A fast and cost-effective microsampling protocol incorporating reduced animal usage for time-series transcriptomics in rodent malaria parasites

6- to 8 week old female CBA mice (SLC Inc., Shizuoka, Japan) were used in all experiments. Mice were housed at 26 °C and maintained on a diet of mouse feed (CLEA Rodent 499 Diet CE-2 from CLEA Japan, Inc.) and water. Mice infected with malaria parasites were given 0.05% para-aminobenzoic acid (PABA)-supplemented water to assist parasite growth.

Plasmodium chabaudi chabaudi AS and Plasmodium vinckei vinckei CY strains were used to initiate infections in mice. In each case, 1 million parasites were intravenously inoculated into each CBA mouse.

Strand-specific RNA-seq paired-end reads were mapped onto the reference genomes, P. chabaudi AS version 3 (http://​www.​genedb.​org/​Homepage/​Pchabaudi) and P. vinckei vinckei CY genome (ENA study accession—PRJEB27301) using TopHat2 v2.0.13 [49] with options “–library-type = fr-firststrand” and “–no-novel-juncs”. Differential expression analysis was carried out using cuffdiff2 v2.2.1 [50] with “-u -b” parameters. Transcript integrity number (TIN) was calculated from the mapped reads using RSeqC [51]. Pearson correlation coefficients were calculated using cor function in R stats package [52] and visualized using corrplot package [53] in R. Multidimensional scaling was performed using cmdscale and dist functions in stats R package. To create a phaseogram, the phase of gene expression was calculated using the ARSER [54] package and the genes were ordered according to their phase. Heatmaps were created using heatmap.2 function in gplots package [55] and graphs plotted using ggplot2 [56] in R.

cDNA synthesis was performed using reverse transcription master mix according to the manufacturer’s instructions (Fluidigm). Pre-amplification of target cDNAs were performed using a multiplexed, target-specific amplification protocol (95 °C for 15 s, 60 °C for 4 min for a total of 14 cycles). The pre-amplification step uses a cocktail of forward and reverse primers of genes of interest to increase the number of copies to a detectable level. Products were diluted fivefolds prior to amplification using SsoFast EvaGreen Supermix with low ROX and target specific primers in 96.96 Dynamic arrays on a Biomark HD microfluidic quantitative RT-PCR system (Fluidigm) (run as technical duplicates). Expression data for each gene was retrieved in the form of C_t values (cycle threshold). The gene expression (in the form of dC_t values using PCHAS_1202900 as housekeeping gene) of 91 genes were assessed and compared between 2 and 4 biological replicates of microsamples and terminally bled samples as a validation of comparisons done by RNA-seq. The dC_t values for terminally bled samples are uniformly lower than the microsamples (despite starting with equal amounts of template cDNA), which might be due to the fact that the terminally bled samples have a higher parasite-to-host RNA ratio due to leukocyte depletion and saponin lysis steps.

Gene-wise fragment counts were inferred using featureCounts [57] and subsampling analysis was performed using subSeq v1.4.1 [58]. Random subsampling of different sizes (1, 3.16, 10, 31.6 and 100% of the total reads) was performed for the 12 P. vinckei samples with up to 10 replications at each subsampling step. For each subsampling step, differential expression analysis was performed for each pairwise comparison among the four time points with a q-value cutoff of 0.05 using two tools, DESeq 2 [59] and edgeR [60]. Cost estimation was done with the following conditions- (i) target sequencing depth of 3000,000 paired-end 100 bp reads per sample, (ii) sequencing cost per gigabasepair is $22 [61] and (iii) Cost of one 6-week old female CBA/J mouse is $31.68 (https://​www.​jax.​org/​strain/​000656).

Twenty microlitres of blood was collected via tail snip from P. chabaudi-infected mice, washed with PBS and immediately lysed with 0.5 mL TRIzol reagent. Following microsample collection, mice were anaesthetized and exsanguinated via incision of the brachial artery. Around 0.5 mL of blood was collected from each mouse, washed twice with PBS and passed through home-made CF11 cellulose columns to remove leukocytes. The RBCs were then gently lysed using saponin and the harvested parasite pellet was immediately lysed with 1 mL TRIzol reagent (see Fig. 1a).

The P. chabaudi microsamples were taken at a low parasitaemia of 4–8% and this was reflected in the total RNA yield from these samples, with most yielding around 1 μg total RNA (see Table 1). Upon performing Illumina RNA sequencing and mapping RNA-seq reads onto the P. chabaudi reference genome, it was found that a low percentage of the reads (4–12%) were of parasite origin in the P. chabaudi samples, resulting in low fragment coverage for each gene (most genes had less than 50 fragments mapped onto them).

There was strong correlation between the normalized gene-wise Fragments Per Kilobase of transcript per Million mapped reads (FPKM) values of microsamples and terminal bleed samples (see Fig. 1c). Pearson correlations of 0.9 to 0.92 were obtained for the four mice that were profiled, based on the expression values of 3936 genes. A positive correlation was also obtained independently by quantitative real-time PCR (qRT-PCR) of 91 genes (see Additional file 1). However, out of all the genes with reads in terminal bleed samples, 942 genes had no reads in the microsamples, owing to the lower fragment depths in microsamples.

Plasmodium v. vinckei CY develops synchronously during blood stage growth [62], similar to P. chabaudi, and in contrast to P. yoelii and P. berghei that show asynchronous growth in vivo. The four time points sampled, therefore, correspond to roughly dominant populations of ring (6 h), early trophozoite (12 h), late trophozoite (18 h) and schizont (24 h) stages. Twenty microlitre samples (microsamples) were taken via tail snip from three mice infected with P. vinckei at four time points; 6 h, 12 h, 18 h and 24 h during the 4th day post infection, and lysed with TRIzol, as before.

First, the yield and quality of RNA obtained from microsamples were assessed. Plasmodium vinckei samples were at a higher parasitaemia (at around 25%) than Plasmodium chabaudi samples. This was reflected in the total RNA yield from these samples, with the majority yielding around 10 μg respectively (Table 1). Quality assessment of total RNA using Bioanalyser found no evidence of degradation and showed rRNA electropherogram peaks of both mouse and Plasmodium origin as expected, (Fig. 1d). Higher percentages (55–75%) of the total reads were mapped onto the P. vinckei genome, resulting in higher fragment depth (most genes with more than 424 mapped fragments) compared to P. chabaudi (Table 1).

Multidimensional scaling of the samples from the four time points showed a good level of dissimilarity between their expression profiles reflecting stage-specific gene expression in the parasite. Tight correlations were also obtained among the three biological replicates at all four time points (Pearson correlations ranging from 0.97 to 0.99) (Fig. 1b). Of a total of 5073 genes in P. vinckei, 4328 genes were significantly differentially expressed (p value less than 0.05) at least in one time point (616 genes were not differentially expressed and only 129 genes had 0 FPKM value at least in one time point). As in other Plasmodium species [1, 3, 10, 11, 23, 24] stage-specific gene expression was inferred in P. vinckei by constructing a phaseogram, where the differentially expressed genes are ordered according to the time point at which their expression peaks (Fig. 2a). For example, as reported previously [1], RNA polymerases (part of the transcription machinery) were highly expressed during the ring and early trophozoite stages and invasion-related genes during the late trophozoite and schizont stages (see Fig. 2b).

Next, a comparison was made between P. vinckei gene expression and the transcriptional cascade shown in P. falciparum [63]. Two thousand four hundred and eighty (2480) P. vinckei genes were ordered according to the expression values of their one-to-one orthologues in P. falciparum (from a total of 2712 P. falciparum genes profiled in [63]), and a similar temporal expression cascade as in [63] was obtained (see Fig. 2a).

The absence of any host depletion step reduces the proportion of sequencing reads of parasite origin and the final read coverage of parasite transcripts. In order to assess the impact of host contamination, the minimum depth of sequencing coverage required per sample to gain robust results during gene expression analysis was estimated.

Random subsampling of different sizes (1, 3.16, 10, 31.6 and 100% of the total reads) was performed for the 12 P. vinckei samples and differentially expressed genes were inferred in each case at a significance level (q-value) of 0.05. It was observed that the number of differentially expressed genes and their expression values (in all pairwise comparisons between the four time points) did not change drastically in subsamples of and above 31.6% of the total reads, which is equivalent to around 3 million paired-end reads per sample (see Additional file 2). Setting this as the target sequencing depth for an RMP transcriptome, sequencing and animal costs alone were calculated for different host contamination levels (10 to 80%) for a microsampling experiment and compared with a terminal blood sampling experiment. As the number of time points or biological replicates increase in the study design, microsamples with host contamination levels less than 70% would cost the same or less than terminal blood sampling (see Additional file 2). Differences in other costs incurred for animal housing and laboratory reagents between the two protocols were assumed to be negligible. These estimates were also made without considering the substantial manpower costs associated with the terminal blood sampling procedure.