ABSTRACT
Malaria is one of the world’s most common and serious diseases causing death up to about three million
people each year. Its most severe occurrence is caused by the protozoan Plasmodium falciparum. Reports
have shown that the resistance of the parasite to existing drugs is increasing. Therefore, there is a huge
and urgent need to discover and validate new drug or vaccine targets to enable the development of new
treatments for malaria. The ability to discover these drug or vaccine targets can only be enhanced from
our deep understanding of the detailed biology of the parasite, for example, how cells function and how
proteins organize into modules such as metabolic, regulatory and signal transduction pathways. The
formally effective and popular anti-malaria drug chloroquine inhibits multiple sites in metabolic
pathways, leading to neutrophil superoxide release. It has therefore been noted that the knowledge of
metabolic pathways and recently signalling transduction pathways in Plasmodium are fundamental to aid
the design of new strategies against malaria. In the first part of this work, a linear-time algorithm for
finding paths in a protein-protein interactions network under modified biologically motivated constraints
was used. Several important signalling transduction pathways in Plasmodium falciparum were predicted.
A viable signalling pathway characterized in terms of the genes responsible that may be the PfPKB
pathway recently elucidated in Plasmodium falciparum was predicted. We obtained from the FIKK
family, a signal transduction pathway that ends upon a chloroquine resistance marker protein, which
indicates that interference with FIKK proteins might reverse Plasmodium falciparum from resistant to
sensitive phenotype. We also propose a hypothesis that showed the FIKK proteins in this pathway as
enabling the resistance parasite to have a mechanism for releasing chloroquine(via an efflux process).
Furthermore, a signalling pathway that may have been responsible for signalling the start of the invasion
process of Red Blood Cell(RBC) by the merozoites was also predicted. It has been noted that the
understanding of this pathway will give insight into the parasite virulence and will facilitate rational
vaccine design against merozoites invasion. And we have a host of other predicted pathways, some of
which have been used in this work to predict the functionality of some proteins. In another work, we
adapted and extended a method (used in the first work for extracting signalling pathways) to extract linear
metabolic pathways from the malaria parasite, Plasmodium falciparum metabolic weighted graphs
(networks). The weights are calculated using the metabolite degrees. Adopting the representation of the
biochemical metabolic network as we have in Koenig et al., 2006, we are able to make our algorithm
tenable to accept metabolic network from other source apart from KEGG. This gives us opportunity for
the first time, to compare the metabolic pathways extracted from different metabolic networks. We run
our algorithm (for four selected pathways: Pyruvate, Glutamate, Glycolysis and Mitochondrial TCA) on
graph from KEGG and compare our results with the results obtained from recent algorithms: ReTrace and
atommetanet. Our results compare favourably with these two algorithms. Considering the results with
genes classified into these pathways from Plasmodb, resulted into a lot of false positiveness. Furthermore,
we compared the runs of our algorithm on graphs from KEGG and PlasmoCyc (from BioCyc). The
results are remarkably different and the results from PlasmoCyc produced less false positiveness when
compared to the results from Plasmodb. We identify 2, 1, 2, 4 gene(s) in addition to belong to these
pathways respectively. Some of the genes have not been classified earlier to any known metabolic pathways.
Jelili, O (2021). Computational Identification Of Signalling And Metabolic Pathways Of Plasmodium Falciparum. Afribary. Retrieved from https://tracking.afribary.com/works/computational-identification-of-signalling-and-metabolic-pathways-of-plasmodium-falciparum
Jelili, OYELADE "Computational Identification Of Signalling And Metabolic Pathways Of Plasmodium Falciparum" Afribary. Afribary, 20 May. 2021, https://tracking.afribary.com/works/computational-identification-of-signalling-and-metabolic-pathways-of-plasmodium-falciparum. Accessed 25 Nov. 2024.
Jelili, OYELADE . "Computational Identification Of Signalling And Metabolic Pathways Of Plasmodium Falciparum". Afribary, Afribary, 20 May. 2021. Web. 25 Nov. 2024. < https://tracking.afribary.com/works/computational-identification-of-signalling-and-metabolic-pathways-of-plasmodium-falciparum >.
Jelili, OYELADE . "Computational Identification Of Signalling And Metabolic Pathways Of Plasmodium Falciparum" Afribary (2021). Accessed November 25, 2024. https://tracking.afribary.com/works/computational-identification-of-signalling-and-metabolic-pathways-of-plasmodium-falciparum