofmann, Andreas , Jabbar, Abdul , Gasser, Robin
- Date: 2017
- Type: Text , Journal article
- Relation: International Journal for Parasitology: Drugs and Drug Resistance Vol. 7, no. 3 (2017), p. 286-294
- Full Text:
- Reviewed:
- Description: The discovery and development of novel anthelmintic classes is essential to sustain the control of socioeconomically important parasitic worms of humans and animals. With the aim of offering novel, lead-like scaffolds for drug discovery, Compounds Australia released the ‘Open Scaffolds’ collection containing 33,999 compounds, with extensive information available on the physicochemical properties of these chemicals. In the present study, we screened 14,464 prioritised compounds from the ‘Open Scaffolds’ collection against the exsheathed third-stage larvae (xL3s) of Haemonchus contortus using recently developed whole-organism screening assays. We identified a hit compound, called SN00797439, which was shown to reproducibly reduce xL3 motility by ≥ 70%; this compound induced a characteristic, “coiled” xL3 phenotype (IC50 = 3.46–5.93 μM), inhibited motility of fourth-stage larvae (L4s; IC50 = 0.31–12.5 μM) and caused considerable cuticular damage to L4s in vitro. When tested on other parasitic nematodes in vitro, SN00797439 was shown to inhibit (IC50 = 3–50 μM) adults of Ancylostoma ceylanicum (hookworm) and first-stage larvae of Trichuris muris (whipworm) and eventually kill (>90%) these stages. Furthermore, this compound completely inhibited the motility of female and male adults of Brugia malayi (50–100 μM) as well as microfilariae of both B. malayi and Dirofilaria immitis (heartworm). Overall, these results show that SN00797439 acts against genetically (evolutionarily) distant parasitic nematodes i.e. H. contortus and A. ceylanicum [strongyloids] vs. B. malayi and D. immitis [filarioids] vs. T. muris [enoplid], and, thus, might offer a novel, lead-like scaffold for the development of a relatively broad-spectrum anthelmintic. Our future work will focus on assessing the activity of SN00797439 against other pathogens that cause neglected tropical diseases, optimising analogs with improved biological activities and characterising their targets. © 2017 The Authors
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