Abstract
Background
Potential biomarkers to aid diagnosis and therapy need to be identified for Amyotrophic Lateral Sclerosis, a progressive motor neuronal degenerative disorder. The present study was designed to identify the factor(s) which are differentially expressed in the cerebrospinal fluid (CSF) of patients with sporadic amyotrophic lateral sclerosis (SALS; ALS-CSF), and could be associated with the pathogenesis of this disease.
Results
Quantitative mass spectrometry of ALS-CSF and control-CSF (from orthopaedic surgical patients undergoing spinal anaesthesia) samples showed upregulation of 31 proteins in the ALS-CSF, amongst which a ten-fold increase in the levels of chitotriosidase-1 (CHIT-1) was seen compared to the controls. A seventeen-fold increase in the CHIT-1 levels was detected by ELISA, while a ten-fold elevated enzyme activity was also observed. Both these results confirmed the finding of LC-MS/MS. CHIT-1 was found to be expressed by the Iba-1 immunopositive microglia.
Conclusion
Elevated CHIT-1 levels in the ALS-CSF suggest a definitive role for the enzyme in the disease pathogenesis. Its synthesis and release from microglia into the CSF may be an aligned event of neurodegeneration. Thus, high levels of CHIT-1 signify enhanced microglial activity which may exacerbate the process of neurodegeneration. In view of the multifold increase observed in ALS-CSF, it can serve as a potential CSF biomarker for the diagnosis of SALS.
Keywords: Proteomics, Cerebrospinal fluid, Sporadic amyotrophic lateral sclerosis
Background
Selective loss of cortical and spinal motor neurons is the characteristic feature of Amyotrophic Lateral Sclerosis (ALS), an adult onset progressive fatal neurodegenerative disorder. Factors predisposing the most prominent form of this multifactorial disease viz. sporadic ALS (SALS) remain obscure due to the difficulties in developing animal models. Therefore, development of novel therapeutics is also severely hampered. This is also largely attributed to the lack of a ‘biomarker’ which can be objectively measured as an indicator of pathogenic processes and/or pharmacologic response to therapeutic interventions [1]. The discovery of ideal biomarkers may offer tools for rapid diagnosis, monitoring disease progression and provide insights into the pathophysiology of the disease; thereby broadening therapeutic options. Proximity to the central nervous system (CNS) renders Cerebrospinal Fluid (CSF) to be the ideal biofluid for detection of biomarkers in CNS pathologies. It is speculated that toxic agents which propagate the disease are synthesized in the affected areas, injure the neighboring cells, and are released into the extracellular space and CSF [2,3].
We have earlier shown that exposure of embryonic rat spinal cord cultures to ALS-CSF (in-vitro) and intrathecal injection of the same into neonatal rats (in-vivo) induced degenerative changes in motor neurons and showed the involvement of astrocytes [4-11]. Intracerebroventricular infusion of ALS-CSF in adult rats perturbed the cortical motor neuronal activity and was associated with poor motor performance [12]. Thus several studies, including ours, support the presence of toxic factor(s) in ALS-CSF and attribute them a role in eliciting its pathophysiology [3,13-15].
We undertook a study to identify the toxic factor(s) in ALS-CSF through proteomic analysis. Quantitative mass spectrometric analysis of ALS-CSF compared to age-matched controls showed upregulation of 31 proteins, amongst which Chitotriosidase-1 (CHIT-1) showed more than 10 fold increase. The biological significance of CHIT-1 expression is intriguing in view of the absence of its natural substrate chitin in human brain. Earlier studies have shown an increase in CSF CHIT-1 levels in multiple sclerosis (MS) and Alzheimer’s disease (AD) [16,17].
Results
Confirmation of toxicity of ALS-CSF samples
The toxicity of the ALS-CSF samples was confirmed prior to proteomic analysis. Exposure of NSC-34 cells to the CSF obtained from ALS patients (ALS-CSF) resulted in a dramatic decrease in their viability when compared to the control groups; i.e. the cells treated with CSF from normal individuals (N-CSF) or without CSF (NC) (***p < 0.001 vs NC; ###p < 0.001 vs N-CSF; Figure 1A). It also induced enhancement of LDH activity in ALS-CSF group (***p < 0.001 vs. NC and $$$p < 0.001 vs. N-CSF; Figure 1B).
Proteomic analysis of control and ALS-CSF samples
Ten CSF samples each from controls and ALS were pooled, depleted of abundant proteins and electrophoresed on SDS-PAGE (Figure 1C). Total protein from control and ALS-CSF were subjected to tryptic digestion, followed by liquid chromatography-tandem mass spectrometry (LC-MS/MS) after labeling with isobaric tags for relative and absolute quantitation (iTRAQ). LC-MS/MS analysis identified 819 proteins using SEQUEST and Mascot (Additional file 1: Table S1). Approximately 31 proteins showed more than 1.5-fold increase, suggesting an up- regulation (Additional file 2: Table S2) and about 17 proteins were down-regulated (decrease of 0.5 fold or more) in ALS-CSF samples compared to the normal controls (Additional file 3: Table S3). Four of the prominently up-regulated proteins were CHIT-1 (10 fold), osteopontin isoform-b (3 fold), chitinase-3-like protein 2 (CHI3L2; 2 fold) and chitinase-3-like protein 1 (CHI3L1; 1.7 fold). Thus CHIT-1 showed the most dramatic increase (Table 1, Figure 1D).
Table 1.
S. No | Gene symbol | Protein name | Relative expression (ALS-CSF/N-CSF) fold change |
---|---|---|---|
1 |
CHIT1 |
chitotriosidase-1 precursor [Homo sapiens] |
10 |
2 |
SPP1 |
osteopontin isoform b precursor [Homo sapiens] |
3 |
3 |
CHI3L2 |
chitinase-3-like protein 2 isoform c [Homo sapiens] |
2 |
4 | CHI3L1 | chitinase-3-like protein 1 precursor [Homo sapiens] | 1.7 |
Validation of LC-MS/MS data by ELISA
Observations obtained by LC-MS/MS were confirmed by ELISA. The basal values of CHIT-1 in the control CSF ranged as wide as 80 – 1250 pg/ml, with a mean of 982 ± 245 (n = 11). In the ALS-CSF, the level of CHIT-1 ranged between 5000 – 54,000 pg/ml, with a mean of 17570 ± 4883 pg/ml (n = 16). The mean increase in the ALS-CSF was approximately 17 fold (**p < 0.01 vs N-CSF; Figure 2A). Amongst the tested CSF samples of ALS patients, 27% showed a 4-fold increase, whereas 73% showed an increase of 10-fold or more.
Similar to the LC-MS/MS data, CHI3L2 levels showed approximately 2-fold increase (**p < 0.01 v/s N-CSF; no. of samples: N-CSF =13, ALS-CSF = 16) while osteopontin levels showed 1.9-fold increase in ALS-CSF compared to the control CSF (*p < 0.05 v/s N-CSF; no. of samples: N-CSF =13, ALS-CSF = 16) (Figure 2B & C). Although the CHI3L1 level was also increased, the change was not statistically significant (Figure 2D).
Validation of LC-MS/MS data by enzyme assay
The CHIT-1 in the CSF samples catalyzed the conversion of 4-methylumbelliferyl-β - d N, N’, N” –triacetylchitotriose to 4-methylumbelliferone confirming that the enzyme was biologically active. The CHIT-1 activity in the control CSF ranged between 0.0169 – 0.1856 μmol/min/μl (Mean: 0.02459 ± 0.01499; n = 13) whereas in the ALS-CSF it was 0.0809 – 4.1658 μmol/min/μl (Mean: 0.9932 ± 0.3023; n = 16). Thus the patient CSF samples revealed approximately a 10-fold higher enzymatic activity (**p < 0.001 vs N-CSF; Figure 2E).
CHIT-1 expression in microglia
The Iba-1 immunoreactive pure microglial cultures when exposed to ALS-CSF, showed an elevated expression of CHIT-1 compared to control cultures (Figure 3).
Discussion
This is the first report demonstrating an increase in the levels of four proteins namely, CHIT-1, osteopontin, CHI3L2 and CHI3L1 in the CSF of ALS patients using the novel and precise quantitative proteomics and ELISA. Similar patterns were observed with both LC-MS/MS of pooled CSF and ELISA of individual CSF. Amongst these the increase in CHIT-1 levels being most dramatic; further experiments were focused on this protein. A profound increase in CHIT-1 enzymatic activity was confirmed in ALS-CSF compared to normal CSF. Accordingly, it is likely to be an important biomarker which may help track the progression of the disease. CHIT-1 could have a role in causing toxicity propagated by the CSF, since the ALS-CSF samples used in the present study also contained neurodegenerative attributes as confirmed by MTT and LDH assays.
CHIT-1 is classically associated with lysosomal storage diseases like Gaucher’s disease, due to its increased levels in the patients’ CSF [18]. Chitin is the natural substrate of CHIT-1, but is thought to be absent in the human brain. However, it is intriguing to know that even in the absence of the substrate the enzyme is synthesized by microglia or infiltrating macrophages [19].
It is uncertain whether CHIT-1 activity directly affects the CNS or symbolizes an archaic macrophage response against chitin-containing pathogens [19,20]. Chitin is an insoluble N-acetylglucosamine polymer found in invertebrates and human parasites [21,22]. In its absence, alternative substances e.g. chitin-like glucosamine polymers may be its likely substrate. In post mortem brains of AD patients, presence of glucosamine polymers in amyloid plaques hints at its role in disease pathogenesis [16]. It is also suggested that chitin-like polysaccharides provide scaffolding for β-amyloid deposition thus facilitating the disease process [23]. Higher CHIT-1 expression in post mortem brains of AD patients [24] underlines the co-activation of macrophages and microglia in response to deposition of β-amyloid [25].
It is reported that higher CSF CHIT-1 levels in MS patients correlate well with the disease progression [26]. In the MS patients, the increase in CSF CHIT-1 levels was approximately two-fold, however we observed approximately 10-fold increase in CHIT-1 levels in the patient CSF. Although it is not justified to compare the differences in the patients’ CSF as their study was on MS whereas we studied ALS patients, it is also likely that the differences in fold levels of CSF CHIT-1 are indeed high in ALS compared to MS.
Contrary to AD, deposits of chitin-like substances were absent in MS. Although microglia and infiltrating macrophages driven innate immune response was a classical molecular feature of MS, the products of the latter processes viz. cytokines, ROS etc. were not substantial enough to establish any clinico-pathological co-relation [17]. However, Correale and Fiol reported that the enhanced level of CSF chitinases driven by IL-13 could contribute to neuroinflammation by increasing immune cell migration across the blood–brain barrier in the CNS [26].
The enhanced expression of CHIT-1, by microglia, possibly indicates a neuroinflammatory response. CHIT-1 is an index of the severity of inflammation alongside the release of pro-inflammatory cytokines like IL-16 and IL-18 [27]. In stroke, CHIT-1, TNF-α and other pro-inflammatory cytokines are accepted as markers of microglial activation, occurring independent of pre-existing inflammatory or infectious conditions in patients [28]. According to an alternative hypothesis, CHIT-1 is speculated to be neuroprotective, in view of the reduction in glucosamine aggregates following intrathecal CHIT-1 administration in MS [17]. Even in AD, enhanced levels of CHIT-1 activity in plasma were considered as the response of the activated microglia-macrophage complex to clear the pathogenic chitin-like substances [16,25]. Its role in ALS is yet to be deciphered.
Conclusion
Although studies report higher CSF CHIT-1 levels in several neurological diseases including MS, AD and stroke, no study till date documents its elevated levels in ALS, where maximum increase was observed compared to other neurodegenerative diseases. The mechanisms of CHIT-1 induction in each of the neurological disorders appear to be unique to the disease. Collectively, our findings of steep increase in CSF CHIT-1 levels in SALS along with stable bioactivity render it a biomarker status and may find applications in developing therapeutic strategies for sporadic ALS.
Materials and methods
CSF sample collection
ALS-CSF samples from patients with a mean age of 47.38 ± 5.38 years and disease duration of 0.5 to 2.5 years were obtained. N-CSF samples were drawn from age-matched patients undergoing spinal anaesthesia for orthopaedic surgery but without any clinical history of neurological deficits (mean age 45.7 ± 7.04 years) (Tables 2 and Table 3). CSF samples were snap frozen in liquid nitrogen and stored at –80°C. Informed consent for CSF sample collection was obtained as per the institutional human ethics committee guidelines.
Table 2.
CSF for iTRAQ study | CSF for validation | |||
---|---|---|---|---|
Gender |
Male – 7 (70%) |
Female – 3 (30%) |
Male – 10 (62.5%) |
Female – 6 (37.5%) |
Age at presentation (Mean ± SD) |
47.40 ± 4.95 (38 – 54) Years |
47.38 ± 5.38 (38 – 54) Years |
||
Age at onset |
46 ± 5.05 (37 – 53) Years |
46.28 ± 5.36 (37 – 53) Years |
||
Duration of illness (Mean ± SD) |
15.9 ± 13.4 (4.0 – 48) months |
14.19 ± 10.59 (4.0 – 48) months |
||
Onset Patter: Bulbar |
1 (10%) |
5 (31.25%) |
||
Limb onset |
9 (90%) |
11 (68.75%) |
||
Upper Limbs |
9 |
11 |
||
Lower Limbs |
6 |
7 |
||
Speech affected |
80% (Mild – 30%, Moderate – 30%, Severe – 20%) |
87.5% (Mild – 31.25%, Moderate – 31.25%, Severe – 25%) |
||
Dysphagia |
80% (Mild – 30%, Moderate – 30%, Severe – 20%) |
93.75% (Mild – 31.25%, Moderate – 18.75%, Severe -12.5%) |
||
Spasticity | 9 cases, with evidence of pyramidal signs in the form of spasticity and exaggerated Deep Tendon Reflexes | 11 cases, with evidence of pyramidal signs in the form of spasticity and exaggerated Deep Tendon Reflexes |
Table 3.
CSF for iTRAQ study | CSF for validation | |||
---|---|---|---|---|
Gender |
Male – 8 (80%) |
Female – 2 (20%) |
Male – 11 (84.6%) |
Female – 2 (15.4%) |
Age (Mean ± SD in years) |
47.3 ± 6.99 (39 – 60) |
45.7 ± 7.04 (39 – 60) |
||
Patients undergoing orthopaedic surgery |
Cell culture
We followed a modified protocol to establish pure microglial cultures from P0 Wistar rat pups [29]. Briefly, the spinal cords were dissected, freed of meninges and mechanically triturated in Dulbecco’s Modified Eagle Medium (DMEM) and propagated in DMEM with 10% FBS (GIBCO-BRL). The mixed glial cultures were allowed to attain 100% confluence. On 10th day in-vitro (DIV), the cultures were placed on incubated orbital shaker at 200 rpm for 3–4 hrs. The supernatant containing microglia was centrifuged at 1500 rpm for 5 min, and the pelleted cells were seeded onto poly-l-lysine coated coverslips at the density of 4.4×104 cells/ml. The cultures were maintained in DMEM with 10% FBS (GIBCO-BRL). The cells were then exposed to ALS- CSF or allowed to propagate under normal conditions.
NSC-34 cell line (Cedarlane Corporation, Canada) routinely maintained in DMEM with 10% FBS [30] was used to analyze the neurotoxic effects of individual ALS-CSF samples.
Cell viability/death assays
NSC-34 cells seeded into 96 well plates (500 cells/well) were exposed to 10% v/v N-CSF or ALS-CSF on 5th DIV for 48 hrs, and then subjected to MTT assay (3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) and LDH assay [30].
Mass spectrometry
Depletion of abundant proteins in CSF
CSF samples from controls (n = 10) and ALS patients (n = 10) were pooled individually and used for iTRAQ based quantitative proteomic comparison by mass spectrometry (Figure 4). Samples were centrifuged at 10,000 rpm for 10 min to remove cell debris. Agilent’s multiple affinity removal system (MARS-14), generally used for depletion of albumin, IgG, transferrin, heptoglobin, IgM, IgA, fibrinogen, alpha antitrypsin, apolipoprotein A1, alpha1 acid glycoprotein, alpha2 macroglobin, transthyretin, complement C3 and apolipoproteins was used to deplete the abundant proteins from CSF samples [31]. Briefly, MARS-14 cartridge was conditioned using 4 ml of Buffer-A (50 g, 1 min). CSF (300 μl) was loaded on to the cartridge and spun at 50 g for 1 min. Flow through was collected and reloaded on to the cartridge, incubated for 5 minutes at room temperature (RT) and spun at 50 g for 1 min. Flow through was re-collected and the bound proteins were eluted using 2.4 ml of Buffer-B. The cartridge was conditioned again using buffer-A and the process was repeated until the abundant proteins were depleted. The fractions were concentrated using Millipore filter (3 kDa). This step also ensures removal of salts contributed by the buffers used during depletion steps.
Protein estimation was carried out using Lowry’s method. 200 μg protein each from controls and ALS was used for proteomic comparison. Sample normalization was based on total protein amount which was further verified by SDS-PAGE.
iTRAQ labelling and strong cation exchange chromatography
Individual depleted extract (125 μg) was treated with 2% SDS and reducing agent (2 μl; 60°C for 1 hr) and alkylated with 1 μl of cysteine blocking agent for 10 min at RT. Proteins were digested overnight at 37°C using sequencing grade trypsin at 1:20 (w/w) ratio. Thereafter, peptides from N-CSF and ALS-CSF were labeled using iTRAQ reagents yielding reporter ions of m/z114 and 115 respectively, for 2 hrs at RT. The reaction was quenched by adding 100 μl of water and the peptides from both N-CSF and ALS-CSF were pooled and fractionated using strong cation exchange (SCX) chromatography. The labeled samples were distributed into 19 fractions using SCX. The fractions were desalted using C18 zip tips, dried and reconstituted in 10 μl of 0.1% trifluoroacetic acid before mass spectrometry analysis [32].
LC-MS/MS analysis
LC-MS/MS analysis of iTRAQ-labeled peptides was carried out on an LTQ-Orbitrap Velos mass spectrometer (Thermo Electron, Bremen, Germany) interfaced with Agilent’s 1200 series nanoflow liquid chromatography system (Agilent Technologies, Santa Clara, CA). Each sample was loaded on to the enrichment column (75 μm × 2 cm, 5 μm, 120 Å, Magic C18 AQ MichromBioresources) at a flow rate of 3 μl/min and then resolved on an analytical column (75 μm × 10 cm, 5 μm, 120 Å, Magic C18 AQ MichromBioresources) at a flow rate of 300 nl/min using a linear gradient of 10% - 40% solvent B (90% acetonitrile in 0.1% TFA) over a period of 70 min. The total run time per sample was 115 min. The resolved peptides from analytical column were delivered to LTQ Orbitrap Velos mass spectrometer through an emitter tip (8 μm, New Objective, Woburn, MA). LC-MS/MS data was acquired in a data dependent manner in FT- FT mode. MS spectra were acquired with a mass range of m/z 350 to 1800. Twenty most abundant precursor ions were selected for fragmentation from each MS scan. Data was acquired at MS resolution of 60,000 (m/z 400) and MS/MS resolution of 15,000. Precursor ion fragmentation was carried out using higher energy collision (HCD) mode with normalized collision energy of 41%. Monoisotopic precursor selection was enabled and the precursor ions that were selected for fragmentation were dynamically excluded for 30 sec [32].
Data analysis
The MS data was analyzed using the Proteome Discoverer software (Thermo Scientific, version 1.2). The data was searched against human protein database (NCBI RefSeq 45) along with known contaminants using SEQUEST and MASCOT search algorithms. The parameters used for data analysis included trypsin as a protease (allowed one missed cleavage), iTRAQ labeling at N-terminus and lysine residues, and cysteine modification by methyl methanethiosulfonate (MMTS) as fixed modifications and oxidation of methionine as a variable modification. The precursor ion mass error tolerance was set to 20 ppm and product ion mass error tolerance was set to 0.1 Da. The peptide data was extracted using 1% FDR as a threshold. Relative abundance of proteins between N-CSF and ALS-CSF was determined by Proteome Discoverer based on difference in the peak intensity of reporter ions in the MS/MS spectra of each peptide that was ultimately used for quantifying the corresponding protein.
Enzyme linked immunosorbent assays (ELISA)
N-CSF (n = 13) and ALS-CSF samples (n = 16) were subjected to ELISA based analysis using commercially available kits for CHIT-1 (MBL, Italy; CSF dilution factor (cdf): N-CSF: undiluted; ALS-CSF 1:20), CHI3L1 (Quidel, USA), CHI3L2 (USCN, China; cdf 1:1) and Osteopontin (R&D Systems; cdf 1:50). The protocol was followed as per the manufacturer’s instructions.
CHIT-1 activity assay
4-methylumbelliferyl-β - d N, N’, N” –triacetylchitotriose (Sigma-Aldrich USA) was used as a substrate to assay the enzyme activity. CSF (2.5 g protein) was added to 150 μl of 22 μmol solution prepared in 0.5 M citrate-phosphate buffer (pH 5.2). Following incubation for 15 min at 37°C, the reaction was stopped using 100 μl of 0.5 mol Na2CO3 -NaHCO3 buffer (pH 10.7). The fluorescence was recorded at 365 nm excitation/450 nm emissions (Tecan 2500 flouorimeter, USA) and measured as micromoles of substrate hydrolysed/min/l.
Immunocytochemistry
Fixed primary microglial cultures were stained with rabbit polyclonal anti-CHIT-1 antibody (1:1000, Santacruz, USA) for 24 hr after blocking with 3% bovine serum albumin (BSA) (Sigma–Aldrich, USA) and detected using FITC-conjugated anti-rabbit secondary antibody (1:200, Sigma–Aldrich, USA). The cultures were further incubated with a goat polyclonal anti Iba-1 antibody (1:400, Abcam, UK) for 24 hr and detected with CY3-conjugated anti-goat antibody (1:200, Sigma–Aldrich, USA). The staining was viewed using confocal microscopy (488 nm and 514 nm for FITC and Cy3, respectively; Leica-TCS-SL, Germany). The emission frequencies were segregated to avoid non-specific overlap of labelling [11].
Statistical analysis
The data was statistically assessed for significance by either Student’s t test or one way ANOVA as applicable, followed by Tukey’s post hoc tests.
Abbreviations
SALS: Sporadic amyotrophic lateral sclerosis; ALS-CSF: Cerebrospinal fluid from amyotrophic lateral sclerosis patients; N-CSF: CSF from patients undergoing orthopaedic surgery; CHIT-1: Chitotriosidase-1; LC-MS/MS: Liquid chromatography-tandem mass spectrometry; Iba-1: Ionised calcium binding adapter molecule-1; GFAP: Glial fibrillary acidic protein; NSC-34: Spinal cord motor neurons fused with neuroblastoma; iTRAQ: Isobaric tags for relative and absolute quantitation; MARS-14: Agilent’s multiple affinity removal system.
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
AMV collected samples, performed the experiments, analysed and wrote the manuscript. AS performed the experiments, analysed and wrote the manuscript. PM carried out microglial experiments, analysed and wrote the manuscript. VK analysed and wrote the manuscript. HHC supervised mass spectrometry, analysed and wrote the manuscript. TNS facilitated obtaining control CSF samples and critically evaluated manuscript. SB designed and supervised the experiments and critically reviewed the manuscript. NA enrolled patients with ALS, performed clinical evaluations and provided ALS-CSF. PAA designed, performed experiments, analyzed and wrote the manuscript. TRR conceptualized the project, obtained funding, supervised the study and critically reviewed the manuscript. All the authors read and approved the final manuscript.
Supplementary Material
Contributor Information
Anu Mary Varghese, Email: v.anumary@gmail.com.
Aparna Sharma, Email: aparnasharma12@gmail.com.
Poojashree Mishra, Email: poojashri.mishra@gmail.com.
Kalyan Vijayalakshmi, Email: vijayalakshmi.kb@gmail.com.
Hindalahalli Chandregowda Harsha, Email: harsha@ibioinformatics.org.
Talakad N Sathyaprabha, Email: drsathyaprabha@gmail.com.
Srinivas MM Bharath, Email: thathachar@rediffmail.com.
Atchayaram Nalini, Email: atchayaramnalini@yahoo.co.in.
Phalguni Anand Alladi, Email: alladiphalguni@gmail.com.
Trichur R Raju, Email: trraju.nimhans@gmail.com.
Acknowledgements
The study was funded by Department of Biotechnology, Govt. of India (BT/PR/4054/Med/30/349/2010). The authors are grateful to the Director, Sanjay Gandhi Institute of Trauma & Orthopaedics Centre- Bangalore, for facilitating the collection of control CSF. AMV is a Council for Scientific and Industrial Research Senior Research Fellow (SRF), PM is University Grants Commission SRF, Harsha HC is a Wellcome Trust/DBT India Alliance Early Career Fellow.
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