Metabolites differ in their physicochemical properties thus sample collection and preparation will depend on the kind of metabolite to be studied and the method used for processing and detecting those metabolites. In some cases preliminary quenching is needed to stabilize the sample which stops the metabolic reactions (Álvarez-Sánchez et al. 2010). It is recommended to store sample at -80 °C and sample aliquoting should be done at the time of collection to avoid repetitive freezing and thawing of samples (Dunn et al. 2011).

Due to great diversity in the metabolites there is no single technique for the separation and quantification for all the metabolites. A number of techniques are used for metabolites with different properties. GC-MS is mostly used for volatile compounds while analysis of polar or ionic metabolites may be achieved with LC-MS. CE-MS can also be used for polar or ionic compounds (Barbas et al. 2011).

Metabolomic studies produce a huge amount of raw data. It is really difficult to handle such complex datasets manually and thus specific software tools and algorithms are required to convert this complex raw data to comprehensive extracted data that can easily be processed using statistical tools (Courant et al. 2014).

Metabolomics generate high dimensionality data. In metabo-lomic fingerprinting, the number of variables measured per subject vastly exceeds the number of subjects to be considered under that study (Guo et al. 2010). Univariate methods such as the classical Student’s t-test can be used to identify candidate compounds showing significant differences in levels between two subgroups of samples. Multivariate techniques are also used to reduce the complexity of the datasets and to derive the analytical information of biological importance (Brown et al. 2005; Trygg et al. 2007).

The advance form of liquid chromatography includes HPLC and UPLC. In HPLC and UPLC, liquid is the mobile phase. Both the technique work on the same principle that is the molecules passing through the stationary phase moves in different speeds depending on their chemical structure. Though complex biological mixtures cannot be separated through LC columns (Tolstikov and Fiehn 2002) but it allows good mass library reproducibility (Huhman and Sumner 2002). HPLC separations are widely used for analysis of labile and non-volatile polar and non-polar compounds in their native form. UPLC utilizes porous particles with diameters smaller than 2 mm leading to increased surface area and thus provide a better separation. UPLC has certain advantages over HPLC as it allows analysis of more number of samples in a particular time, has high efficacy and peak capacity compared to that of HPLC columns (Zhang et al. 2012).

Alterations in the metabolites of three South African sorghum cultivars; namely Amazi Mhlophe, NS 5511 (bitter abbreviated B) and NS 5655 (sweet, abbreviated S) responding to Colletotrichum sublineolum, were investigated by Tugizimana et al. (2019) using LC-MS based untargeted metabolomics and accumulation of a wide range of antifungal phenolic compounds were observed, particularly apigeninidin, luteolinidin, 3-deoxyanthocynidin phytoalexins and other related conjugates were detected. Yogendra et al. (2014) did a non-targeted metabolomic study of the resistant related metabolites by comparing metabolomics of potato late blight resistant (AC04 and AC09) and susceptible potato genotypes (Criolla Colombia). Trough LC-MS, it was observed that defence-related compounds such as flavonoids phenylpropanoids and alkaloid chemical groups were highly induced in resistant genotypes compared to susceptible ones. Deposition of HCAAs, alkaloids and amides flavonoids leads to the thickening of the cell wall leading to resistance against pathogen penetration.

Chalcone synthase is a key enzyme of flavonoid synthesis pathway which leads to accumulation of cell wall-bound phenolic compounds resulting in resistance in Arabidopsis plants against bacterial pathogen Pseudomonas syringae (Soylu 2006).

Chen et al. (2018) conducted untargeted metabolomics of Arabidopsis through LC-MS. The focus of the study was to observe the role of metabolite N-hydroxy-pipecolic acid in inducing systemic disease resistance in Arabidopsis against bacterial pathogen, P. syringae pathovar tomato. The study demonstrated that Flavin-Dependent Monooxygenase 1 (FMO1), which plays a key role in inducing systemic acquired resistance (SAR), can synthesize N-OH-Pip from pipecolic acid present in plant, and fmo1 mutants when applied exogenously with N-OH-Pip move systemically in Arabidopsis plant and can overcome the SAR-deficiency of the mutants. Several plant metabolites including Pipecolic acid (Pip) (Návarová et al. 2012) are reported to be involved in signal amplification and long-distance communication during SAR (Dempsey and Klessig 2012; Shah and Zeier 2013; Shah et al. 2014).

GC-MS is mainly used for volatile compounds which vaporize without decomposition. Mobile phase is mainly an inert or unreactive gas such as nitrogen or helium. Mostly helium gas is used as carrier gas. Compounds which are volatile and thermally stable such as short chain alcohols, acid, esters, and hydrocarbons are mainly analyzed using this technique.

GC can also be used for analysis of many other compounds only after following derivatization which includes alkylation and silylation (Begley et al. 2009; Broeckling et al. 2005). Polar compounds like carbohydrates, carboxylic acids and free amino acids can be analyzed using GC-MS as derivatives of methoxime/trimethylsilyl (Roessner et al. 2001) whereas no further processing is needed for volatiles (Beck et al. 2014). The sample metabolites differ in their retention times and thus can be automatically identified by comparing and matching the retention time from mass spectra of chroma-tograms through pure chemical standards (Gross 2004).

Studies of plant metabolites can also help to differentiate pathogenic infections and thus may be a great tool for detection and diagnosis. A study was conducted by Lui et al. (2005) to discriminate three fungal diseases of potato through metabolite profiling using GC-MS. Potato tubers were inoculated with three pathogens: P. infestans, Botrytis cinerea and Pythium ultimum. Tubers inoculated with Botrytis produced two specific volatiles: 2-2-propenyl-1,3-dioxolane and 3, 5-heptadiyn-2-one and those inoculated with Pythium produced three metabolites: 2-butanone, 2-methyl-l-butanol and 2-methyl-2-butanalnine. However ethoxy-ethene was observed in tubers inoculated with Phytophthora inoculated tubers.

Several plant defence compounds have been analyzed using GC-MS techniques; various phenolic compounds were mainly found in potato (Wagner et al. 2003; Yang and Bernards 2007), soybean leaves (Benkeblia et al. 2007), maize (Röhlig et al. 2009) and tobacco (Dauwe et al. 2007).

In capillary electrophoresis, analytes are separated on the basis of their ionic mobility or partitioning into an alternate phase through non-covalent interactions. CE-MS is an effective promising separation technique providing high-analyte resolution, for charged metabolites and provides information mainly on polar or ionic compounds (Barbas et al. 2011). It applies separations with high resolutions, sensitive mass determination and specific chemical standards to identify and quantify thousands of metabolites on the basis of their charge over both negative and positive ionization modes (Sato et al. 2004). It is really applicable for the analysis of water-soluble polar metabolites.

Several metabolites, the phenylpropanoid and shikimate pathways, show rise in their levels after Rhizoctonia solani infection (Mutuku and Nose 2012). Plant defence mechanism involves a number of pathways and phenylpropanoid and shikimate pathways form an important part of plant defence (Dixon et al. 2002; Tzin and Galili 2010) and they are involved in the synthesis of various secondary metabolites including phenol compounds (Lattanzio et al. 2006). Synthesis of phenols plays a key role in providing resistance against infection caused by R. solani (Akhtar et al. 2011).

Suharti et al. (2016) studied the difference in levels of metabolites in R. solani infected resistant and susceptible lines of rice (32R and 29S, respectively) through capillary electrophoresis equipped with time of flight mass spectro-photometry (CE/TOF-MS) in positive ion mode. Chlorogenic acid metabolite showed a positive response in 32R and amino acids which showed increase in 29S after inoculation with R. solani were: γ-aminobutyric acid, glutamate, glycine, phenylalanine, histidine, tryptophan, tyrosine and serine. Several compounds produced in plants are plant defence response regulators. Mucha et al. (2019) did a CE study of systemin (an eighteen amino acid peptide plant hormone) which plays an important role in regulating plant defence response. Systemin peptide was injected into the leaves and stem of tomato plant and its transportation in the plant tissues was traced by CE. Systemin is a signalling compound which plays an important role in systemic defence; about 20 defensive genes (like proteinase inhibitors or polyphenol oxidase genes) are activated and regulated by systemin (Pearce et al. 1991; Ryan 2000).

The technique involves use of matrix-assisted laser desorption ionization as a mass spectrometry imaging technique in which the sample (tissue section) is moved in two dimensions while the mass spectrum is recorded (Chaurand et al. 2006). This method has an advantage as it measures the distribution of several analytes at one time without destroying the sample. This technique provides a means to study the plant pathogen interaction and to discover potential markers of infection. It utilizes a matrix, typically a small organic acid with strong ultraviolet absorbance, mixed with analytes to aid desorption and ionization (Norris and Caprioli 2013). The resulting gas phase analyte ions are detected and displayed in a spectrum according to their mass-to-charge ratios (m/z), which yield specific molecular signatures within complex samples. This label-free technology can be used without a priori knowledge of sample composition, allowing for the detection of a variety of analytes, from small molecules to large proteins (Angel and Caprioli 2013).

The technique is a gift of modernization in technology, and can be a great advantage in studying plant pathogen interactions. The technique was successfully utilized by Becker et al. (2014) to study the compounds produced by grapevine as a defence response against Plasmopara viticola. It was observed from the study that other than reservetrol, more toxic compounds such as pterostilbene and viniferins are produced as defence compounds. The technique plays an important role of detection of pathogenic microbes in soil (Siricord and O’Brien 2008).

Ion exchange chromatography is an important technique for separation of ionic compounds. It is mainly of two types: anion exchange and cation exchange. In this technique, analyte molecules are retained on the column through ionic interactions. The ion exchange chromatography matrix consists of positively and negatively charged ions.

Elicitors are known to induce plant defence responses, such as cell wall strengthening, ethylene biosynthesis, reactive oxygen species, induction of hypersensitive response proteins, and expression of pathogenesis-related (Miyata et al. 2006; B. Wang et al. 2012; J.Y. Wang et al. 2004). Some beneficial bacteria, such as the plant growth-promoting rhizobacteria (PGPR), have the tendency to reduce the activity of pathogenic microorganisms by microbial antagonism through competing for nutrients, secretion of lytic enzymes and production of antibiotics (Handelsman and Stabb 1996; van Loon and Bakker 2003; van Loon and Glick 2004). Furthermore, they can indirectly prevent plant from pathogens by eliciting the plant defence system (Haas and Défago 2005).

Protein elicitors from some biocontrol strains have been reported to induce disease resistance, such fengycins and surfactins from Bacillus subtilis (Ongena et al. 2007). Shen et al. (2019) reported novel protein elicitor (AMEP412) from B. subtilis BU412 which leads to hypersensitive response (HR) and SAR in tobacco. Ion-exchange and size exclusion chroma-tography were used for purification. The study revealed that AMEP412 can trigger a series of defence mechanisms such as the generation of reactive oxygen species. It also induced defence enzymes, including phenylalanine ammonialyase, polyphenol oxidase, peroxidase and superoxide dismutase. AMEP412 could stimulate plant systemic resistance against P. syringae pv. tomato DC3000.

N. Wang et al. (2016) reported a novel protein elicitor from Bacillus amyloliquefaciens NC6 which was responsible for induction of systemic resistance in tobacco. The elicitor led to the HR necrosis in leaves of tobacco plant. Systemic resistance was observed against a broad range of pathogens, including tobacco mosaic virus (TMV) and B. cinerea. The elicitor up regulated many genes including the phenylalanine ammonia lyase (PAL), salicylic acid (SA)-responsive PR1a, PR1b, PR5, Coronatine insensitive 1 (COI1) and jasmonic acid (JA)-responsive PDF1.2 which play a key role in plant defence.

Certain fungi produce some antifungal compounds which can be utilized in a number of ways. The first filamentous fungus to potently produce an antifungal peptide (AFP) was Aspergillus giganteus (Olson and Goerner 1965; Wnendt et al. 1994). Rao et al. (2015) identified an antifungal protein, AfAFPR9, and purified it from supernatant of culture of Aspergillus fumigatus R9. AfAFPR9 showed antifungal effect against plant pathogenic fungi Fusarium oxysporum, Alternarialongipes, Colletotrichum gloeosporioides, Paecilomyces variotii, and Trichoderma viride at minimum inhibitory concentrations of 0.6, 0.6, 1.2, 1.2, and 2.4 μg disc^-1, respectively.

NMR is a new and non-destructive technique that requires minimal amount of sample preparation and has a high throughput (can process hundreds of samples per day). The principle of NMR utilizes compounds with odd atomic mass numbered nuclei, which tend to act like magnets in a provided external magnetic field through a process known as nuclear spin (Hatada and Kitayama 2004).

Plant pathogens cause metabolic perturbations in plants which can be studied through metabolite profiling of infected plants to gain insights into plant disease response (Abdel-Farid et al. 2009; Brechenmacher et al. 2010; Choi et al. 2004; Dai et al. 2010; Krishnan et al. 2005; Skirycz et al. 2010; Ward et al. 2011). Bednarek et al. (2005) used wild-type and mutant root cultures of Arabidopsis thaliana infected by root rot pathogen Pythium sylvaticum and observed how aromatic metabolite profiles differ. 1H-NMR was used to study one heterocyclic, sixteen indolic and three phenylpropanoid compounds. The study revealed a relative increase in levels of indolics upon infection. It also concluded that nature and quantity of phenylpropanoid metabolites differ in roots and leaves. Lima et al. (2010) studied the metabolic differences in the healthy and esca disease infected Vitis vinifera plants. 1D and 2D 1H-NMR was used for evaluation and it was observed that various phenolic compounds, methanol, alanine, and g-aminobutyric acid content were increased in diseased plants which may be due to plant defence activation.

Hong et al. (2012) studied the metabolic changes occurring in grapes infected by B. cinerea. Metabolite profiling was done using H-NMR and multivariate statistical analysis of berries from botrytized and healthy bunches. It was observed that phenylpropanoids, flavonoid compounds, glycerol, succinate and gluconic acid, all were directly associated with B. cinerea growth, and were only detected in Botrytis infected berries.

The Table 1 explains how variantly these metabolomic techniques have helped us to study the plant pathogen interactions. In case of plant disease complex, they can be utilized to differentiate the diseases, the detection of some important compounds which are produced in the defence mechanism by plants is made easier, also how resistant and susceptible varieties are different can be detected. Studying the soil microbes is difficult but the techniques make it possible for us to identify the microbes that are involved in disease causation in plants. Thus, all these techniques can be considered as the gift of modern technologies to mankind. Metabolomic tools are now being utilized in the field of plant pathology as detectives to find out how does beneficial microbes instigate the defence mechanism in plants, how does the microbiome present in its periphery plays a role in favour or in against the occurrence of a disease, how does certain chemical formulations when applied to plants lead to biochemical changes in the host plant to defend against pathogens, how does a pathogen has an audacity to breach the plant defence mechanisms, how can improved soil health leads to a microbiota which strengthens the plants against pathogens, what are the chemical talks between the microbes inside the plant system or on the surface that greatly decide the fate of the plants.