Gene_locus Report for: schha-ACHE

Schistosomiasis is a neglected tropical disease caused by blood flukes (genus Schistosoma; schistosomes) and affecting 200 million people worldwide. No vaccines are available, and treatment relies on one drug, praziquantel. Schistosoma haematobium has come into the spotlight as a major cause of urogenital disease, as an agent linked to bladder cancer and as a predisposing factor for HIV/AIDS. The parasite is transmitted to humans from freshwater snails. Worms dwell in blood vessels and release eggs that become embedded in the bladder wall to elicit chronic immune-mediated disease and induce squamous cell carcinoma. Here we sequenced the 385-Mb genome of S. haematobium using Illumina-based technology at 74-fold coverage and compared it to sequences from related parasites. We included genome annotation based on function, gene ontology, networking and pathway mapping. This genome now provides an unprecedented resource for many fundamental research areas and shows great promise for the design of new disease interventions.

Acetylcholinesterase (AChE) on the surface of the parasitic blood fluke Schistosoma is the likely target for schistosomicidal anticholinesterases. Determination of the molecular structure of this drug target is key for the development of improved anticholinesterase drugs and potentially a novel vaccine. We have recently cloned the cDNA encoding the AChE from the human parasite Schistosoma haematobium and succeeded in expressing functional recombinant protein. We now describe the cloning and molecular characterisation of homologues from two other schistosome species-Schistosoma mansoni and Schistosoma bovis, which are important parasites of man and cattle, respectively, but which differ in their sensitivity to the therapeutic anticholinesterase metrifonate. Comparison of the deduced amino acid sequences revealed that the AChE from all three species posses a high degree of identity, with conservation of all of the residues known to be important for substrate binding and catalytic activity. Also conserved is a unique C-terminal domain which is unusual in that it lacks the consensus for GPI modification, even though the native protein is considered to be GPI-anchored. We have also established the AChE gene structures for all three species and cloned the complete gene for S. haematobium AChE. The gene structure is relatively complex, comprising nine coding exons; the location of the splice sites is identical in all three species, but the size of the introns varies considerably. The two C-terminal splicing sites that are conserved in all species are also present in Schistosoma, but a third C-terminal conserved splicing site which is located 11-13 amino acids upstream of the histidine of the catalytic triad in all invertebrate AChE genes characterised to date is absent. We discuss our findings in the context of the molecular phylogeny of the AChE genes and the potential application to the control of schistosomiasis.

Acetylcholinesterase (AChE) present on the surface of the trematode blood fluke Schistosoma has been implicated in the regulation of glucose scavenging from the host blood. Determination of the molecular structure and functional characteristics of this molecule is a crucial first step in understanding the novel function for AChE and in evaluating the potential of schistosome AChE as a target of new parasite control methods. We have determined the primary structure of acetylcholinesterase from Schistosoma haematobium. Immunolocalization studies confirmed that the enzyme was present on the parasite surface as well as in the muscle. The derived amino acid sequence possesses features common to acetylcholinesterases: the catalytic triad, six cysteines that form three intramolecular disulphide bonds, and aromatic residues lining the catalytic gorge. An unusual feature is that the fully processed native enzyme exists as a glycoinositol phospholipid (GPI)-anchored dimer, but the sequence of the C?terminus does not conform to the current consensus for GPI modification. The enzyme expressed in Xenopus oocytes showed conventional substrate specificity and sensitivity to established inhibitors of AChE, although it is relatively insensitive to the peripheral site inhibitor propidium iodide. Distinctions between host and parasite AChEs will allow the rational design of schistosome-specific drugs and vaccines.

Schistosomiasis is a neglected tropical disease caused by blood flukes (genus Schistosoma; schistosomes) and affecting 200 million people worldwide. No vaccines are available, and treatment relies on one drug, praziquantel. Schistosoma haematobium has come into the spotlight as a major cause of urogenital disease, as an agent linked to bladder cancer and as a predisposing factor for HIV/AIDS. The parasite is transmitted to humans from freshwater snails. Worms dwell in blood vessels and release eggs that become embedded in the bladder wall to elicit chronic immune-mediated disease and induce squamous cell carcinoma. Here we sequenced the 385-Mb genome of S. haematobium using Illumina-based technology at 74-fold coverage and compared it to sequences from related parasites. We included genome annotation based on function, gene ontology, networking and pathway mapping. This genome now provides an unprecedented resource for many fundamental research areas and shows great promise for the design of new disease interventions.

Acetylcholinesterase (AChE) on the surface of the parasitic blood fluke Schistosoma is the likely target for schistosomicidal anticholinesterases. Determination of the molecular structure of this drug target is key for the development of improved anticholinesterase drugs and potentially a novel vaccine. We have recently cloned the cDNA encoding the AChE from the human parasite Schistosoma haematobium and succeeded in expressing functional recombinant protein. We now describe the cloning and molecular characterisation of homologues from two other schistosome species-Schistosoma mansoni and Schistosoma bovis, which are important parasites of man and cattle, respectively, but which differ in their sensitivity to the therapeutic anticholinesterase metrifonate. Comparison of the deduced amino acid sequences revealed that the AChE from all three species posses a high degree of identity, with conservation of all of the residues known to be important for substrate binding and catalytic activity. Also conserved is a unique C-terminal domain which is unusual in that it lacks the consensus for GPI modification, even though the native protein is considered to be GPI-anchored. We have also established the AChE gene structures for all three species and cloned the complete gene for S. haematobium AChE. The gene structure is relatively complex, comprising nine coding exons; the location of the splice sites is identical in all three species, but the size of the introns varies considerably. The two C-terminal splicing sites that are conserved in all species are also present in Schistosoma, but a third C-terminal conserved splicing site which is located 11-13 amino acids upstream of the histidine of the catalytic triad in all invertebrate AChE genes characterised to date is absent. We discuss our findings in the context of the molecular phylogeny of the AChE genes and the potential application to the control of schistosomiasis.

Acetylcholinesterase (AChE) present on the surface of the trematode blood fluke Schistosoma has been implicated in the regulation of glucose scavenging from the host blood. Determination of the molecular structure and functional characteristics of this molecule is a crucial first step in understanding the novel function for AChE and in evaluating the potential of schistosome AChE as a target of new parasite control methods. We have determined the primary structure of acetylcholinesterase from Schistosoma haematobium. Immunolocalization studies confirmed that the enzyme was present on the parasite surface as well as in the muscle. The derived amino acid sequence possesses features common to acetylcholinesterases: the catalytic triad, six cysteines that form three intramolecular disulphide bonds, and aromatic residues lining the catalytic gorge. An unusual feature is that the fully processed native enzyme exists as a glycoinositol phospholipid (GPI)-anchored dimer, but the sequence of the C?terminus does not conform to the current consensus for GPI modification. The enzyme expressed in Xenopus oocytes showed conventional substrate specificity and sensitivity to established inhibitors of AChE, although it is relatively insensitive to the peripheral site inhibitor propidium iodide. Distinctions between host and parasite AChEs will allow the rational design of schistosome-specific drugs and vaccines.