Spatio-temporal analysis of genetic diversity of merozoite surface protein-3 alpha in Myanmar Plasmodium vivax isolates

IF 2.6 4区医学 Q3 INFECTIOUS DISEASES

Infection Genetics and Evolution Pub Date : 2024-07-10 DOI:10.1016/j.meegid.2024.105639

Tuấn Cường Võ , Jung-Mi Kang , Hương Giang Lê , Haung Naw , Tong-Soo Kim , Ho-Joon Shin , Moe Kyaw Myint , Zaw Than Htun , Byoung-Kuk Na

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引用次数: 0

Abstract

Myanmar aims to eliminate malaria by 2030. However, recent increase of malaria incidence is a great challenge to archive that goal. Increasing prevalence of Plasmodium vivax also hinders this endeavor. Monitoring genetic structure of the parasite is necessary to understand genetic nature and evolutionary aspect of P. vivax population in Myanmar. Partial fragment flanking blocks I and II of merozoite surface protein-3 alpha of P. vivax (pvmsp-3α) was amplified from P. vivax isolates collected in Pyin Oo Lwin, Mandalay Region, Myanmar in 2013–2015. Sequence analysis of pvmsp-3α was performed to determine genetic diversity and natural selection of this gene. Spatio-temporal genetic changes of pvmsp-3α in Myanmar P. vivax population were also investigated via comparative analysis of gene sequences obtained in this study and previously reported Myanmar pvmsp-3α sequences. Genetic diversity of Myanmar pvmsp-3α was detected in P. vivax isolates analyzed. Size polymorphisms in block I and amino acid changes and recombination events in block II were main factors contributing to the genetic diversity of pvmsp-3α. Comparative spatio-temporal analysis with previously reported Myanmar pvmsp-3α populations revealed the presence of genetic differences by population with moderate genetic differentiation between populations. Similar pattern of natural selection was also detected in Myanmar pvmsp-3α populations. These suggested that enough size of the P. vivax population sufficient to generate or maintain the genetic diversity remains in the population. Thus, continuous molecular surveillance of genetic structure of Myanmar P. vivax is necessary.

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缅甸疟原虫分离物中裂殖体表面蛋白-3 alpha 遗传多样性的时空分析。

缅甸的目标是到 2030 年消除疟疾。然而，最近疟疾发病率的上升是实现这一目标的巨大挑战。间日疟原虫发病率的上升也阻碍了这一目标的实现。为了了解缅甸间日疟原虫种群的遗传性质和进化情况，有必要对寄生虫的遗传结构进行监测。研究人员从2013-2015年在缅甸曼德勒地区彬乌伦收集到的疟原虫分离株中扩增出了疟原虫裂殖体表面蛋白-3α（pvmsp-3α）的I和II区块侧翼部分片段。对 pvmsp-3α 进行了序列分析，以确定该基因的遗传多样性和自然选择。通过对本研究获得的基因序列和之前报道的缅甸 pvmsp-3α 序列进行比较分析，还研究了缅甸 P. vivax 群体中 pvmsp-3α 的时空遗传变化。在分析的间日疟原虫分离株中发现了缅甸 pvmsp-3α 的遗传多样性。第一区块的大小多态性和第二区块的氨基酸变化及重组事件是导致 pvmsp-3α 遗传多样性的主要因素。与之前报道的缅甸 pvmsp-3α 种群进行的时空比较分析表明，不同种群之间存在遗传差异，种群之间的遗传差异适中。在缅甸 pvmsp-3α 群体中也发现了类似的自然选择模式。这表明，该种群中仍有足够数量的间日疟原虫种群，足以产生或维持遗传多样性。因此，有必要对缅甸鼠疫的遗传结构进行持续的分子监测。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Infection Genetics and Evolution 医学-传染病学

CiteScore

8.40

自引率

0.00%

发文量

215

审稿时长

82 days

期刊介绍： (aka Journal of Molecular Epidemiology and Evolutionary Genetics of Infectious Diseases -- MEEGID) Infectious diseases constitute one of the main challenges to medical science in the coming century. The impressive development of molecular megatechnologies and of bioinformatics have greatly increased our knowledge of the evolution, transmission and pathogenicity of infectious diseases. Research has shown that host susceptibility to many infectious diseases has a genetic basis. Furthermore, much is now known on the molecular epidemiology, evolution and virulence of pathogenic agents, as well as their resistance to drugs, vaccines, and antibiotics. Equally, research on the genetics of disease vectors has greatly improved our understanding of their systematics, has increased our capacity to identify target populations for control or intervention, and has provided detailed information on the mechanisms of insecticide resistance. However, the genetics and evolutionary biology of hosts, pathogens and vectors have tended to develop as three separate fields of research. This artificial compartmentalisation is of concern due to our growing appreciation of the strong co-evolutionary interactions among hosts, pathogens and vectors. Infection, Genetics and Evolution and its companion congress [MEEGID](http://www.meegidconference.com/) (for Molecular Epidemiology and Evolutionary Genetics of Infectious Diseases) are the main forum acting for the cross-fertilization between evolutionary science and biomedical research on infectious diseases. Infection, Genetics and Evolution is the only journal that welcomes articles dealing with the genetics and evolutionary biology of hosts, pathogens and vectors, and coevolution processes among them in relation to infection and disease manifestation. All infectious models enter the scope of the journal, including pathogens of humans, animals and plants, either parasites, fungi, bacteria, viruses or prions. The journal welcomes articles dealing with genetics, population genetics, genomics, postgenomics, gene expression, evolutionary biology, population dynamics, mathematical modeling and bioinformatics. We also provide many author benefits, such as free PDFs, a liberal copyright policy, special discounts on Elsevier publications and much more. Please click here for more information on our author services .