Vivek Bhakta Mathema, Kesara Na-BangchangChulabhorn International College of Medicine, Thammasat University, Klonglung, PathumThani, Thailand

A brief review on biomarkers and proteomic approach for malaria research

Vivek Bhakta Mathema, Kesara Na-Bangchang*
Chulabhorn International College of Medicine, Thammasat University, Klonglung, PathumThani, Thailand

ARTICLE INFO

Article history:

Received 15 January 2015

Received in revised form 20 February 2015

Accepted 15 March 2015

Available online 20 April 2015

Biomarkers

Malaria

Plasmodium

Proteomics

Malaria remains as one of the significant health threat to people living in countries throughout tropical and subtropical zones. Proteomic studies of Plasmodium, the protozoan causing malaria, is essential for understanding its cellular structure, growth stage-specific expression of protein metabolites and complex interaction with host. In-depth knowledge of the pathogen is required for identification of novel biomarkers that can be utilized to develop diagnostic tests and therapeutic antimalarial drugs. The alarming rise in drug-resistant strains of Plasmodium has created an urgent need to identify new targets for drug development that can act by obstructing life cycle of this parasite. In the present review, we briefly discuss on role of various biomarkers including Plasmodium-associated aldolase, histidine-rich proteins and lactate dehydrogenase for diagnosis of malaria. Here we also summarize the present and future prospects of currently used techniques in proteomic approaches such as two dimensional gel electrophoresis and matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) for diagnosis and potential identification of novel proteins for malaria research.

1. Introduction

Malaria is an ancient vector-borne disease of humans and other primates caused by a highly complex protozoan belonging to the genus Plasmodium[1,2]. Female Anopheles mosquitoes are insect vector for transmitting the disease in humans. The disease is endemic to more than 100 countries throughout tropical and subtropical zones. Recently, the world malaria report released by world health organization has estimated that around 3.4 billion people are at risk of malaria and about 207 million cases of malaria occurred globally during 2013[3]. In Africa significant numbers of child death has been directly attributed to malaria. A research suggests that majority of malaria-associated deaths globally were children less than 5 years of age from sub-Saharan Africa[4]. Nonetheless, even after several decades of the disease control campaigns, malaria persists as one of the most serious public health problem not only in endemic countries but also in non-endemic regions where the increasing number of imported malaria cases via tourists and immigrants are on the rise[5].

Four species of the pathogen namely: Plasmodium vivax (P. vivax), Plasmodium falciparum (P. falciparum), Plasmodium malariae, and Plasmodium ovale (P. ovale) are highly distributed among malariaaffected regions in the world. In addition, recently discovered Plasmodium knowlesi-associated zoonotic form of human malaria in Southeast Asia is also creating serious concerns among pathologist and epidemiologists[6]. Among the species, P. falciparum accounts almost all of the malaria-associated mortality[7,8]. Malarial pathogen has exceptional ability to adopt and maintain a complex parasite life cycle in both humans and Anopheles spp. with several morphologically and functionally distinct extra- and intra-cellular stages. In addition, mutational selection resulting into drug resistant strains of the parasite, the spread of insecticide resistant mosquitoes and lack of effective vaccines against the Plasmodium spp. are some of the critical barriers preventing eradication of this disease[9].

Morbidity and mortality caused by the disease is exclusively

associated with the erythrocytic stage of infection where the pathogen continuously undergoes intracellular development and reinvasion into red blood cells (RBCs) resulting in exponential parasite proliferation. If untreated, the disease progressively causes severe haemopenia, kidney failure, mental confusion,seizures, coma, and death[10,11]. Multiple neurological complications and cognitive deficits can arise specially during cerebral malaria as the parasite can also infect brain. In addition, the parasite is known to constantly develop resistance against antimalarial drugs making it more difficult to cure the disease[12]. Hence, it is clear that early diagnosis and prophylaxis has a major role in preventing malaria-associated mortality. Even though several rapid detection tests (RDTs) and kits are available for screening malaria infection, their efficiency and accuracy are still questionable. Thus, there is a growing need for exploring new detection techniques that are highly sensitive and portable for early identification of malaria. In this context, an indepth study of potential biomarkers associated with malaria pathogen can be crucial for identification of a suitable biorecognition element and its implementation for devising a robust and reliable diagnosis technique for early detection of the disease. Here, we briefly discuss on the current prospect and future potential of biomarkers and different proteomic approaches that can be used for malaria research.

2. Drugs used for treatment of malaria

Parasite causing malaria exhibits astonishing adoption abilities and due to prevalence of several species, strains, and variants the treatment of malaria is not always easy. Even today, the choice of drugs for effective medication is quite limited and drug resistant strains of this pathogen are on the rise[12,13]. The drug of choice Aralen (Chloroquine phosphate) is effective for all malarial parasites except for chloroquine-resistant Plasmodium strains[9]. Traditional medication for P. falciparum-mediated malaria involved the use of sulphadoxine-pyrimethamine (SP) or chloroquine. However, the over-dependence and excess use of both quinoline compounds (amodiaquine, chloroquine, mefloquine, and quinine) and antifolatedrugs (chlorproguanil, sulphonamides, and pyrimethamine) have led to cross-resistance among these compounds[14,15]. Emergence of such resistant strains of P. falciparum has motivated to switch towards new class of artemisinin-derived antimalarial compounds. Currently, the artemisinin-derived combination therapies (ACTs) which involves use of artemisinin derivatives in combination with other traditional antimalarial drugs, is regarded as the best treatment option[16]. For P. vivax and P. ovale which are known to possess dormant stages and can cause relapses, primaquine is often administered in addition to ACTs. Unfortunately, any therapy is not always guaranteed to work against the disease since several strains of the parasite resistant even to ACTs have been reported in different parts of the world[16,17]. Although several strategies and multiple drug treatment protocols do exist to prevent drug resistant malaria, detecting the disease at its early stage remains vital for the successful treatment. Hence, in this scenario the importance of biomarkerbased technique for timely diagnosis of the disease becomes more essential.

3. Role of biomarkers in malaria diagnosis

Biomarkers can be defined as any measurable changes for molecular, biochemical or cellular alternations in biological samples that can indicate biological, pathological or therapeutic responses[18]. Possibility to detect certain biomarkers for Plasmodium-mediated infection at early stages of malaria can be crucial for formulating disease management strategies and choosing correct prophylaxis for the disease[19]. Typically for the endemic zones of Africa where asymptomatic malaria is rampant, such biomarker-based detection techniques combined with proper treatment strategies may significantly help deplete human reservoirs of the parasite that frequently contributing to persistence of malaria transmission in such areas[19-21]. Current advancement in proteomics and immunotechnology has provided vital tools for in-depth study and analysis of different human body fluids including saliva, urine, and serum. In general, analysis of proteome from such fluids provides a valuable resource for the identification of potential disease-related markers. The host immune response against the disease condition can exhibit rapid alteration in expression pattern unique for a pathogen which may be directly correlated with disease progression at its early state[22]. The use of biomarkers provides us with sensitive and effective means for investigation of disease pathogenesis. Currently, several malaria-associated biomarkers have been utilized for the disease identification and few of them are briefly described below.

3.1. P. falciparum lactate dehydrogenase (PfLDH)

Plasmodium is a voracious scavenger of blood glucose that can force the RBC to increase glucose consumption up to 100-fold during intraerythrocytic cycle. Microarray experiments using P. falciperum transcriptome has shown that all enzymes in glycolytic pathway are significantly upregulated during early trophozoite stage correlating with the high metabolic state of the pathogen at this particular stage of its asexual life-cycle[23]. In particular, the enzymes involved in energy metabolism during the intraerythrocytic stages of the parasite lack a functional citric acid cycle, and production of ATP depends fully on the glycolytic pathway[24]. Among other enzymes, the pathogen seems to principally rely on PfLDH as its essential enzyme in glycolytic pathway to convert pyruvate into lactate[25]. The PfLDH RNA expression level gradually increases and reaches its peak within 24 to 30 hours of infection during the intraerythrocytic cycle. This expression subsequently declines tozero in the schizont stage[20,26]. Since the Plasmodium LDH (pLHD)

3.2. Histidine-rich proteins (HRPs)

The HRPs relating to Plasmodium were first discovered during the analysis of cytoplasmic granules from the avian malaria parasite Plasmodium lophurae. The polypeptides in granules contained abnormally high levels of histidine reaching upto 73% in total[33]. There are three major types of HRPs associated with Plasmodium parasite and named according to the order of their discovery[24,34]. The HRP1 is basically aKnob-associated protein present in Knobpositive strains of the parasite and is known to assist coadhereance of infected erythrocyte to venular endothelial cells[20,35]. The HRP2 is regarded as a vital biomarker unique to P. falciparium and is present in both Knob-positive and -negative strains of the parasite that causes the most severe form of malaria[36]. The P. falciparum HRP2 (PfHRP2) is known to exhibit many functions including tightly binding with glycosaminoglycans (heparan sulfate,dermatan sulfate, and heparin) causing inhibition of antithrombin and detoxification of heme by forming haemozoin[2]. HRP2 has remained one of the prime targets for development of antimalarial drugs and rapid diagnostictests (RDTs) as evidence shows that PfHRP2-based assays are more sensitive towards detection of P. falciparum than aldolaseand LHD-based diagnostic tests[37]. However, the P. falciparum from Asia-Pacific region is known to express high variability in PfHRP2, which has posed significant difficulty for the development of efficient malaria RDTs development[38]. Lastly, the HRP3 is not as common as HRP1 and HRP2. P. falciparum HRP3 (PfHRP3) is a small histidine-rich protein (SHARP) that shares several structural homology with PfHRP2. It has been suggested that both PfHRP2 and PfHRP3 were derived from duplication and interchromosomal divergence from a common ancestral gene[38-40]. Due to structural homology, several antibodies against PfHRP2 are known to cross-react with PfHRP3, and thus contributing to the detection of P. falciparum[41,42]. Overall, the Plasmodium-associated HRPs constitute a prominent biomarker for malaria diagnosis.

3.3. Haemozoin

Haemozoin is often known as malaria pigment as it is a visible marker in detection of malarial parasite. It is a non-toxic insoluble microcrystalline by-product formed by polymerizing free-toxic heme after digestion of haemoglobulin by Plasmodium and some other RBC-feeding parasites[10,43,44]. Several currently available antimalarial drugs including mefloquine and chloroquine act by blocking the haemozoin biocrystallization that kills malaria parasite[45]. Even though the exact process for formation of haemozoin is barely understood, the HRP2 is suggested to assist initiation of haemozoin formation by firmly binding to heme molecules and initiating their polymerization. However other haemozoin synthesis mechanism based on neutral lipid bodies and polar membrane lipids have also been reported[46-48]. As the haemozoin formation is crucial for the parasite survival, it has therefore become a prominent target for antimalarial drug development.

3.4. Plasmodium aldolase

Proteins and enzymes associated with the glycolytic pathways of the Plasmodium has remained a prime focus for parasite detection and antimalarial drug development. Aldolase has a vital role in cleavage of fructose-1,6-bisphosphate into glyceraldehyde-3-phosphate and dihydroxyacetone phosphate in the glycolytic pathway of the parasite. The Plasmodium aldolase is a homotetrameric in nature with each subunit of approximately 40 kDa[49]. Unlike vertebrates which comprise three tissue-specific aldolase enzymes, the P. vivax and P. falciparum contain only one type of aldolase isozyme. The enzyme is 369 amino acids in length and their nucleotide and amino acid sequences are relatively conserved[50,51]. The enzyme can be found either as an insoluble membrane-bound aldolase or localized in cytoplasm of the parasite as an active and soluble form[49]. The plasticity of active-site region and multimeric nature of the enzyme is also suggested for its intriguing non-enzymatic activity for assisting the invasion machinery of the malaria parasite[52]. The Plasmodium aldolase exhibits drastic difference from the host enzyme and thus has been utilized in several commercially available RDTs. Even though several reports have suggested that aldolase-based diagnostic tests provide relatively lower sensitivity as compared to HRPsbased tests, the enzyme remains a vital target for disease diagnosis and drug development[53]. Thus, the Plasmodium aldolase has been regarded as prominent biomarker in malaria research.

3.5. Glutamate dehydrogenase (GDHs)

The GDHs are ubiquitous enzymes responsible for the reversible

初始设计的RBF神经网是不能够正常工作的，需要采集适当的样本数据对网络进行适当训练。较多的样本数据可以更好地表现原始数据的特性，但会增大网络的训练时间；而过少的样本数据不能反应数据的原始特性，训练出来的网络泛化性会降低，因此，样本数的选择应能体现数据的特性且不宜过多。在0～20 mm全量程范围内，根据间隙值均等分布的原则选取41个数据样本点，并对其进行归一化处理以方便RBF网络计算，样本数据如图5所示。图5中，选取样本中均等分布的21个样本点作为训练样本，在网络参数优化学习时使用；选取其余20个样本点作为测试集来验证网络对陌生样本预测时的泛化性能。

oxidative deamination of L-glutamate for production of α -ketoglutarate and ammonia utilizing NAD (H) or NADP (H) as co-factors[54]. The enzyme serves as a branching point of nitrogen-carbon metabolism as it can either assimilate ammonia and provides glutamate for storage of nitrogen or dissimilates ammonia and generates α-ketoglutarate as a feed for tricarboxylic acid metabolism. Since malaria parasite exhibits different isoforms of GDHs, these enzymes are considered as an important biomarker for malaria diagnosis.Both NADP- and NAD-dependent GHDs are present in Plasmodium. In particular, the P. falciparum exhibits three types of isozymes encoding GDHs. Two genes gdha and gdhb encoding potential GDHs are located in chromosome 14 and the third gene gdhc is present in chromosome 8[7,54]. The Plasmodium GDHs contains N-terminal residue unique to the parasite that is present throughout intra-erythrocytic cycle of the pathogen. As RBCs do not contain GDHs, it can potentially serve as a biomarker for disease diagnosis[55,56]. Techniques involving western blotting, immunochromatographic assays have been utilized to detect the parasite utilizing GDHs[8,57]. Hence, the GDHs may be considered as a significantly important disease-associated biomarker for malaria diagnosis and treatment.

4. Role of proteomics in malaria research

Proteome generally refers to the entire set of proteins belonging to a cell or an organism which can vary with time depending on distinct requirements or stresses that it endures[58]. Proteomics provides necessary tools for large-scale experimental analysis of the proteome for generating data on relevant protein sets from pathogen and the host[59]. This information can help understand the hostparasite relation in context to the structures, specific expressions, and functions of the proteins. The past decade has witnessed astonishing increase in study and global shearing of knowledge on Plasmodium proteome leading to establishment of global protein database of malaria parasite[60]. This has significantly helped researchers by assisting identification of potential targets for antimalarial drugs that specifically interrupt the host-parasite interaction and thus prevent disease development[61]. Reports have suggested that the survival of malaria parasite requires tight regulation of several proteins during different stages of its life-cycle in both vertebrate and invertebrate host[1,61]. However, most of today's modern technologies in proteomics for detection and prevention of malaria are focused on intra-erythrocytic stage of the parasite life-cycle which is the major cause of malaria-associated mortalities[59]. Thus, the techniques that can be applicable both for research and clinical diagnosis of malaria are of immense importance for combating this disease.Some of the major modern proteomics-based approaches for research on pathogenesis and diagnosis of Plasmodium infection are summarized below.

4.1. One dimension sodium dodecyl sulphate-polyacrylamide gel electrophoresis (1D SDS-PAGE) approach in malaria research

Proteomic approach requires identification and ascertaining the protein population that are differentially expressed and also detection of any post-translational modifications that occur during each stage of parasites life-cycle[11,62]. The1D SDS-PAGE is a widely used technique in molecular biology to separate biological macromolecules, usually proteins or nucleic acids (Figure 1). The technique has been frequently employed for separating and analyzing various protein fractions from trophozoite stage of P. flaciparum[11]. In addition, it has also been used for identification of phosphorylated protein pattern by separation of phosphoproteome of P. falciparum parasitized RBCs[63]. The method has application in protein separation for detection of distinct patterns of bloodstage Plasmodium antigens using plasma immunoglobulin-G (IgG) subclasses from individuals with different level of exposure to P. falciparum infections[64]. The 1D-SDS PAGE has remained a welladopted method for separating the protein fractions derived from Plasmodium-infected samples to enhance sensitivity and resolution of protein identification prior to mass spectrometry[63,65]. Taken together, the 1D SDS-PAGE presents itself as a simple yet highly applicable technique for study of malaria proteomics.

4.2. Two dimensional SDS-PAGE (2D SDS-PAGE) approach in malaria research

The 2D SDS PAGE is a widely used two-dimensional gel electrophoresis (2-DE) technique for investigating P. vivax and P. falciparum infected blood samples[66,67]. It is also one of the most commonly used methods for obtaining a snapshot of proteome at the specific time of infection. A basic schematic of the assay is given in Figure 2. Customized forms of 2D SDS-PAGE has been utilized as a semiquantative gel electrophoresis technique for assisting proteomic profiling of P. falciparum[68]. In addition, the mass spectrometrybased techniques such as matrix-assisted laser desorption/ionization time of flight (MALDI-TOF) preferentially require the samples to be pre-processed using 2D SDS-PAGE for analyzing the bimolecular content in high resolution[63,69]. Moreover, the first pioneering study on protein maps from proteomes of merozoites and schizonts of P. falciparum were obtained utilizing 2D-PAGE and mass spectrometry[70,71]. Recently, the 2D SDS-PAGE approach along with immunoflurosence assay has been utilized to identify and investigate the expression and localization of a relatively conserved heat shock protein in malaria parasite[72]. Likely, in a separate report, the 2-DE has been implemented as a method of choice for proteomic approach to study malaria by investigating protein expression pattern in P. falciparium under treatment of antiplasmodial drug such as quinine and mefloquine[73]. Thus, is it clear that 2-DE serves as an essential tool for malaria research with proteomic approach.

4.3. Liquid chromatography-tandem mass spectrometry (LCMS/MS)

The LC-MS/MS is basically a hybrid analytical technique that contains physical separation capabilities of high performance liquid chromatography (HPLC) to fractionate the samples into individual analytes while retaining mass analysis capabilities of tandem mass spectrometry to quantitate these analytes[74]. A generalized schematic of the technique is given in Figure 3. The quest for rapid screening of multi-biomarker profiles for various diseases diagnosis has led to increasing use of LC-MS/MS for both clinical and research purpose[75]. The technology enables researcher to undertake advance proteomic approaches by investigating large-scale protein expression profiles with high accuracy for complex organism like Plasmodium. The LC-MS/MS in combination with 1D-SDS PAGE has previously been used for proteomic analysis of salivary gland proteins extracted from urban malaria vector Anopheles stephensi[76]. Similarly, the technique has also been employed for investigation of the P. vivax schizont stage proteome in humans for identification of immunogenic proteins that may hold therapeutic potentials[62]. Their computational research data provided first direct insight into identification and functional characterization of salivary proteins[76]. LC-MS/MS analysis of P. falciparum extracellular secretory proteins produced during asexual blood stages of parasite has assisted in revealing numerous proteins potentially involved in host immune modulation and signaling[77]. In addition, the technique has also been utilized for study of plasma and cerebrospinal proteomes from children acquiring cerebral malaria for better understanding of pathogenesis and helps develop more-specific diagnostic methods[78]. Hence, the technique can be regarded as a rapid yet highly efficient tool for large-scale proteomic analysis for malaria.

4.4. MALDI-TOF

The technique is based on ionization of biomolecules, generally proteins, in samples, followed by analysis of its constituent using specially designed mass spectrometric equipment that utilizes high energy collision-induced dissociation to investigate amino acid sequence of peptides[79]. Figure 4 represents generalized schematics of MALDI-TOF mass spectrometry (MS). Due to its accuracy, speed and cost effectiveness, the technique has been successfully employed as an identification procedure in clinical microbiology and also widely implemented in routine laboratory practices[79,80]. The technique along with SDS-PAGE has been applied for characterization of the P. vivax erythrocytic stage proteome and identification of a relatively stable protein PV180L as a potent immunogenic antigen during the erythrocytic cycle of malaria parasite[81]. Previously, it was reported that the method had been employed to assist analysis of recombinant P. vivax merozoite surface antigen protein that was allowed to be expressed in Escherichia coli for malaria vaccine development research[82]. Recently, MALDI-TOF has been employed for rapid identification of Anopheles mosquitoes from its leg protein samples and has been able to generate several sets of biomarkers for its precise identification[83]. The P. falicaprum and P. vivax proteomes subjected to MALDI-TOF analysis have revealed several proteins that are differentially expressed and are potentially important for studying disease pathogenesis[66]. In a separate report, the technology has been applied to assist identification and extend the knowledge on redox proteins such as pthioredoxin, glutaredoxin and plasm oredoxin for better understanding of redox interactome in malarial parasites[84]. Thus, reports presented here clearly demonstrate that MALDI-TOF is a relevant tool for studying malaria proteomics and opens new avenues for both clinical diagnosis and experimental antimalarial drug development.

4.5. Surface-enhanced laser desorption/ionization time of flight (SELDI-TOF)

The SELDI-TOF MS is a modified form of MALDI-TOF that

utilizes target surface modified to achieve biochemical affinity and selectively analyze samples based on their affinity towards the surface matrix[85,86]. Generalized schematic of the technique is given in Figure 5. One of the obvious advantages of this surfaceenhanced process is that components, such as salts or detergents that commonly cause problems with other analytical tools, are removed prior to analysis[87]. The technology is characterized by its rapid diagnostic capabilities that can be applied to study proteomes to discover biomarkers associated with parasitic diseases which may include host proteins or protein fragments derived from parasite or host, in body fluids or tissues following infection[88]. In comparison with other proteomic techniques, SELDI-TOF has several key advantages including ability to analyze complex biological samples with minimal pre-processing, ease of handling, and high throughput[86]. The method had been used for protein expression profiling to identify chloroquine resistance markers in P. falciparium strains resistant to chloroquine[9]. Recently, the SELDITOF has been used to identify hepcidin, a hepatocyte-associated protein having a function of sequestration of iron, from blood plasma for its possible role in anti-inflammatory response in childhood malaria[89]. The technique has been employed for determining urinary hepcidin in malaria patient suffering from uncomplicated P. falciparum infection to study the relationship between parasitemia and anemia[90]. Moreover, the level of sophistication behind this technology has assisted researchers in proteomics to explore previously uncharted conditions in patients chronically infected with blood-borne protozoan parasites including malaria[88,91]. Thus, it is clearly evident that the protein expression profiling approach using SELDI-TOF provides a useful tool for understanding the proteome of malarial parasites.

5. Conclusion

The advancement in techniques for investigating proteome of Plasmodium and identification of potential biomarkers has undoubtedly widened our knowledge on malaria research. Protein profiling and characterization of stage-specific proteome of the parasite has helped researchers to reveal numerous novel molecules that may hold significant potential for targeted therapeutic drug development.The level of sophistication and sensitivity offered by current technologies for proteomic studies can help researcher to deeply explore the malaria pathogenesis and possibly assist identification of new targets and strategies for devising reliable diagnostic tests. Overall, the review provides a brief overview on the current scenario and future prospects of malaria biomarkers and various proteomic approaches used for malaria research.

Conflict of interest statement

We declare that we have no conflict of interest.

Acknowledgements

This study was supported by Chulabhorn International College of Medicine, Thammasat University, Thailand.

[1] Florens L, Washburn MP, Raine JD, Anthony RM, Grainger M, Haynes JD, et al. A proteomic view of the Plasmodium falciparum life cycle. Nature 2002; 419: 520-526.

[2] Ndonwi M, Burlingame OO, Miller AS, Tollefsen DM, Broze GJ Jr, Goldberg DE. Inhibition of antithrombin by Plasmodium falciparum histidine-rich proteinⅡ. Blood 2011; 117: 6347-6354.

[3] World Health Organization. World malaria report. Geneva: WHO; 2013.

[Online] Available from: http://www.who.int/iris/bitstream/10665/97008/ 1/9789241564694_eng.pdf.

[4] Black RE, Cousens S, Johnson HL, Lawn JE, Rudan I, Bassani DG, et al. Global, regional, and national causes of child mortality in 2008: a systematic analysis. Lancet 2010; 375: 1969-1987.

[5] World Health Organization. World malaria report. Geneva: WHO; 2010. Press; 2010. [Online] Available from http://www.who.int/malaria/world_ malaria_report_2010/world_malaria_report_2010.pdf.

[6] Antinori S, Galimberti L, Milazzo L, Corbellino M. Plasmodium knowlesi: the emerging zoonotic malaria parasite. Acta Trop 2013; 125: 191-201.

[7] Gardner MJ, Hall N, Fung E, White O, Berriman M, Hyman RW, et al. Genome sequence of the human malaria parasite Plasmodium falciparum. Nature 2002; 419: 498-511.

[8] Li Y, Ning YS, Li L, Peng DD, Dong WQ, Li M. Preparation of monoclonal antibodies against Plasmodium falciparum glutamate dehydrogenase and establishment of colloidal goldimmunochromatographic assay. Di Yi Jun Yi Da Xue Xue Bao 2005; 25: 435-438.

[9] Koncarevic S, Bogumil R, Becker K. SELDI-TOF-MS analysis of chloroquine resistant and sensitive Plasmodium falciparum strains. Proteomics 2007; 7: 711-721.

[10] Pisciotta JM, Ponder EL, Fried B, Sullivan D. Hemozoin formation in Echinostoma trivolvisrediae. Int J Parasitol 2005; 35: 1037-1042.

[11] Oehring SC, Woodcroft BJ, Moes S, Wetzel J, Dietz O, Pulfer A, et al. Organellar proteomics reveals hundreds of novel nuclear proteins in the malaria parasite Plasmodium falciparum. Genome Biol 2012; 13: R108.

[12] Na-Bangchang K. Pharmacodynamics of antimalarial chemotherapy. Expert Rev Clin Pharmacol 2009; 2: 491-515.

[13] Na-Bangchang K, Muhamad P, Ruaengweerayut R, Chaijaroenkul W, Karbwang J. Identification of resistance of Plasmodium falciparum to artesunate-mefloquine combination in an area along the Thai-Myanmar border: integration of clinico-parasitological response, systemic drug exposure, and in vitro parasite sensitivity. Malar J 2013; 30(12): 263.

[14] World Health Organization. Drug resistance in malaria. Geneva: WHO; 2001. [Online]Available from http://www.who.int/csr/resources/ publications/drugresist/malaria.pdf.

[15] Ross LS, Gamo FJ, Lafuente-Monasterio MJ, Singh OM, Rowland P, Wiegand RC, et al. In vitro resistance selections for Plasmodium falciparum dihydroorotate dehydrogenase inhibitors give mutants with multiple point mutations in the drug-binding site and altered growth. J Biol Chem 2014; 289: 17980-17995.

[16] Abiodun OO, Brun R, Wittlin S. In vitro interaction of artemisinin derivatives or the fully synthetic peroxidic anti-malarial OZ277 with thapsigargin in Plasmodium falciparum strains. Malaria J 2013; 12: 43.

[17] Taylor SM, Juliano JJ. Artemisinin combination therapies and malaria parasite drug resistance: the game is afoot. J Infect Dis 2014; 210: 335-337.

[18] Hulka BS. Overview of biological markers. In: Biological markers in epidemiology. Hulka BS, Griffith JD, Wilcosky TC, eds. New York: Oxford University Press; 1990, p. 3-15.

[19] Dal-Bianco MP1, Köster KB, Kombila UD, Kun JF, Grobusch MP, Ngoma GM, et al. High prevalence of asymptomatic Plasmodium falciparum infection in Gabonese adults. Am J Trop Med Hyg 2007; 77: 939-942.

[20] Jain P, Chakma B, Patra S, Goswami P. Potential biomarkers and their applications for rapid and reliable detection of malaria. Biomed Res Int 2014; doi: 10.1155/2014/852645.

[21] Zoghi S1, Mehrizi AA, Raeisi A, Haghdoost AA, Turki H, Safari R, et al. Survey for asymptomatic malaria cases in low transmission settings of Iran under elimination programme. Malar J 2012; 11:126.

[22] Ray S, Reddy PJ, Jain R, Gollapalli K, Moiyadi A, Srivastava S. Proteomic technologies for the identification of disease biomarkers in serum: advances and challenges ahead. Proteomics 2011; 11: 2139-2161.

[23] Bozdech Z, Llinás M, Pulliam BL, Wong ED, Zhu J, DeRisi JL. The transcriptome of the intraerythrocytic developmental cycle of Plasmodium falciparum. PLoS Biol 2003; 1: E5.

[24] Moody A. Rapid diagnostic tests for malaria parasites. Clin Microbiol Rev 2002; 15: 66-78.

[25] Jensen MD, Conley M, Helstowski LD. Culture of Plasmodium falciparum: the role of pH, glucose, and lactate. J Parasitol 1983; 69: 1060-1067.

[26] Pfaller MA, Krogstad DJ, Parquette AR, Nguyen-Dinh P. Plasmodium falciparum: stage-specific lactate production in synchronized cultures. Exp Parasitol 1982; 54: 391-396.

[27] Winter VJ, Cameron A, Tranter R, Sessions RB, Brady RL. Crystal structure of Plasmodium berghei lactate dehydrogenase indicates the unique structural differences of these enzymes are shared across the Plasmodium genus. Mol Biochem Parasitol 2003; 131: 1-10.

[28] Brown WM, Yowell CA, Hoard A, Vander Jagt TA, Hunsaker LA, Deck LM, et al. Comparative structural analysis and kinetic properties of lactate dehydrogenases from the four species of human malarial parasites. Biochemistry 2004; 43: 6219-6229.

[29] Bzik DJ, Fox BA, Gonyer K. Expression of Plasmodium falciparum lactate dehydrogenase in Escherichia coli. Mol Biochem Parasitol 1993; 59: 155-166.

[30] Hurdayal R, Achilonu I, Choveaux D, Coetzer TH, Dean Goldring JP. Anti-peptide antibodies differentiate between plasmodial lactate dehydrogenases. Peptides 2010; 31: 525-532.

[31] Shoemark DK, Cliff MJ, Sessions RB, Clarke AR. Enzymatic properties of the lactate dehydrogenase enzyme from Plasmodium falciparum. FEBS J 2007; 274: 2738-2748.

[32] Hewitt CO, Eszes CM, Sessions RB, Moreton KM, Dafforn TR, Takei J, et al. A general method for relieving substrate inhibition in lactate dehydrogenases. Protein Eng 1999; 12: 491-496.

[33] Kilejian A. A unique histidine rich polypeptide from the malaria parasite, Plasmodium lophurae. J Biol Chem 1974; 249: 4650-4655.

[34] Howard RJ, Uni S, Aikawa M, Aley SB, Leech JH, Lew AM, et

al. Secretionofa malarial histidine-rich protein (Pf HRP Ⅱ) from Plasmodium falciparum-infected erythrocytes. J Cell Biol 1986; 103: 1269-1277.

[35] Pologe LG, Pavlovec A, Shio H, Ravetch JV. Primary structure and subcellular localization of the knob-associated histidine-rich protein of Plasmodium falciparum. Proc Natl Acad Sci U S A 1987; 84: 7139-7143.

[36] Kifude CM, Rajasekariah HG, Sullivan DJ, Stewart VA, Angov E, Martin SK, et al. Enzyme-linked immunosorbent assay for detection of Plasmodium falciparum histidine-rich protein 2 in blood, plasma, and serum. Clin Vaccine Immunol 2008; 15:1012-1018.

[37] Iqbal J, Khalid N, Hira PR. Comparison of two commercial assays with expert microscopy for confirmation of symptomatically diagnosed malaria. J Clin Microbiol 2002; 40: 4675-4678.

[38] Baker J, Ho MF, Pelecanos A, Gatton M, Chen N, Abdullah S, et al. Global sequence variation in the histidine-rich proteins 2 and 3 of Plasmodium falciparum: implications for the performance of malaria rapid diagnostic tests. Malar J 2010; 9: 129.

[39] Kemp DJ, Thompson JK, Walliker D, Corcoran LM. Molecular karyotype of Plasmodium falciparum: conserved linkage groups and expendable histidine rich protein genes. Proc Natl Acad Sci U S A 1987; 84: 7672-7676.

[40] Wellems TE, Walliker D, Smith CL, do Rosario VE, Maloy WL, Howard RJ, et al. A histidine rich protein gene marks a linkage group favoured strongly in a genetic cross of Plasmodium falciparum. Cell 1987; 49: 633-642.

[41] Wellems TE, Howard RJ. Homologous genes encode two distinct, histidine rich proteins in a cloned isolate of Plasmodium falciparum. Proc Natl Acad Sci U S A 1986; 83: 6065-6069.

[42] Sharma YD. Genomic organization, structure and possible function of histidine rich proteins of malaria parasites. Int J Biochem 1988; 20: 471-477.

[43] Yao MX, Wang H. Hemozoin detection in malaria diagnosis. Zhongguo Ji Sheng Chong Xue Yu Ji Sheng Chong Bing ZaZhi 2014; 32: 68-71.

[44] Chen MM1, Shi L, Sullivan DJ Jr. Haemoproteus and Schistosoma synthesize heme polymers similar to Plasmodium hemozoin and betahematin. Mol Biochem Parasitol 2001; 113: 1-8.

[45] Hempelmann E. Hemozo in biocrystallization in Plasmodium falciparum and the antimalarial activity of crystallization inhibitors. Parasitol Res 2007; 100: 671-676.

[46] Bendrat K, Berger BJ, Cerami A. Haem polymerization in malaria. Nature 1995; 378: 138-139.

[47] Jackson KE, Klonis N, Ferguson DJ, Adisa A, Dogovski C, Tilley L. Food vacuole-associated lipid bodies and heterogeneous lipid environments in the malaria parasite, Plasmodium falciparum. Mol Microbiol 2004; 54: 109-122.

[48] Pisciotta JM, Coppens I, Tripathi AK, Scholl PF, Shuman J, Bajad S, et al. The role of eutral lipid nanospheres in Plasmodium falciparum haem crystallization. Biochem J 2007; 402: 197-204.

[49] Döbeli H, Trzeciak A, Gillessen D, Matile H, Srivastava IK, Perrin LH, et al. Expression, purification, biochemical characterization and inhibition of recombinant Plasmodium falciparum aldolase. Mol Biochem Parasitol 1990; 41: 259-268.

[50] Cloonan N, Fischer K, Cheng Q, Saul A. Aldolase genes of Plasmodium species. Mol Biochem Parasitol 2001; 113: 327-330.

[51] Lee N, Baker J, Bell D, McCarthy J, Cheng Q. Assessing the Genetic Diversity of the Aldolase genes of Plasmodium falciparum and Plasmodium vivax and its potential effect on performance of aldolasedetecting rapid diagnostic tests. J ClinMicrobiol 2006; 44: 4547-4549.

[52] Bosch J, Buscaglia CA, Krumm B, Ingason BP, Lucas R, Roach C, et al. Aldolase provides an unusual binding site for thrombospondin-related anonymous protein in the invasion machinery of the malaria parasite. Proc Natl Acad Sci U S A 2007; 104: 7015-7020.

[53] Hendriksen IC, Mtove G, Pedro AJ, Gomes E, Silamut K, Lee SJ, et al. Evaluation of a PfHRP2 and a pLDH-based rapid diagnostic test for the diagnosis of severe malaria in 2 populations of African children. Clin Infect Dis 2011; 52: 1100-1107.

[54] Storm J, Perner J, Aparicio I, Patzewitz EM, Olszewski K, Llinas M, et al. Plasmodium falciparum glutamate dehydrogenase a is dispensable and not a drug target during erythrocytic development. Malar J 2011; 10: 193.

[55] Wagner JT, Lüdemann H, Färber PM, Lottspeich F, Krauth-Siegel RL. Glutamate dehydrogenase, the marker protein of Plasmodium falciparum cloning, expression and characterization of the malarial enzyme. Eur J Biochem 1998; 258: 813-819.

[56] Minucci A, Giardina B, Zuppi C, Capoluongo E. Glucose-6-phosphate dehydrogenase laboratory assay: How, when, and why? IUBMB Life 2009; 61: 27-34.

[57] Rodríguez-Acosta A, Domínguez NG, Aguilar I, Girón ME. Characterization of Plasmodium falciparum glutamate dehydrogenasesoluble antigen. Braz J Med Biol Res 1998; 31: 1149-1155.

[58] Anni H, Israel Y. Proteomics in alcohol research. Alcohol Res Health 2002; 26: 219-232.

[59] Bautista JM, Marín-García P, Diez A, Azcárate IG, Puyet A. Malaria proteomics: Insights into the parasite-host interactionsin the pathogenic space. J Proteomics 2014; 97: 107-125.

[60] Solyakov L, Halbert J, Alam MM, Semblat JP, Dorin-Semblat D, Reininger L, et al. Global kinomic and phospho-proteomic analyses of the human malaria parasite Plasmodium falciparum. Nat Commun 2011; 2: 565.

[61] Lasonder E, Ishihama Y, Andersen JS, Vermunt AM, Pain A, Sauerwein RW, et al. Analysis of the Plasmodium falciparum proteome by highaccuracy mass spectrometry. Nature 2002; 419: 537-542.

[62] Roobsoong W, Roytraku S, Sattabongkot J. Determination of the Plasmodium vivax schizont stage proteome. J Proteomics 2011; 74: 1701-1710.

[63] Wu Y, Nelson MM, Quaile A, Xia D, Wastling JM, Craig A. Identification of phosphorylated proteins in erythrocytes infected by the human malaria parasite Plasmodium falciparum. Malar J 2009; 8: 105.

[64] Olesen CH, Brahimi K, Vandahl B, Lousada-Dietrich S, Jogdand PS, Vestergaard LS, et al. Distinct patterns of blood-stage parasite antigens detected by plasma IgG subclasses from individuals with different level of exposure to Plasmodium falciparum infections. Malar J 2010; 9: 296.

[65] Lindner SE, Swearingen KE, Harupa A, Vaughan AM, Sinnis P, Moritz RL, et al. Total and Putative Surface Proteomics of Malaria Parasite Salivary Gland Sporozoites. Mol Cell Proteomics 2013; 12: 1127-1143.

[66] Ray S, Kamath KS, Srivastava R, Raghu D, Gollapalli K, Jain R, et al. Serum proteome analysis of vivax malaria: An insight into disease pathogenesis and host immune response. J Proteomics 2012; 75: 3063-3080.

[67] Bousema T, Drakeley C. Infectivity of Plasmodium falciparum and Plasmodium vivax gametocytes in relation to malaria control and elimination. Clin Microbiol Rev 2011; 4: 377-410.

[68] Smit S, Stoychev S, Louw AI, Birkholtz LM. Proteomic profiling of Plasmodium falciparum through improved, semiquantitative twodimensional gel electrophoresis. J Proteome Res 2010; 9: 2170-2181.

[69] Lim H, Eng J, Yates JR, Tollaksen SL, Giometti CS, Holden JF, et al. Identification of 2D-gel proteins: A comparison of MALDI/TOF peptide mass mapping to µ LC-ESI tandem mass spectrometry. J Am Soc Mass Spectrom 2003; 14: 957-970.

[70] Gelhaus C, Fritsch J, Krause E, Leippe M. Fractionation and identification of proteins by 2-DE and MS: towards a proteomic analysis of Plasmodium falciparum. Proteomics 2005; 5: 4213-4222.

[71] Siqueira-Batista R, Gomes AP, Mendonça EG, Vitorino RR, Azevedo SF, et al. Plasmodium falciparum malaria: proteomic studies. Rev Bras TerIntensiva 2012; 24: 394-400.

[72] Sayeed SK, Shah V, Chaubey S, Singh M, Alampalli SV, et al. Identification of heat shock factor binding protein in Plasmodium falciparum. Malar J 2014; 13: 118.

[73] Segura C, Cuesta-Astroz Y, Nunes-Batista C, Zalis M, von Krüger WM, MascarelloBisch P. Partial characterization of Plasmodium falciparum trophozoite proteome under treatment with quinine, mefloquine and the natural antiplasmodial diosgenone. Biomedica 2014; 34: 237-249.

[74] Vogeser M, Parhofer KG. Liquid chromatography tandem-mass spectrometry (LC-MS/MS)--technique and applications in endocrinology. Exp Clin Endocrinol Diabetes 2007; 115: 559-570.

[75] Grebe SK, Singh RJ. LC-MS/MS in the Clinical laboratory - Where to from here? Clin Biochem Rev 2011; 32: 5-31.

[76] Vijay S, Rawat M, Sharma A. Proteomic analysis of salivary glands of urban malaria vector Anopheles stephensi. Bio Med Res Intl 2014: 1-12.

[77] Singh M, Mukherjee P, Narayanasamy K, Arora R, Sen SD, Gupta S, et al. Analysis of Plasmodium falciparum extracellular secretory antigens at asexual blood stages reveals a cohort of proteins with possible roles in immune modulation and signaling. Mol Cell Proteomics 2009; 8: 2102-2118.

[78] Gitau EN, Kokwaro GO, Karanja H, Newton CR, Ward SA. Plasma and cerebrospinal proteomes from children with cerebral malaria differ from those of children with other Encephalopathies. J Infect Dis 2013; 208: 1494-1503.

[79] Yergey AL, Coorssen JR, Backlund PS Jr, Blank PS, Humphrey GA, Zimmerberg J, et al. De novo sequencing of peptides using MALDI/ TOF-TOF. J Am Soc Mass Spectrometry 2002; 13: 784-791.

[80] Hrabák J, Chudácková E, Walková R. Matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) mass spectrometry for detection of antibiotic resistance mechanisms: from research to routine diagnosis. Clin Microbiol Rev 2013; 26: 103-114.

[81] Roobsoong W, Roytrakul S, Kiatfuengfoo R, Nuchpramool W, Cui L, Udomsangpetch R. Characterization of the Plasmodium vivax erythrocytic stage proteome and identification of a potent immunogenic antigen of the asexual stages. Malaria J 2010; 9(Suppl 2): 44.

[82] Dutta S, Ware LA, Barbosa A, Ockenhouse CF, Lanar DE. Purification, characterization, and immunogenicity of a disulfide cross-linked Plasmodium vivax vaccine candidate antigen, merozoite surface protein 1, expressed in Escherichia coli. Infect Immun 2001; 69: 5464-5470.

[83] Yssouf A, Socolovschi C, Flaudrops C, Ndiath MO, Sougoufara S, Dehecq JS, et al. Matrix-assisted laser desorption ionization - time of flight mass spectrometry: An emerging tool for the rapid identification of mosquito vectors. PLoS One 2013; 8: e72380.

[84] Sturm N, Jortzik E, Mailu BM, Koncarevic S, Deponte M, Forchhammer K, et al. Identification of proteins targeted by the thioredoxin superfamily in Plasmodium falciparum. PLoS Pathog 2009; 5:e1000383

[85] Tang N, Tornatore P, Weinberger SR. Current developments in SELDI affinity technology. Mass Spectrom Rev 2004; 23: 34-44.

[86] Buhimschi IA. Using SELDI-TOF mass spectrometry on amniotic fluid and for clinical proteomics and theranostics in disorders of pregnancy. Methods Mol Biol 2012; 818: 171-197.

[87] Seibert V, Wiesner A, Buschmann T, Meuer J. Surface-enhanced laser desorption ionization time-of-flight mass spectrometry (SELDI TOFMS) and Protein Chip technology in proteomics research. Pathol Res Pract 2004; 200: 83-94.

[88] Ndao M. Biomarker discovery in serum/plasma using surface enhanced laser desorption ionization time of flight (SELDI-TOF) mass spectrometry. Methods Mol Biol 2012; 818: 67-79.

[89] Burté F, Brown BJ, Orimadegun AE, Ajetunmobi WA, Afolabi NK, Akinkunmi F, et al. Circulatory hepcidin is associated with the antiinflammatory response but not with iron or anemic status in childhood malaria. Blood 2013; 121: 3016-3022.

[90] Howard CT, McKakpo US, Quakyi IA, Bosompem KM, Addison EA, Sun K, et al. Relationship of hepcidin with parasitemia and anemia among patients with uncomplicated Plasmodium falciparum malaria in Ghana. Am J Trop Med Hyg 2007; 77: 623-626.

[91] Ndao M, Rainczuk A, Rioux MC, Spithill TW, Ward BJ. Is SELDI-TOF a valid tool for diagnostic biomarkers？Trends Parasitol 2010; 26: 561-567.

ment heading

10.1016/S1995-7645(14)60327-8

*Corresponding author: Chulabhorn International College of Medicine, Thammasat University, Phahonyothin Rd Klongluang, Pathumthani,Thailand 12120.

Tel: 662 564-4400 Ext. 1800

Fax:662 564-4398

E-mail: kesaratmu@yahoo.com