Abstract
Leishmania donovani causes anthroponotic visceral leishmaniasis, responsible for about 50,000 annual deaths worldwide. Current therapies have considerable side effects. Drug resistance has been reported and no vaccine is available nowadays. The development of undifferentiated promastigotes in the sand fly vector’s gut leads to the promastigote form that is highly infective to the mammalian host. Fully differentiated promastigotes play a crucial role in the initial stages of mammalian host infection before internalization in the host phagocytic cell. Therefore, the study of protein levels in the promastigote stage is relevant for disease control, and proteomics analysis is an ideal source of vaccine candidate discovery. This study aims to get insight into the protein levels during the differentiation process of promastigotes by 2DE-MALDI-TOF/TOF. This partial proteome analysis has led to the identification of 75 proteins increased in at least one of the L. donovani promastigote differentiation and growth phases. This study has revealed the differential abundance of said proteins during growth and differentiation. According to previous studies, some are directly involved in parasite survival or are immunostimulatory. The parasite survival–related proteins are ascorbate peroxidase; cystathionine β synthase; an elongation factor 1β paralog; elongation factor 2; endoribonuclease L-PSP; an iron superoxide dismutase paralog; GDP-mannose pyrophosphorylase; several heat shock proteins—HSP70, HSP83-17, mHSP70-rel, HSP110; methylthioadenosine phosphorylase; two thiol-dependent reductase 1 paralogs; transitional endoplasmic reticulum ATPase; and the AhpC thioredoxin paralog. The confirmed immunostimulatory proteins are the heat shock proteins, enolase, and protein kinase C receptor analog. The potential immunostimulatory molecules according to findings in patogenic bacteria are fructose-1,6-diphophate aldolase, dihydrolipoamide acetyltransferase, isocitrate dehydrogenase, pyruvate dehydrogenase E1α and E1β subunits, and triosephosphate isomerase. These proteins may become disease control candidates through future intra-vector control methods or vaccines.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Leishmania donovani (Kinetoplastida: Trypanosomatidae) is the causative agent of anthroponotic visceral leishmaniasis (AVL), also named Kala-Azar or dumdum fever. AVL is fatal if left untreated (Desjeux 2001; WHO 2010). The estimated disease burden of visceral leishmaniasis (VL) is 500,000 cases, including AVL and zoonotic visceral leishmaniasis (ZVL). VL causes approximately 50,000 annual deaths (WHO 2010; Alvar et al. 2012; Desjeux 2004). East Africa and the Indian subcontinent are the main L. donovani endemic areas. Vaccines are not available, and the approved drugs frequently cause adverse effects and resistance.
The Leishmania spp. life cycle is digenetic. The promastigote stage is extracellular and undergoes differentiation in the sandfly vector (Psychodidae: Phlebotominae) gut, leading to highly infective forms called metacyclic promastigotes. The sandfly injects mature promastigotes into the mammalian host’s dermis during bloodmeal intakes. Most promastigotes are killed in about 3 min by the complement system (Moreno et al. 2007; Dominguez et al. 2002), and only a fraction of the population enters phagocytic host cells, where they rapidly differentiate into the amastigote stage. Amastigotes survive within the phagolysosome's acidic microenvironment in the presence of hydrolytic enzymes (Zilberstein et al. 2008; Zilberstein and Shapira 1994) at 32–37 °C, depending on the species. Regarding this sequence of events during the life cycle, fully differentiated promastigotes likely bear most vaccine candidates (Alcolea et al. 2016a), and amastigotes most drug targets. However, the opposite should not be discarded in vaccine development as the objective is to block both stages.
High-throughput quantitative transcriptomic and proteomic approaches allowed for differential gene expression analysis promastigote-to-amastigote development (Lahav et al. 2011; Rosenzweig et al. 2008a, 2008b; Saxena et al. 2007; Srividya et al. 2007), but not L. donovani promastigote growth and differentiation. In this study, protein levels in the early logarithmic, mid-logarithmic, and stationary phase of L. donovani promastigotes have been compared employing two-dimensional electrophoresis (2DE). Therefore, the promastigote growth and differentiation process leading to an infectivity increase has been compared in terms of relative protein abundance. Protein identification was performed by MALDI-TOF/TOF mass spectrometry. Interestingly, some differentially abundant proteins are immunostimulatory or are involved in parasite survival, according to previous studies.
Materials and methods
Promastigote cultures
Promastigotes of the L. donovani Karthoum strain (MHOM/SD/43/124) were kindly provided by A. Toraño and M. Domínguez (Department of Immunology, Centro Nacional de Microbiología, Virología e Inmunología Sanitarias, Instituto de Salud Carlos III, Majadahonda, Spain). Three cultures were set at an initial cell density of 2 × 106/ml in RPMI 1640 supplemented with L-glutamine (Life Technologies, Carlsbad, CA), 10% heat-inactivated fetal bovine serum (Lonza, Basel, Switzerland), and 100 μg/ml streptomycin—100 IU/ml penicillin (Life Technologies), and incubated at 27 °C. Cell density was estimated with a Neubauer chamber and total protein extracts from 108 promastigotes per culture were prepared daily after harvesting them at 2000 g for 10 min.
Protein extracts
Samples containing 108 promastigotes were washed with PBS and lysed with 150 μl of a buffer containing 8.4 M urea, 2.4 M thiourea, 5% CHAPS, 50 mM DTT, 1% Triton X-100, and 50 μg/ml DNase I. The buffer also contained Mini EDTA-free Protease Inhibitor Cocktail at the amount specified by the manufacturer (Roche, Mannheim, Germany). Lysis was allowed for 30 min under mild rotation. Then, the extracts were centrifuged at 8000 g for 10 min. The supernatants were precipitated with methanol/chloroform (Wessel and Flugge 1984). Once the sediments dried, they were resuspended in 2 × rehydration buffer (7 M urea, 2 M thiourea, 4% CHAPS, 0.003% bromophenol blue). Protein concentration was measured with the RC DC protein assay kit (BioRad, Hercules, CA) according to the manufacturer’s instructions, and by densitometry of SDS-PAGE runs (Alcolea et al. 2011).
2DE analysis of the relative protein levels
The input for 2DE was 50 μg per sample, which were equivalent to ~ 3 × 107 promastigotes. After diluting to 140 μl with 2 × isoelectrofocusing (IEF) buffer (18.2 mM DTT and 0.5% IPG buffer solution pH 3–10, BioRad), IEF runs were carried out in a Protean IEF Cell system (BioRad) using IPG strips of 7 cm in length, and a non-linear gradient from pH 3 to 10 (BioRad). More than 12,000 V·h were reached in all steps, which were: 50 V for 12 h; 250 V for 1 h; 500 V for 1 h; 1000 V for 1 h; 2000 V for 1 h; linear ramp to 8000 V for 1 h; and 8000 V up to 3500 V·h. Then, the proteins were separated by 12% SDS-PAGE in a pre-cooled MiniProtean 3 Dodeca Cell system (BioRad) at 0.5 W/gel for the first 30 min and 1.5 W for 5 min more than required for the dye front to reach the bottom edge. After staining with SYPRO Ruby (BioRad), the images were analyzed with PDQuest 2D Advanced 8.0.1 software (BioRad) according to the manufacturer’s instructions. Briefly, the images of all experimental conditions and replicates were overlapped, generating a composite image (i.e., master gel). Then, spots were automatically detected in all individual member gel images and in the master gel, and undetected spots were manually set. The landmark tool allowed enhancing the accuracy of pairwise spot recognition across gels. Then, a manual check of all spot histograms and 3D density graphs was carried out in order to remove artifacts. The normalization method was based on the Total Quantity in Valid Spots algorithm. The reference samples for calculation of the gene expression ratios were early logarithmic phase promastigotes (day 2).
MALDI-TOF/TOF mass spectrometry protein identification
Spot excision from 2DE gels was carried out with EXQuest Spot Cutter (BioRad). In-gel digestion was carried out with porcine trypsin, and peptides were prepared for MALDI-TOF/TOF mass spectrometry as described (Alcolea et al. 2011). First, the spots were washed with 50 mM ammonium bicarbonate. Then, they were washed with acetonitrile, reduced with 10 mM DTT in the presence of 25 mM ammonium bicarbonate at 56 °C for 20 min, and alkylated with 50 mM iodoacetamide in a 50 mM ammonium bicarbonate solution. The wash steps were repeated and the spots were dried at 40 °C. Protein digestions were performed with 16 ng/ml modified porcine trypsin (Promega, Madison, WI) in a 25% acetonitrile-50 mM ammonium bicarbonate solution at 37 °C for 6 h. The reactions were stopped by addition of 0.5% (v/v) trifluoroacetic acid (TFA). The peptides were extracted with TFA for 15 min. The eluted tryptic peptides were dried in a vacuum centrifuge and resuspended in 4 ml of a 30%/15%/0.1% water/isopropanol/TFA solution. The 0.8 μl digests were mixed with 0.8 μl aliquots of 3 μg/μl α-cyano-4-hydroxycinnamic acid (Sigma), organized in an OptiTOF™ Plate (Life Technologies), and air-dried at room temperature. The ABI 4800 MALDI-TOF/TOF mass spectrometer (Life Technologies) runs were performed in positive reflector mode at 25 kV for MS and 1 kV for MS/MS. Using ABI 4000 Series Explorer Software 3.6 (Life Technologies), peptide mass fingerprinting (PMF) and MS/MS fragment ion spectra were smoothed and corrected to zero baseline. Each PMF spectrum was internally calibrated with the mass signals of ions generated in trypsin autolysis in order to reach < 25 ppm accuracy in mass measurements. Trypsin and keratin mass signals and potential sodium and potassium adducts (+ 21 Da and + 39 Da) were removed from the peak list.
Statistical analysis and meta-analysis
Three biological replicates of the experiment were performed. After spot identification and curation (“2DE analysis of the relative protein levels”), the relative expression levels were calculated with PD Quest 2D Advanced 8.0.1 software (BioRad). Spots showing statistically significant (Student’s t-test, α > 0.05) differences in protein levels (≥ 1.7-fold) were selected.
The PMF and fragment ion spectra were processed with MASCOT 2.1 and Global Protein Server Explorer 4.9 (Life Technologies) for protein identification with the following settings: trypsin as the enzyme for peptide generation; allowed one missed cleavage; carbamidomethyl cystein as fixed modification due to treatment with iodoacetamide; oxidation of methionine as a variable modification; ± 50 ppm mass tolerance for precursors, and ± 0.3 Da for MS/MS fragment ions; and confidence interval for protein identification ≥ 95% (p < 0.05). Only peptides with an individual ion score above the identity threshold (52) were considered correctly identified. The last release (TriTrypDB rel. 52, 2021; www.tritrypdb.org) of the resequenced and the de novo assembled L. infantum JPCM5 genome (Gonzalez-de la Fuente et al. 2017) was used as the reference sequence for protein identifications because this genome sequence has been extensively curated for almost 15 years and because L. infantum belongs to the L. donovani species complex. Gene Ontology (GO) enrichment analysis was performed with REVIGO (Supek et al. 2011). Interactive graphs of GO Biological Process (GOBP) and GO Molecular Function (GOMF) terms were generated for the protein sets increased and decreased on days 4 and 6 with respect to day 2.
Western blot
Twenty micrograms of each protein extract were separated by 10% SDS-PAGE at 12 mA for 30 min and 30 mA for 90 min. Semi-dry electrotransfer onto Trans-Blot® 0.2 μm nitrocellulose membranes was performed at 1.3A and 25 V for 10 min using the Trans-Blot® Turbo Transfer System (BioRad). Next, the membranes were blocked with a 5% skimmed milk solution in PBS with 0.1% Tween 20 (Sigma) for 1 h at room temperature and washed three times with PBS containing 0.1% Tween 20 (PBS-Tween) for 15, 5, and 5 min, respectively. Thereafter, the membranes were incubated with 1∶1000-diluted rabbit anti-LACK polyclonal serum in the blocking solution for 2 h (Alcolea et al. 2016b). The membrane was washed before and after incubation with 1∶2,000 HRP-conjugated goat anti-rabbit IgG (DAKO, Ely, UK) for 1.5 h, and developed with ECL reagents (GE Healthcare, Pittsburg, PA) in a Chemi-Doc™ (BioRad) instrument following the manufacturers’ instructions. The antibodies were removed from the membrane by a 1 h stripping step at 50 °C in a solution containing 111 mM β-mercaptoethanol, 347 mM SDS, and 62.5 mM Tris–HCl pH6.8. During this step, thorough mixing was performed for 10 s every 5 min. The hybridization procedure was repeated using a 1:10,000 dilution of a monoclonal mouse anti-L. mexicana gGAPDH antibody kindly provided by Paul Michels (University of Edinburgh), which was the loading control (Alcolea et al. 2014).
Results and discussion
Analysis of protein levels in L. donovani promastigotes by 2DE-MALDI-TOF/TOF
Protein extracts were prepared from promastigote samples at the following logistic growth curve time points (Fig. 1): day 2 (early logarithmic phase), day 4 (mid-logarithmic phase), and day 6 (stationary phase). The proteomics experiment was performed in triplicate including analysis of biological variation in the experimental design (i.e., individual processing of three independent cultures). One out of three replicate 2DE gels per condition is shown in Figs. 2, 3, and 4.
Statistical analysis included normalization with the Total Quantity in Valid Spots algorithm and statistical inference using the paired Student’s t-test (threshold values: ≥ 1.7-fold expression; p < 0.05). For this purpose, PDQuest software (BioRad) was used. The number of differentially expressed proteins with respect to day 2 promastigotes (MASCOT score > 52) that were identified in at least one of the conditions studied is 75 (Table 1). About 200 quality spots could be confirmed in each 2DE gel. The total number of spots containing differentially abundant proteins was 81, but 6 could not be identified by MALDI-TOF/TOF. Some of the differentially abundant proteins found (Table 1) were previously described as potential immunostimulatory proteins and some others are related to stress (Fig. 5).
The LACK levels decrease throughout L. donovani promastigote growth
The activated protein kinase C receptor analog (LACK) abundance peak is reached at the beginning of L. donovani promastigote growth and differentiation. As these processes progress, a considerable gradual decrease is observed (Table 1), which has been validated by Western blot (Fig. 5; Supplementary Information (SI): Fig. 11). A similar expression pattern has been observed in L. infantum (Alcolea et al. 2011), L. amazonensis (Alcolea et al. 2016b), and the non-pathogenic trypanosomatid Crithidia fasciculata, which contains the CACK ortholog (Alcolea et al. 2014). The steady-state transcript levels are not coincident with the protein levels because the L. infantum LACK transcript levels are constant (Gonzalez-Aseguinolaza et al. 1999; Alcolea et al. 2010) thanks to translational or post-translational regulation. L. amazonensis causes ACL, and L. infantum and L. donovani cause VL, although both species have specific features leading to different disease transmission and progression. L. donovani causes AVL, whereas L. infantum VL is zoonotic (ZVL), of which canids are the main reservoirs. ZVL in humans is especially prevalent in children and immunosuppressed patients (Cruz et al. 2006; Pasquau et al. 2005). However, an outbreak involving lagomorphs as reservoirs remains active in Spain (Arce et al. 2013; Jimenez et al. 2014; Molina et al. 2012). LACK is an antigenic protein able to partially protect against L. infantum in dogs (Ramiro et al. 2003; Ramos et al. 2008, 2009; Alcolea et al. 2019a). The L. infantum LACK protein localizes in the cytoplasm particulate fraction near the plasma membrane. The LACK levels decrease throughout promastigote growth. However, they are sufficiently high in the stationary phase. A LACK-based DNA vaccine against canine leishmaniasis has been achieved (Ramiro et al. 2003; Ramos et al. 2008, 2009; Alcolea et al. 2019a). The LACK gene expression regulation behavior is similar in L. donovani and L. amazonensis suggesting that the protein is also protective in these species.
Differential abundance of parasite survival and immunostimulatory proteins
Some differentially abundant proteins from Table 1 are involved in parasite survival or are immunostimulatory, according to previous studies. These changes will be detailed and discussed in the following sections. The genes upregulated in earlier promastigote differentiation stages may be used to design intra-vector control strategies, and those upregulated at the end of differentiation may be vaccine candidates. These expression patterns are not always mutually exclusive. A given protein may be a vaccine candidate whenever the steady-state levels are sufficient for immunization, even when their levels decrease compared to other growth phases. The LACK antigen is an example. Western blot-validated downregulation in L. donovani promastigotes indicates that LACK is upregulated in early logarithmic phase promastigotes. Constant low expression levels remain until the end of differentiation (Fig. 6), as confirmed in L. infantum and C. fasciculata. Therefore, these data support that LACK plays determinant roles in all promastigote differentiation stages and may be used in intra-vector control, not only as a vaccine. The gene expression criterion is effective to select vaccine candidates only when combined with other criteria, such as immunogenic properties and biological role (Alcolea et al. 2016a). LACK elicits a Th1 response (Ramiro et al. 2003; Ramos et al. 2008), and relatively low expression levels in differentiated promastigotes are sufficient to protect against infection.
Overview of the differentially abundant proteins: GO enrichment analysis
Compared to early logarithmic phase promastigotes, mid-logarithmic phase promastigotes increase the levels of a set of proteins enriched in GOBP terms involved in mitosis, cytoskeleton organization and microtubule-based processes, proteolysis, carbohydrate catabolic processes, the tricarboxylic acid cycle (TCA), energy obtention, ATP metabolism, generation of precursor metabolites, nucleotide metabolism, metabolism of nitrogen and sulfur compounds, response to nitrogen compounds, reactive oxygen species (ROS) metabolic processes, superoxide metabolism, and transport from the endoplasmic reticulum to the cytosol (Fig. 7A; SI: Fig. 12A). These GOBP terms are associated with GOMF terms reflecting the same types of processes easily recognizable in the interactive graph shown in Fig. 7B and SI: Fig. 12B.
The GOBP terms associated with the set of proteins that decrease in mid-logarithmic phase promastigotes compared to the early logarithmic phase are involved in translational termination, regulation of cytokinesis, peroxisome fission, regulation of cell division and cell death, stabilization of membrane potential, calcium ion homeostasis, reactive oxygen species metabolic process, hydrogen peroxide catabolic process, growth, and oxidative phosphorylation (Fig. 8A; SI: Fig. 13A). The corresponding GOMF terms are structural molecule activity, L-ascorbate peroxidase activity, oxidoreductase activity acting on peroxide as acceptor and on diphenols and other substances as donors, guanylyl nucleotide-binding, GTP-binding, hydrolase activity, GTPase activity, transaminase activity, translation factor activity, cytoskeleton, and S-methyl-5-thioadenosine phosphorylase activity (Fig. 8B; SI: Fig. 13B).
The GOBP terms increased in stationary phase promastigotes are related to carbohydrate, amino acid, and nucleotide metabolic processes, catabolism, the TCA, processes related to redox homeostasis, and negative regulation of mitosis (Fig. 9A; SI: Fig. 14A). The GOMF terms reflect these biological processes through the following activities (Fig. 9B; SI: Fig. 14B): glutathione disulfide oxidoreductase, glutathione dehydrogenase (ascorbate), oxidoreductase on superoxide radicals as acceptor, antioxidant, cystathionine beta-synthase (involved in glutathione biosynthesis), delta-1-pyrroline-5-carboxylate, isocitrate dehydrogenase, GTPase, lyase; fructose-bisphosphate aldolase, phosphopyruvate hydratase, aldehyde-lyase, NADP- and NADPH-binding, and lyase.
The GOBP terms that decrease in stationary phase promastigotes are related to the regulation of cell division and cytokinesis, negative regulation of cell death, stabilization of membrane potential, reactive oxygen species metabolic processes, including hydrogen peroxide, catabolic processes, and retrograde vesicle-mediated transport (Fig. 10A; SI: Fig. 15A). The associated GOMF terms in this set are L-ascorbate peroxidase activity, oxidoreductase on peroxide as acceptor, oxidoreductase activity on the aldehyde or oxo group of donors, transaminase activity, carboxypeptidase activity, fructose-bisphosphate aldolase activity (associated to oxidoreductase activity acting on diphenols and related substances as donors), unfolded protein-binding, and GTPase activity (Fig. 10B; SI: Fig. 15B).
Gene expression regulation and protein folding
The glycolytic enzyme enolase is more abundant in the mid-logarithmic (day 4) and stationary (day 6) phase promastigotes (Table 1) than in the reference condition (early logarithmic phase promastigotes, day 2). The parasite's enolase is a versatile protein that participates in transcription, protein folding (i.e., chaperone), cell migration, and plasminogen reception (Fonseca et al. 2014). The differential gene expression data don't provide information about which of these processes is favored by enolase upregulation. Interestingly, enolase is an antigen and probably a virulence factor in Leishmania spp. (Fonseca et al. 2014; Avilan et al. 2011; Vanegas et al. 2007; Abanades et al. 2012). The enolase increase in differentiated promastigotes and the role as an antigen suggest that this is a vaccine candidate.
The gene copies LINF_340014000 and LINF_340014200 encode for elongation factor 1β (EF1β), which increases in the early logarithmic phase of L. donovani promastigotes (Table 1). Conversely, the levels of EF1β encoded by the gene LINF_360020500 are constitutive in promastigotes of this species (Alcolea et al. 2019b). The LINF_340014000/14200 EF1β differs from LINF_360020500 EF1β in the N-terminal region (~ 100 and ~ 71 first amino acids, respectively; SI: Fig. 16). Elongation factor 2 (EF2) reaches higher levels at the beginning of L. donovani promastigote growth and differentiation (Table 1). The EF2 N-terminal domain is an immunostimulatory molecule protecting BALB/c mice in combination with CpG oligodeoxynucleotides as molecular adjuvants (Agallou et al. 2018). This protein stimulates the protective Th1 response against the parasite. (Gupta et al. 2007; Kushawaha et al. 2011). The EF2 levels decrease in mid-logarithmic and stationary phase promastigotes, and EF2 is present in infective promastigotes, in which this molecule may be a target in an immunized animal in the early infection steps.
The endoribonuclease L-PSP contributes to parasite survival (Fonseca et al. 2014). A mammalian ortholog is a potent protein synthesis inhibitor (Morishita et al. 1999). This activity may be related to metacyclogenesis (mid-logarithmic phase), as EndoL-PSP upregulation suggests, because differentiation probably involves translational efficiency modulation, as confirmed in Trypanosoma spp. (Jensen et al. 2014; Smircich et al. 2015). Therefore, the endoribonuclease L-PSP may contribute to survival affecting differentiation through gene expression-mediated modulation.
The levels of several chaperones change across the growth and differentiation of L. donovani promastigotes (Table 1). The heat shock protein 110 (HSP110) levels are higher on day 2. All other mentioned HSPs increase in later stages. Chromosome 28 encodes an HSP70 gene tandem array composed of two copies (spots LdK.2905, LdK.3901, and LdK.4902). HSP70 increases in mid-logarithmic and stationary phase promastigotes. These findings suggest that this protein from the HSP70 family plays a determinant role during the intermediate stages of L. donovani promastigote differentiation. HSP70 proteins are also relevant for parasite survival (Fonseca et al. 2014). Also, three hsp70-related mitochondrial precursor paralogs increase during the ongoing growth and differentiation, one on day 4 and two on day 6. The HSP83-17 protein also increases on day 6. HSP70 and HSP83 are immunostimulatory proteins triggering specific B cell proliferation (Echeverria et al. 2001; Rico et al. 1999, 1998, 2002).
The T-complex protein 1 (TCP1) γ, δ, and η subunits decrease in the stationary phase of L. donovani promastigotes. The same profile was observed for TCP1γ protein levels in L. infantum (Alcolea et al. 2011). TCP1 is a ring-shaped chaperonin complex responsible for folding certain nascent or incorrectly folded proteins such as tubulins in an ATP-dependent manner. This complex is active in L. donovani because refolding of unfolded luciferase was achieved using a homo-oligomeric LdTCP1γ complex alone without the LdTCP1 partner units. LdTCP1γ also interacts with tubulins (Bhaskar et al. 2015).
The protein disulfide isomerase 2 (PDI2) is an enzyme facilitating correct protein folding in the ER lumen. PDI catalyzes disulfide bond reduction and formation, protein isomerization, and protein folding. Bacitracin inhibits isomerase and reductase activity, which leads to promastigote and amastigote growth. Other compounds inhibit PDI activity in L. major. Therefore, PDI2 is a potential drug target (Ben Khalaf et al. 2012). Mid-logarithmic phase L. donovani promastigotes upregulate PDI2 (Table 1). An intense metabolic activity leading to protein synthesis is a feature of this growth phase.
Cell division and protein degradation
The transitional ER ATPase (TER-ATPase; CDC48 in Saccharomyces cerevisiae) is involved in the segregation of macromolecular complexes, such as chromatin, membranes, and protein assemblies (e.g., proteasome) (Druck et al. 1995; Rabouille et al. 1995). Therefore, the high relative expression levels of TER-ATPase found in actively growing mid-logarithmic phase L. donovani promastigotes (Table 1) match with a role in cell cycle progression. The proteasome α7 subunit is upregulated in early logarithmic phase promastigotes, and two carboxypeptidases increase in the mid-logarithmic phase.
The replication factor A 51 KDa subunit (RPA51) levels are null in the stationary phase. RPA51 is part of a heterotrimeric complex involved in single-stranded DNA intermediate stabilization in the DNA replication process during the cell cycle S phase and damaged DNA repair. This information is consistent with RPA51 gene downregulation in the stationary phase, where the population replication rate is null.
Metabolism and glycoconjugate biosynthesis
The glycolytic enzymes fructose-1,6-bisphosphate aldolase (ALD), triosephosphate isomerase (TPI), cytosolic glyceraldehyde-3-phosphate dehydrogenase (cGAPDH), and enolase are upregulated in advanced differentiation stages. Specifically, TPI, cGAPDH, and enolase increase in the mid-logarithmic and stationary phase, whereas ALD only increases in the stationary phase. Enolase is involved in a compendium of biological roles, contributing to transcription, protein folding (i.e., chaperone), cell migration, and plasminogen reception (Fonseca et al. 2014), which facilitates parasite survival. This protein is an antigen, a virulence factor, and a probable vaccine candidate.
The pyruvate dehydrogenase complex E1β subunit (PDC-E1β) is upregulated in mid-logarithmic phase L. donovani promastigotes. On the contrary, the dihydrolipoamide acetyltransferase (DHLAT) PDC component is upregulated in the early and mid-logarithmic phases (Fig. 5, Table 1). The isocitrate dehydrogenase (ICDH) increases in the mid-logarithmic and stationary phases. The respiratory chain component iron-sulfur cluster 2Fe-2S protein is upregulated in the early logarithmic phase of promastigotes. On the grounds of observations in pathogenic E. coli strains and Mycobacterium tuberculosis (Brandes et al. 2007; Rhee et al. 2005), as well as proven resistance of amastigotes and promastigotes to NO, we proposed a hypothesis relating differential abundance of glycolytic, PDC, Krebs cycle, and respiratory chain proteins with resistance to NO in L. amazonensis (Alcolea et al. 2016b), a species that causes American Cutaneous Leishmaniasis (ACL).
The GDP-mannose pyrophosphorylase (GDP-MP) is upregulated in the mid-logarithmic phase. This enzyme is crucial for LPG biosynthesis, glycosyl inositol phospholipids (GIPLs), and other surface glycoconjugates. The L. mexicana promastigote GDP-MP is essential for virulence (Davis et al. 2004). GDP-MP downregulation in the stationary phase is consistent with these observations because LPG biosynthesis is only required before the differentiation process concludes.
Methylthioadenosine phosphorylase (MTAP) is an enzyme involved in purine and polyamine salvage biosynthesis pathways (Bacchi et al. 1991). This enzyme is important in trypanosomatids because these parasites lack the de novo purine and polyamine biosynthesis pathways (Kouni 2003) and require spermidine for trypanothione biosynthesis. These differences with the mammalian hosts are important and suggest that MTAP is a potential therapeutic target (Datta et al. 2008; Singh et al. 2012). 5′-methylthioadenosine (MTA) is the natural MTAP substrate, which is cleaved to 5-methylthioribose-1-phosphate (MTRP) and adenine (Bacchi et al. 1991; Bertino et al. 2011). The MTAP gene is strongly upregulated at the protein level in L. donovani intracellular amastigotes (Pescher et al. 2011). MTAP might be a drug target according to this expression profile, the mentioned differences between trypanosomatids and mammalian hosts in purine, polyamine, and methionine biosynthesis, and high druggability indexes (Abid et al. 2017). The MTAP expression peak occurs in the early logarithmic phase of L. donovani promastigotes. Therefore, this protein may also be a target for intra-vector parasite control.
The cystathionine β-synthase (CβS) catalyzes the first step of the two-reaction reverse trans-sulfurylation cysteine biosynthesis pathway. CβS substrates are homocysteine and serine, and cysteine γ-lyase converts the product into cysteine. The CβS is more abundant in the stationary phase (Table 1) and participates in resistance to oxidative stress (Romero et al. 2015). Therefore, this enzyme is part of the protein repertoire increased in differentiated promastigotes.
The aspartate aminotransferase (ASAT) from Leishmania spp. is a broad-specificity enzyme because L-aspartate, L-tyrosine, L-alanine, and L-tryptophan are substrates. The optimal temperature for ASAT activity is 29.5ºC in Leishmania (Fair and Krassner 1971), close to the promastigote growth optimum (26–27 °C). This enzyme is more abundant in the early logarithmic phase (Table 1). In this phase, amino acid demand for protein biosynthesis is higher. The δ-pyrroline-5-carboxylate dehydrogenase is an enzyme involved in proline catabolism increased in mid-logarithmic and stationary phase promastigotes (Table 1). The transcript encoding for this enzyme also increases in highly infective promastigotes isolated from the sand fly stomodeal valve (Alcolea et al. 2016c). Therefore, this enzyme increases in the ongoing promastigote differentiation.
Cytoskeleton
The levels of several α- and β-tubulins increase during promastigote growth and differentiation, whereas other variants decrease. These expression profiles may be related to body length decrease and flagellar length increase at this stage. The flagellar radial spoke protein reaches its maximum levels in mid-logarithmic phase promastigotes, where more elongated parasites called nectomonads are predominant (Lei et al. 2010). Fully differentiated promastigotes are shorter but show a higher cell body:flagellum length ratio. The paralyzed flagellar protein 16 increases in mid-logarithmic phase promastigotes.
Redox homeostasis
The L. donovani LINF_340014000/14200 EF1β (Table 1) increases in early logarithmic phase promastigotes (Table 1), as well as the L. pifanoi ortholog (Alcolea et al. 2016d). The LINF_360020500 EF1β paralog is constitutively expressed in L. donovani (Alcolea et al. 2019b). On the contrary, the ortholog from the closely related non-pathogenic trypanosomatid Crithidia fasciculata is increased in early logarithmic phase (Alcolea et al. 2014). The LINF_340014000/14200 EF1β differs from the LINF_360020500 EF1β in the N-terminal region (~ 100 and ~ 71 first amino acids; SI: Fig. 16), whereas their C-terminal regions are identical and bear the elongation factor 1β function (SSF54984, PF00736, IPR014038, IPR036019, PTHR11595). The N-terminal domain lacks annotated domains in both cases. Hence, this region may be responsible for the trypanothione S-transferase activity reported by Vickers et al. (Vickers and Fairlamb 2004; Vickers et al. 2004), and cadmium-induced stress increases LINF_360020500 EF1β transcript levels. The LINF_340014000/14200 EF1β trypanothione S-transferase activity is represented in Fig. 5 as EF1β* to distinguish this protein from the constitutive LINF_360020500 EF1β in L. donovani.
Three almost identical genes encode for tryparedoxin peroxidases (TrxPs) according to multiple alignments (Alcolea et al. 2019b). These enzymes can reduce reactive oxygen species (ROS) in the presence of reduced tryparedoxin (TXN[SH2]), which is oxidized (TXN[S]) during this reaction. TXN[SH2] is regenerated by reduced trypanothione (T[SH2]), which is recycled by the NADPH-dependent enzyme trypanothione reductase (TryR) (Day 2009; Flohe et al. 1999; Gretes et al. 2012). A TXN gene was also confirmed to be constitutively expressed in promastigotes (Alcolea et al. 2019b), whereas a different TXN called AhpC/TSA family thioredoxin-like protein is upregulated in early logarithmic phase promastigotes. Constitutive levels of the iron superoxide dismutase (Fe-SOD) paralogs (SI: Fig. 17) were also found (Alcolea et al. 2019b), except for LINF_320033200. The present study has revealed that the LINF_320033200 Fe-SOD paralog (Fe-SOD*) increases in mid-logarithmic and stationary phase promastigotes (Table 1). The Fe-SOD enzymes are functionally coupled to TrxPs through superoxide anion reduction (Fig. 5) generated in reactions catalyzed by enzymes like the ribonucleotide reductase (RNR). In the non-pathogenic trypanosomatid Crithidia fasciculata, Fe-SOD and TrxP are also upregulated (Alcolea et al. 2014).
Ascorbate peroxidase (APX) is a heme-dependent enzyme initially found in cyanobacteria, plants, and algae which catalyzes L-ascorbate oxidation to dehydroascorbate using hydrogen peroxide as electron donor. This enzyme participates in the ascorbate–glutathione cycle in plants, which is also present in trypanosomatids and allows for hydrogen peroxide elimination (Caverzan et al. 2012). Functional APX-like enzymes have been found in trypanosomatids. For example, a Trypanosoma cruzi APX (TcAPX) can protect the parasite against hydrogen peroxide-induced stress, which was demonstrated by comparing benznidazole sensitive (BZS) and resistant (BZR) strains. APX levels increase in BZR compared to BZS strains (Nogueira et al. 2012). TcAPX catalyzes the electron transfer from reduced ascorbate. NADPH oxidation via trypanothione-TryR recycles this molecule (Fig. 5) (Wilkinson et al. 2002). TcAPX is a type A heme-dependent hybrid with the cytochrome c peroxidase (TcAPX-CCP), using ferrocytochrome c and ascorbate as electron donors (Hugo et al. 2017). In T. cruzi, TcAPX-CCP is located in the amastigote ER (Wilkinson et al. 2002), mitochondrion, and nucleus (Hugo et al. 2017). The genus Leishmania also contains this enzyme. A potential antioxidant role–scavenging hydrogen peroxide and superoxide anion has been found in L. major. LmAPX-CCP activity using ferrocytochrome c is considerably higher than using ascorbate as the electron donor, suggesting a role similar to yeast CCP, which consists of hydrogen peroxide and superoxide anion detoxification in the mitochondrion (Adak and Pal 2013). Mitochondria contribution to ROS production in non-photosynthetic organisms is much higher than in plants. The LdAPX peak level is found in the early logarithmic phase (Fig. 5, Table 1), suggesting that intense metabolic activity at the beginning of the growth curve requires hydrogen peroxide removal. TryR is not the only enzyme capable of oxidizing NADPH for the LdAPX reaction in trypanosomatids. The thiol-dependent reductase 1 (TDR1) can reduce ascorbate by transferring reducing power from NADPH. The TDR1 level increase has been observed in L. donovani mid-logarithmic and stationary phase promastigotes, whereas the TryR levels remain constitutive in all growth phases, like in L. amazonensis (Alcolea et al. 2016b). In summary, these data support that the redox homeostasis proteins changing their levels are APX, AhpC-TXN, EF1β*, two TDR1, and Fe-SOD*, whereas all TrxP and all other TXN and Fe-SOD are constitutively expressed throughout promastigote growth and differentiation. The functional connections between APX, AhpC-TXN, EF1β*, TDR1, and Fe-SOD are represented in Fig. 5.
Conclusions
This study has revealed the differential abundance of 75 proteins during growth and differentiation. According to previous studies, some are involved in parasite survival (APX, CβS, EF1β*, EF2, endoribonuclease L-PSP, Fe-SOD*, GDP-MP, HSP70, HSP83-17, mHSP70-rel, HSP110, MTAP, TDR1, TER-ATPase, and AhpC-TXN), or are immunostimulatory against Leishmania spp. (HSP70, HSP83-17, mHSP70-rel, HSP110, enolase, and LACK) or pathogenic bacteria (ALD, DHLAT, ICDH, PDC-E1α, PDC-E1β, and TPI). The proteins increased at earlier promastigote differentiation stages may be used to design intra-vector control strategies (APX, AhpC-TXN, EF1β*, EF2, HSP110, MTAP, ALD, LACK, DHLAT, and PDC-E1α), and those upregulated at the end of differentiation may be vaccine candidates (CβS, Fe-SOD, endoribonuclease L-PSP, GDP-MP,HSP70, HSP83-17, mHSP70-rel, TDR1, TER-ATPase, enolase, ICDH, PDC-E1β, and TPI). Both groups are not mutually exclusive, and case-by-case characterization is required. For example, although the LACK antigen decreases at the stationary phase, the protein levels may be sufficient to protect against L. donovani. We have generated a vaccine against canine leishmaniasis based on the LACK gene. In this study, the L. donovani LACK abundance profile found by 2DE-MS/MS has been validated with four independent Western blot replicate experiments.
References
Abanades DR, Arruda LV, Arruda ES, Pinto JR, Palma MS, Aquino D, Caldas AJ, Soto M, Barral A, Barral-Netto M (2012) Immunodominant antigens of Leishmania chagasi associated with protection against human visceral leishmaniasis. PLoS Negl Trop Dis 6(6):e1687
Abid H, Harigua-Souiai E, Mejri T, Barhoumi M, Guizani I (2017) Leishmania infantum 5′-methylthioadenosine phosphorylase presents relevant structural divergence to constitute a potential drug target. BMC Struct Biol 17(1):9
Adak S, Pal S (2013) Ascorbate peroxidase acts as a novel determiner of redox homeostasis in Leishmania. Antioxid Redox Signal 19(7):746–754
Agallou M, Pantazi E, Tsiftsaki E, Toubanaki DK, Gaitanaki C, Smirlis D, Karagouni E (2018) Induction of protective cellular immune responses against experimental visceral leishmaniasis mediated by dendritic cells pulsed with the N-terminal domain of Leishmania infantum elongation factor-2 and CpG oligodeoxynucleotides. Mol Immunol 103:7–20
Alcolea PJ, Alonso A, Gomez MJ, Moreno I, Dominguez M, Parro V, Larraga V (2010) Transcriptomics throughout the life cycle of Leishmania infantum: high down-regulation rate in the amastigote stage. Int J Parasitol 40(13):1497–1516
Alcolea PJ, Alonso A, Larraga V (2011) Proteome profiling of Leishmania infantum promastigotes. J Eukaryot Microbiol 58(4):352–358
Alcolea PJ, Alonso A, Garcia-Tabares F, Torano A, Larraga V (2014) An insight into the proteome of Crithidia fasciculata choanomastigotes as a comparative approach to axenic growth, peanut lectin agglutination and differentiation of Leishmania spp. promastigotes. PLoS One 9(12):e113837
Alcolea PJ, Alonso A, Larraga V (2016) Rationale for selection of developmentally regulated genes as vaccine candidates against Leishmania infantum infection. Vaccine 34(46):5474–5478
Alcolea PJ, Alonso A, Garcia-Tabares F, Mena MC, Ciordia S, Larraga V (2016) Increased abundance of proteins involved in resistance to oxidative and nitrosative stress at the last stages of growth and development of Leishmania amazonensis promastigotes revealed by proteome analysis. PLoS One 11(10):e0164344
Alcolea PJ, Alonso A, Dominguez M, Parro V, Jimenez M, Molina R, Larraga V (2016) Influence of the microenvironment in the transcriptome of Leishmania infantum promastigotes: Sand Fly versus Culture. PLoS Negl Trop Dis 10(5):e0004693
Alcolea PJ, Alonso A, Garcia-Tabares F, Mena MD, Ciordia S, Larraga V (2016) Proteome profiling of the growth phases of Leishmania pifanoi promastigotes in axenic culture reveals differential abundance of immunostimulatory proteins. Acta Trop 158:240–247
Alcolea PJ, Alonso A, Esteban A, Peris P, Cortes A, Castillo JA, Larraga V (2019) IL12 p35 and p40 subunit genes administered as pPAL plasmid constructs do not improve protection of pPAL-LACK vaccine against canine leishmaniasis. PLoS One 14(2):e0212136
Alcolea PJ, Alonso A, Garcia-Tabares F, Mena MDC, Ciordia S, Larraga V (2019) An insight into the constitutive proteome throughout Leishmania donovani promastigote growth and differentiation. Int Microbiol 22(1):143–154
Alvar J, Velez ID, Bern C, Herrero M, Desjeux P, Cano J, Jannin J, den Boer M (2012) Team WHOLC: Leishmaniasis worldwide and global estimates of its incidence. PLoS One 7(5):e35671
Arce A, Estirado A, Ordobas M, Sevilla S, Garcia N, Moratilla L, de la Fuente S, Martinez AM, Perez AM, Aranguez E et al (2013) Re-emergence of leishmaniasis in Spain: community outbreak in Madrid, Spain, 2009 to 2012. Euro Surveill 18(30):20546
Avilan L, Gualdron-Lopez M, Quinones W, Gonzalez-Gonzalez L, Hannaert V, Michels PA, Concepcion JL (2011) Enolase: a key player in the metabolism and a probable virulence factor of trypanosomatid parasites-perspectives for its use as a therapeutic target. Enzyme Res 2011:932549
Bacchi CJ, Sufrin JR, Nathan HC, Spiess AJ, Hannan T, Garofalo J, Alecia K, Katz L, Yarlett N (1991) 5′-Alkyl-substituted analogs of 5’-methylthioadenosine as trypanocides. Antimicrob Agents Chemother 35(7):1315–1320
Ben Khalaf N, De Muylder G, Louzir H, McKerrow J, Chenik M (2012) Leishmania major protein disulfide isomerase as a drug target: enzymatic and functional characterization. Parasitol Res 110(5):1911–1917
Bertino JR, Waud WR, Parker WB, Lubin M (2011) Targeting tumors that lack methylthioadenosine phosphorylase (MTAP) activity: current strategies. Cancer Biol Ther 11(7):627–632
Bhaskar, Mitra K, Kuldeep J, Siddiqi MI, Goyal N (2015) The TCP1gamma subunit of Leishmania donovani forms a biologically active homo-oligomeric complex. FEBS J 282(23):4607–4619
Brandes N, Rinck A, Leichert LI, Jakob U (2007) Nitrosative stress treatment of E. coli targets distinct set of thiol-containing proteins. Mol Microbiol 66(4):901–914
Caverzan A, Passaia G, Rosa SB, Ribeiro CW, Lazzarotto F, Margis-Pinheiro M (2012) Plant responses to stresses: Role of ascorbate peroxidase in the antioxidant protection. Genet Mol Biol 35(4 suppl):1011–1019
Cruz I, Nieto J, Moreno J, Canavate C, Desjeux P, Alvar J (2006) Leishmania/HIV co-infections in the second decade. Indian J Med Res 123(3):357–388
da Fonseca PS, Fialho LC Jr, Silva SO, Melo MN, de Souza CC, Tafuri WL, Bruna Romero O, de Andrade HM (2014) Identification of virulence factors in Leishmania infantum strains by a proteomic approach. J Proteome Res 13(4):1860–1872
Datta AK, Datta R, Sen B (2008) Antiparasitic chemotherapy: tinkering with the purine salvage pathway. Adv Exp Med Biol 625:116–132
Davis AJ, Perugini MA, Smith BJ, Stewart JD, Ilg T, Hodder AN, Handman E (2004) Properties of GDP-mannose pyrophosphorylase, a critical enzyme and drug target in Leishmania mexicana. J Biol Chem 279(13):12462–12468
Day BJ (2009) Catalase and glutathione peroxidase mimics. Biochem Pharmacol 77(3):285–296
Desjeux P (2001) The increase in risk factors for leishmaniasis worldwide. Trans R Soc Trop Med Hyg 95(3):239–243
Desjeux P (2004) Leishmaniasis: current situation and new perspectives. Comp Immunol Microbiol Infect Dis 27(5):305–318
Dominguez M, Moreno I, Lopez-Trascasa M, Torano A (2002) Complement interaction with trypanosomatid promastigotes in normal human serum. J Exp Med 195(4):451–459
Druck T, Gu Y, Prabhala G, Cannizzaro LA, Park SH, Huebner K, Keen JH (1995) Chromosome localization of human genes for clathrin adaptor polypeptides AP2 beta and AP50 and the clathrin-binding protein. VCP Genomics 30(1):94–97
Echeverria P, Dran G, Pereda G, Rico AI, Requena JM, Alonso C, Guarnera E, Angel SO (2001) Analysis of the adjuvant effect of recombinant Leishmania infantum Hsp83 protein as a tool for vaccination. Immunol Lett 76(2):107–110
el Kouni MH (2003) Potential chemotherapeutic targets in the purine metabolism of parasites. Pharmacol Ther 99(3):283–309
Fair DS, Krassner SM (1971) Alanine aminotransferase and aspartate aminotransferase in Leishmania tarentolae. J Protozool 18(3):441–444
Flohe L, Hecht HJ, Steinert P (1999) Glutathione and trypanothione in parasitic hydroperoxide metabolism. Free Radic Biol Med 27(9–10):966–984
Gonzalez-Aseguinolaza G, Taladriz S, Marquet A, Larraga V (1999) Molecular cloning, cell localization and binding affinity to DNA replication proteins of the p36/LACK protective antigen from Leishmania infantum. Eur J Biochem 259(3):909–916
Gonzalez-de la Fuente S, Peiro-Pastor R, Rastrojo A, Moreno J, Carrasco-Ramiro F, Requena JM, Aguado B (2017) Resequencing of the Leishmania infantum (strain JPCM5) genome and de novo assembly into 36 contigs. Sci Rep 7(1):18050
Gretes MC, Poole LB, Karplus PA (2012) Peroxiredoxins in parasites. Antioxid Redox Signal 17(4):608–633
Gupta SK, Sisodia BS, Sinha S, Hajela K, Naik S, Shasany AK, Dube A (2007) Proteomic approach for identification and characterization of novel immunostimulatory proteins from soluble antigens of Leishmania donovani promastigotes. Proteomics 7(5):816–823
Hugo M, Martinez A, Trujillo M, Estrada D, Mastrogiovanni M, Linares E, Augusto O, Issoglio F, Zeida A, Estrin DA et al (2017) Kinetics, subcellular localization, and contribution to parasite virulence of a Trypanosoma cruzi hybrid type A heme peroxidase (TcAPx-CcP). Proc Natl Acad Sci U S A 114(8):E1326–E1335
Jensen BC, Ramasamy G, Vasconcelos EJ, Ingolia NT, Myler PJ, Parsons M (2014) Extensive stage-regulation of translation revealed by ribosome profiling of Trypanosoma brucei. BMC Genomics 15:911
Jimenez M, Gonzalez E, Martin-Martin I, Hernandez S, Molina R (2014) Could wild rabbits (Oryctolagus cuniculus) be reservoirs for Leishmania infantum in the focus of Madrid, Spain? Vet Parasitol 202(3–4):296–300
Kushawaha PK, Gupta R, Sundar S, Sahasrabuddhe AA, Dube A (2011) Elongation factor-2, a Th1 stimulatory protein of Leishmania donovani, generates strong IFN-gamma and IL-12 response in cured Leishmania-infected patients/hamsters and protects hamsters against Leishmania challenge. J Immunol 187(12):6417–6427
Lahav T, Sivam D, Volpin H, Ronen M, Tsigankov P, Green A, Holland N, Kuzyk M, Borchers C, Zilberstein D et al (2011) Multiple levels of gene regulation mediate differentiation of the intracellular pathogen Leishmania. FASEB J 25(2):515–525
Lei SM, Romine NM, Beetham JK (2010) Population changes in Leishmania chagasi promastigote developmental stages due to serial passage. J Parasitol 96(6):1134–1138
Molina R, Jimenez MI, Cruz I, Iriso A, Martin-Martin I, Sevillano O, Melero S, Bernal J (2012) The hare (Lepus granatensis) as potential sylvatic reservoir of Leishmania infantum in Spain. Vet Parasitol 190(1–2):268–271
Moreno I, Molina R, Torano A, Laurin E, Garcia E, Dominguez M (2007) Comparative real-time kinetic analysis of human complement killing of Leishmania infantum promastigotes derived from axenic culture or from Phlebotomus perniciosus. Microbes Infect 9(14–15):1574–1580
Morishita R, Kawagoshi A, Sawasaki T, Madin K, Ogasawara T, Oka T, Endo Y (1999) Ribonuclease activity of rat liver perchloric acid-soluble protein, a potent inhibitor of protein synthesis. J Biol Chem 274(29):20688–20692
Nogueira FB, Rodrigues JF, Correa MM, Ruiz JC, Romanha AJ, Murta SM (2012) The level of ascorbate peroxidase is enhanced in benznidazole-resistant populations of Trypanosoma cruzi and its expression is modulated by stress generated by hydrogen peroxide. Mem Inst Oswaldo Cruz 107(4):494–502
Pasquau F, Ena J, Sanchez R, Cuadrado JM, Amador C, Flores J, Benito C, Redondo C, Lacruz J, Abril V et al (2005) Leishmaniasis as an opportunistic infection in HIV-infected patients: determinants of relapse and mortality in a collaborative study of 228 episodes in a Mediterreanean region. Eur J Clin Microbiol Infect Dis 24(6):411–418
Pescher P, Blisnick T, Bastin P, Spath GF (2011) Quantitative proteome profiling informs on phenotypic traits that adapt Leishmania donovani for axenic and intracellular proliferation. Cell Microbiol 13(7):978–991
Rabouille C, Levine TP, Peters JM, Warren G (1995) An NSF-like ATPase, p97, and NSF mediate cisternal regrowth from mitotic Golgi fragments. Cell 82(6):905–914
Ramiro MJ, Zarate JJ, Hanke T, Rodriguez D, Rodriguez JR, Esteban M, Lucientes J, Castillo JA, Larraga V (2003) Protection in dogs against visceral leishmaniasis caused by Leishmania infantum is achieved by immunization with a heterologous prime-boost regime using DNA and vaccinia recombinant vectors expressing LACK. Vaccine 21(19–20):2474–2484
Ramos I, Alonso A, Marcen JM, Peris A, Castillo JA, Colmenares M, Larraga V (2008) Heterologous prime-boost vaccination with a non-replicative vaccinia recombinant vector expressing LACK confers protection against canine visceral leishmaniasis with a predominant Th1-specific immune response. Vaccine 26(3):333–344
Ramos I, Alonso A, Peris A, Marcen JM, Abengozar MA, Alcolea PJ, Castillo JA, Larraga V (2009) Antibiotic resistance free plasmid DNA expressing LACK protein leads towards a protective Th1 response against Leishmania infantum infection. Vaccine 27(48):6695–6703
Rhee KY, Erdjument-Bromage H, Tempst P, Nathan CF (2005) S-nitroso proteome of Mycobacterium tuberculosis: Enzymes of intermediary metabolism and antioxidant defense. Proc Natl Acad Sci U S A 102(2):467–472
Rico AI, Del Real G, Soto M, Quijada L, Martinez AC, Alonso C, Requena JM (1998) Characterization of the immunostimulatory properties of Leishmania infantum HSP70 by fusion to the Escherichia coli maltose-binding protein in normal and nu/nu BALB/c mice. Infect Immun 66(1):347–352
Rico AI, Angel SO, Alonso C, Requena JM (1999) Immunostimulatory properties of the Leishmania infantum heat shock proteins HSP70 and HSP83. Mol Immunol 36(17):1131–1139
Rico AI, Girones N, Fresno M, Alonso C, Requena JM (2002) The heat shock proteins, Hsp70 and Hsp83, of Leishmania infantum are mitogens for mouse B cells. Cell Stress Chaperones 7(4):339–346
Romero I, Tellez J, Romanha AJ, Steindel M, Grisard EC (2015) Upregulation of cysteine synthase and cystathionine beta-synthase contributes to Leishmania braziliensis survival under oxidative stress. Antimicrob Agents Chemother 59(8):4770–4781
Rosenzweig D, Smith D, Opperdoes F, Stern S, Olafson RW, Zilberstein D (2008) Retooling Leishmania metabolism: from sand fly gut to human macrophage. FASEB J 22(2):590–602
Rosenzweig D, Smith D, Myler PJ, Olafson RW, Zilberstein D (2008) Post-translational modification of cellular proteins during Leishmania donovani differentiation. Proteomics 8(9):1843–1850
Saxena A, Lahav T, Holland N, Aggarwal G, Anupama A, Huang Y, Volpin H, Myler PJ, Zilberstein D (2007) Analysis of the Leishmania donovani transcriptome reveals an ordered progression of transient and permanent changes in gene expression during differentiation. Mol Biochem Parasitol 152(1):53–65
Singh N, Kumar M, Singh RK (2012) Leishmaniasis: current status of available drugs and new potential drug targets. Asian Pac J Trop Med 5(6):485–497
Smircich P, Eastman G, Bispo S, Duhagon MA, Guerra-Slompo EP, Garat B, Goldenberg S, Munroe DJ, Dallagiovanna B, Holetz F et al (2015) Ribosome profiling reveals translation control as a key mechanism generating differential gene expression in Trypanosoma cruzi. BMC Genomics 16:443
Srividya G, Duncan R, Sharma P, Raju BV, Nakhasi HL, Salotra P (2007) Transcriptome analysis during the process of in vitro differentiation of Leishmania donovani using genomic microarrays. Parasitology 134(Pt 11):1527–1539
Supek F, Bosnjak M, Skunca N, Smuc T (2011) REVIGO summarizes and visualizes long lists of gene ontology terms. PLoS One 6(7):e21800
Vanegas G, Quinones W, Carrasco-Lopez C, Concepcion JL, Albericio F, Avilan L (2007) Enolase as a plasminogen binding protein in Leishmania mexicana. Parasitol Res 101(6):1511–1516
Vickers TJ, Fairlamb AH (2004) Trypanothione S-transferase activity in a trypanosomatid ribosomal elongation factor 1B. J Biol Chem 279(26):27246–27256
Vickers TJ, Wyllie S, Fairlamb AH (2004) Leishmania major elongation factor 1B complex has trypanothione S-transferase and peroxidase activity. J Biol Chem 279(47):49003–49009
Wessel D, Flugge UI (1984) A method for the quantitative recovery of protein in dilute solution in the presence of detergents and lipids. Anal Biochem 138(1):141–143
WHO (2010) Report of a Meeting of the WHO Expert Committee on the Control of Leishmaniases. WHO, Geneva, Switzerland, p 104
Wilkinson SR, Obado SO, Mauricio IL, Kelly JM (2002) Trypanosoma cruzi expresses a plant-like ascorbate-dependent hemoperoxidase localized to the endoplasmic reticulum. Proc Natl Acad Sci U S A 99(21):13453–13458
Zilberstein D (2008) Physiological and biochemical aspects of Leishmania development. In: Myler P, Fassel N (eds) Leishmania after the genome. Caister Academic Press, Norfolk, pp 107–122
Zilberstein D, Shapira M (1994) The role of pH and temperature in the development of Leishmania parasites. Annu Rev Microbiol 48:449–470
Funding
Open Access funding provided thanks to the CRUE-CSIC agreement with Springer Nature. This work was supported by the Ramón Areces Foundation (competitive call contract; XVIII Concurso Nacional de Ayudas a la Investigación en Ciencias de la Vida y de la Materia, 2016 call).
Author information
Authors and Affiliations
Contributions
PJA, AA, and VL conceived and designed the study. PJA, AA, FGT, JL, LTCM, FJL, and SRG performed research. PJA analyzed the data. PJA and VL wrote the paper. All authors read, edited, and approved the submitted manuscript.
Corresponding authors
Ethics declarations
Conflict of interest
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Alcolea, P.J., Alonso, A., García-Tabares, F. et al. An insight into differential protein abundance throughout Leishmania donovani promastigote growth and differentiation. Int Microbiol 26, 25–42 (2023). https://doi.org/10.1007/s10123-022-00259-4
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10123-022-00259-4