Plasmodium falciparum UvrD activities are downregulated by DNA-interacting compounds and its dsRNA inhibits malaria parasite growth.

Q2 Biochemistry, Genetics and Molecular Biology
Mohammed Tarique, Farha Tabassum, Moaz Ahmad, Renu Tuteja
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引用次数: 16

Abstract

Background: Human malaria parasite infection and its control is a global challenge which is responsible for ~0.65 million deaths every year globally. The emergence of drug resistant malaria parasite is another challenge to fight with malaria. Enormous efforts are being made to identify suitable drug targets in order to develop newer classes of drug. Helicases play crucial roles in DNA metabolism and have been proposed as therapeutic targets for cancer therapy as well as viral and parasitic infections. Genome wide analysis revealed that Plasmodium falciparum possesses UvrD helicase, which is absent in the human host.

Results: Recently the biochemical characterization of P. falciparum UvrD helicase revealed that N-terminal UvrD (PfUDN) hydrolyses ATP, translocates in 3' to 5' direction and interacts with MLH to modulate each other's activity. In this follow up study, further characterization of P. falciparum UvrD helicase is presented. Here, we screened the effect of various DNA interacting compounds on the ATPase and helicase activity of PfUDN. This study resulted into the identification of daunorubicin (daunomycin), netropsin, nogalamycin, and ethidium bromide as the potential inhibitor molecules for the biochemical activities of PfUDN with IC50 values ranging from ~3.0 to ~5.0 μM. Interestingly etoposide did not inhibit the ATPase activity but considerable inhibition of unwinding activity was observed at 20 μM. Further study for analyzing the importance of PfUvrD enzyme in parasite growth revealed that PfUvrD is crucial/important for its growth ex-vivo.

Conclusions: As PfUvrD is absent in human hence on the basis of this study we propose PfUvrD as suitable drug target to control malaria. Some of the PfUvrD inhibitors identified in the present study can be utilized to further design novel and specific inhibitor molecules.

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恶性疟原虫UvrD活性被dna相互作用化合物下调,其dsRNA抑制疟原虫生长。
背景:人疟原虫感染及其控制是一项全球性挑战,每年在全球造成约65万人死亡。耐药疟原虫的出现是抗击疟疾的另一个挑战。目前正在作出巨大努力来确定合适的药物靶点,以便开发新的药物类别。解旋酶在DNA代谢中起着至关重要的作用,已被认为是癌症治疗以及病毒和寄生虫感染的治疗靶点。全基因组分析表明,恶性疟原虫具有人类宿主不存在的UvrD解旋酶。结果:近年来恶性疟原虫UvrD解旋酶的生化特性表明,n端UvrD (PfUDN)水解ATP,并在3′~ 5′方向移位,与MLH相互作用,调节彼此的活性。在这项后续研究中,进一步表征了恶性疟原虫UvrD解旋酶。在这里,我们筛选了各种DNA相互作用化合物对PfUDN的atp酶和解旋酶活性的影响。本研究鉴定出柔红霉素(道诺霉素)、netropsin、诺加霉素和溴化乙啶作为PfUDN生物化学活性的潜在抑制分子,IC50值在~3.0 ~ ~5.0 μM之间。有趣的是,依托泊苷没有抑制atp酶活性,但在20 μM下观察到相当大的解绕活性抑制。进一步的研究分析了PfUvrD酶在寄生虫生长中的重要性,发现PfUvrD对寄生虫的体外生长至关重要。结论:由于PfUvrD在人体内缺乏,因此在本研究的基础上,我们提出PfUvrD作为控制疟疾的合适药物靶点。本研究中发现的一些PfUvrD抑制剂可用于进一步设计新的特异性抑制剂分子。
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来源期刊
BMC Biochemistry
BMC Biochemistry BIOCHEMISTRY & MOLECULAR BIOLOGY-
CiteScore
4.80
自引率
0.00%
发文量
0
审稿时长
3 months
期刊介绍: BMC Biochemistry is an open access journal publishing original peer-reviewed research articles in all aspects of biochemical processes, including the structure, function and dynamics of metabolic pathways, supramolecular complexes, enzymes, proteins, nucleic acids and small molecular components of organelles, cells and tissues. BMC Biochemistry (ISSN 1471-2091) is indexed/tracked/covered by PubMed, MEDLINE, BIOSIS, CAS, EMBASE, Scopus, Zoological Record, Thomson Reuters (ISI) and Google Scholar.
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