Quantitative Proteomics Analysis of Plasmodium vivax Induced Alterations in Human Serum during the Acute and Convalescent Phases of Infection.

The radial distribution of Plasmodium vivax malaria burden has evoked enormous concern among the global research community. In this study, we have investigated the serum proteome alterations in non-severe vivax malaria patients before and during patient recuperation starting from the early febrile to the defervescence and convalescent stages of the infection. We have also performed an extensive quantitative proteomics analysis to compare the serum proteome profiles of vivax malaria patients with low (LPVM) and moderately-high (MPVM) parasitemia with healthy community controls. Interestingly, some of the serum proteins such as Serum amyloid A, Apolipoprotein A1, C-reactive protein, Titin and Haptoglobin, were found to be sequentially altered with respect to increased parasite counts. Analysis of a longitudinal cohort of malaria patients indicated reversible alterations in serum levels of some proteins such as Haptoglobin, Apolipoprotein E, Apolipoprotein A1, Carbonic anhydrase 1, and Hemoglobin subunit alpha upon treatment; however, the levels of a few other proteins did not return to the baseline even during the convalescent phase of the infection. Here we present the first comprehensive serum proteomics analysis of vivax malaria patients with different levels of parasitemia and during the acute and convalescent phases of the infection.

Proteomics of Plasmodium vivax malaria: new insights, progress and potential.

INTRODUCTION: Plasmodium vivax has accounted for an enormous share of the global malaria burden in recent years, along with Plasmodium falciparum. The wide distribution of P. vivax and recent evidences of severe and complicated vivax malaria across several endemic regions of the world suggest that this disease may have been more overlooked than benign. While P. falciparum has been extensively studied, P. vivax has received limited research attention owing to its complex nature and absence of a continuous culture system. AREAS COVERED: This review briefly describes the epidemiology of vivax malaria, analyzes challenges towards effective control and summarizes major insights provided by genomics and transcriptomics research in the area. Subsequently, the review provides a detailed description of the applications of proteomics in vivax malaria research, focusing on both host responses and parasite proteomics studies to understand P. vivax biology. Expert commentary: In recent years, proteomics technologies are being used effectively to understand P. vivax biology and the underlying pathogenesis. Technological advances in mass spectrometry configurations, multiomics investigations and emerging strategies such as targeted proteomics may also immensely aid in studying disease severity, improving existing diagnosis and identifying new drug and vaccine targets.

Clinicopathological Analysis and Multipronged Quantitative Proteomics Reveal Oxidative Stress and Cytoskeletal Proteins as Possible Markers for Severe Vivax Malaria.

In Plasmodium vivax malaria, mechanisms that trigger transition from uncomplicated to fatal severe infections are obscure. In this multi-disciplinary study we have performed a comprehensive analysis of clinicopathological parameters and serum proteome profiles of vivax malaria patients with different severity levels of infection to investigate pathogenesis of severe malaria and identify surrogate markers of severity. Clinicopathological analysis and proteomics profiling has provided evidences for the modulation of diverse physiological pathways including oxidative stress, cytoskeletal regulation, lipid metabolism and complement cascades in severe malaria. Strikingly, unlike severe falciparum malaria the blood coagulation cascade was not found to be affected adversely in acute P. vivax infection. To the best of our knowledge, this is the first comprehensive proteomics study, which identified some possible cues for severe P. vivax infection. Our results suggest that Superoxide dismutase, Vitronectin, Titin, Apolipoprotein E, Serum amyloid A, and Haptoglobin are potential predictive markers for malaria severity.