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The eukaryotic parasite Trypanosoma brucei has evolved sophisticated strategies to persist within its mammalian host. Trypanosomes evade the hosts' immune system by antigenic variation of their surface coat, consisting of variant surface glycoproteins (VSGs). Out of a repertoire of thousands of VSG genes, only one is expressed at any given time from one of the 15 telomeric expression sites (ES). The VSG is stochastically exchanged either by a transcriptional switch of the active ES (in situ switch) or by a recombinational exchange of the VSG within the active ES. However, for infections to persist, the parasite burden has to be limited. The slender (sl) bloodstream form secretes the stumpy induction factor (SIF), which accumulates with rising parasitemia. SIF induces the irreversible developmental transition from the proliferative sl to the cell cycle-arrested but fly-infective stumpy (st) stage once a concentration threshold is reached. Thus, antigenic variation and st development ensure persistent infections and transmissibility. A previous study in monomorphic cells indicated that the attenuation of the active ES could be relevant for the development of trypanosomes. The present thesis investigated this hypothesis using the inducible overexpression of an ectopic VSG in pleomorphic trypanosomes, which possess full developmental competence. These studies revealed a surprising phenotypic plasticity: while the endogenous VSG was always down-regulated upon induction, the ESactivity determined whether the VSG overexpressors arrested in growth or kept proliferating. Full ES-attenuation induced the differentiation of bona fide st parasites independent of the cell density and thus represents the sole natural SIF-independent differentiation trigger to date. A milder decrease of the ES-activity did not induce phenotypic changes, but appeared to prime the parasites for SIF-induced differentiation. These results demonstrate that antigenic variation and development are linked and indicated that the ES and the VSG are independently regulated. Therefore, I investigated in the second part of my thesis how ES-attenuation and VSG-silencing can be mediated. Integration of reporters with a functional or defective VSG 3'UTR into different genomic loci showed that the maintenance of the active state of the ES depends on a conserved motif within the VSG 3'UTR. In situ switching was only triggered when the telomere-proximal motif was partially deleted, suggesting that it serves as a DNA-binding motif for a telomere-associated protein. The VSG levels seem to be additionally regulated in trans based on the VSG 3'UTR independent of the genomic context, which was reinforced by the regulation of a constitutively expressed reporter with VSG 3' UTR upon ectopic VSG overexpression.
The unicellular pathogen Trypanosoma brucei is the causative agent of African
trypanosomiasis, an endemic disease prevalent in sub-Saharan Africa. Trypanosoma brucei alternates between a mammalian host and the tsetse fly vector. The extracellular parasite survives in the mammalian bloodstream by periodically exchanging their ˈvariant surface glycoproteinˈ (VSG) coat to evade the host immune response. This antigenic variation is achieved through monoallelic expression of one VSG variant from subtelomeric ˈbloodstream
form expression sitesˈ (BES) at a given timepoint. During the differentiation from the bloodstream form (BSF) to the procyclic form (PCF) in the tsetse fly midgut, the stage specific surface protein is transcriptionally silenced and replaced by procyclins. Due to their subtelomeric localization on the chromosomes, VSG transcription and silencing is partly regulated by homologues of the mammalian telomere complex such as TbTRF, TbTIF2 and TbRAP1 as well as by ˈtelomere-associated proteinsˈ (TelAPs) like TelAP1. To gain more insights into transcription regulation of VSG genes, the identification and characterization of other TelAPs is critical and has not yet been achieved. In a previous study, two biochemical approaches were used to identify other novel TelAPs. By using ˈco-immunoprecipitationˈ (co-IP) to enrich possible interaction partners of TbTRF and by affinity chromatography using telomeric repeat oligonucleotides, a listing of TelAP candidates has been conducted. With this approach TelAP1 was identified as a novel component of the telomere complex, involved in the kinetics of transcriptional BES silencing during BSF to PCF differentiation. To gain further insights into the telomere complex composition, other previously enriched proteins were characterized through a screening process using RNA interference to deplete potential candidates. VSG expression profile changes and overall proteomic changes after depletion were analyzed by mass spectrometry. With this method, one can gain insights into the functions of the proteins and their involvement in VSG expression site regulation. To validate the interaction of proteins enriched by co-IP with TbTRF and TelAP1 and to identify novel interaction proteins, I performed reciprocal affinity purifications of the four most promising candidates (TelAP2, TelAP3, PPL2 and PolIE) and additionally confirmed colocalization of two candidates with TbTRF via immunofluorescence (TelAP2, TelAP3). TelAP3 colocalizes with TbTRF and potentially interacts with TbTRF, TbTIF2, TelAP1 and TelAP2, as well as with two translesion polymerases PPL2 and PolIE in BSF. PPL2 and PolIE seem to be in close contact to each other at the telomeric ends and fulfill different roles as only PolIE is involved in VSG regulation while PPL2 is not. TelAP2 was previously characterized to be associated with telomeres by partially colocalizing with TbTRF and cells show a VSG derepression phenotype when the protein was depleted. Here I show that TelAP2 interacts with the telomere-binding proteins TbTRF and TbTIF2 as well as with the telomere-associated protein TelAP1 in BSF and that TelAP2 depletion results in a loss of TelAP1 colocalization with TbTRF in BSF.
In conclusion, this study demonstrates that characterizing potential TelAPs is effective in gaining insights into the telomeric complex's composition and its role in VSG regulation in Trypanosoma brucei. Understanding these interactions could potentially lead to new therapeutic targets for combatting African trypanosomiasis.
For cellular viability, transcription is a fundamental process. Hereby, the DNA plays the most elemental and highly versatile role. It has long been known that promoters contain conserved and often well-defined motifs, which dictate the site of transcription initiation by providing binding sites for regulatory proteins. However, research within the last decade revealed that it is promoters lacking conserved promoter motifs and transcribing constitutively expressed genes that constitute the majority of promoters in eukaryotes. While the process of transcription initiation is well studied, whether defined DNA sequence motifs are required for the transcription of constitutively expressed genes in eukaryotes remains unknown. In the highly divergent protozoan parasite Trypanosoma brucei, most of the proteincoding genes are organized in large polycistronic transcription units. The genes within one polycistronic transcription unit are generally unrelated and transcribed by a common transcription start site for which no RNA polymerase II promoter motifs have been identified so far. Thus, it is assumed that transcription initiation is not regulated but how transcription is initiated in T. brucei is not known. This study aimed to investigate the requirement of DNA sequence motifs and chromatin structures for transcription initiation in an organism lacking transcriptional regulation. To this end, I performed a systematic analysis to investigate the dependence of transcription initiation on the DNA sequence. I was able to identify GT-rich promoter elements required for directional transcription initiation and targeted deposition of the histone variant H2A.Z, a conserved component during transcription initiation. Furthermore, nucleosome positioning data in this work provide evidence that sites of transcription initiation are rather characterized by broad regions of open and more accessible chromatin than narrow nucleosome depleted regions as it is the case in other eukaryotes. These findings highlight the importance of chromatin during transcription initiation. Polycistronic RNA in T. brucei is separated by adding an independently transcribed miniexon during trans-splicing. The data in this work suggest that nucleosome occupancy plays an important role during RNA maturation by slowing down the progressing polymerase and thereby facilitating the choice of the proper splice site during trans-splicing. Overall, this work investigated the role of the DNA sequence during transcription initiation and nucleosome positioning in a highly divergent eukaryote. Furthermore, the findings shed light on the conservation of the requirement of DNA motifs during transcription initiation and the regulatory potential of chromatin during RNA maturation. The findings improve the understanding of gene expression regulation in T. brucei, a eukaryotic parasite lacking transcriptional Regulation.
The protozoan parasite Trypanosoma brucei is the causal agent of sleeping sickness and besides its epidemiological importance it has been used as model organism for the study of many aspects of cellular and molecular biology especially the post-transcriptional control of gene expression.
Several studies in the last 30 years have shown the importance of mRNA processing and stability for gene regulation. In T. brucei genes are unusually arranged in polycistronic transcription units (PTUs) and a coupled process of trans-splicing and polyadenylation produces the mature mRNAs. Both processes, mRNA processing and stability, cannot completely explain the control of gene expression in the different life cycle stages analyzed in T. brucei so far.
In recent years, the relevance of expression regulation at the level of translation has become evident in other eukaryotes. Therefore, in the first part of my thesis I studied the impact of translational regulation by means of a genome-wide ribosome profiling approach. My data suggest that translational efficiencies vary between life cycle stages of the parasite as well as between genes within one life cycle stage. Furthermore, using ribosome profiling I was able to identify many new putative un-annotated coding sequences and to evaluate the coding potential of upstream open reading frames (uORF). Comparing my results with previously published proteomic and RNA interference (RNAi) target sequencing (RIT-seq) datasets allowed me to validate some of the new coding sequences and to evaluate their relevance for the fitness of the parasite.
In the second part of my thesis I used the transcriptomic and translatomic profiles obtained from the ribosome profiling analysis for the identification of putative non-coding RNAs (ncRNAs). These results led to the analysis of the coding potential in the regions upstream and downstream of the expressed variant surface glycoprotein (VSG), which is outlined in the third part of the results section. The region upstream of the VSG, the co-transposed region (CTR), has been implicated in an increase of the in situ switching rate upon its deletion. The ribosome profiling results indicated moderate transcription but not translation in this region. These results raised the possibility that the CTR may be transcribed into ncRNA. Therefore, in the third part of my thesis, I performed a primary characterization of the CTR-derived transcripts based on northern blotting and RACE. The results suggested the presence of a unique transcript species of about 1,200 nucleotides (nt) and polyadenylated at the 3’-end of the sequence.
The deletion of the CTR sequence promoting and increase of the in situ switching rates was performed around 20 years ago by means of inserting reporter genes. With the recent development of endonuclease-based tools for genome editing, it is now possible to delete sequences in a marker-free way. In the fourth part of my thesis, I show the results on the implementation of the highly efficient genome-editing CRISPR-Cas9 system in T. brucei using episomes. As a proof of principle, I inserted the sequence coding for the enhanced green fluorescent protein (eGFP) at the end of the SCD6 coding sequence (CDS). Fluorescent cells were observed as early as two days after transfection. Therefore, after the successful set up of the CRISPR-Cas9 system it will be possible to modify genomic regions with more relevance for the biology of the parasite, such as the substitution of codons present in gene tandem arrays.
The implementation of ribosome profiling in T. brucei opens the opportunity for the study of translational regulation in a genome-wide scale, the re-annotation of the currently available genome, the search for new putative coding sequences, the detection of putative ncRNAs, the evaluation of the coding potential in uORFs and the role of unstranslated regions (UTRs) in the regulation of translation. In turn, the implementation of the CRISPR-Cas9 system offers the possibility to manipulate the genome of the parasite at a nucleotide resolution and without the need of including resistant makers. The CRISPR-Cas9 system is a powerful tool for editing ncRNAs, UTRs, multicopy gene families and CDSs keeping their endogenous UTRs. Moreover, the system can be used for the modification of both alleles after just one round of transfection and of codons coding for amino acids carrying post-translational modifications (PTMs) among other possibilities.
Switches in trypanosome differentiation: ALBA proteins acting on post-transcriptional mRNA control
(2011)
Trypanosoma brucei is a digenetic eukaryotic parasite that develops in different tissues of a mammalian host and a tsetse fly. It is responsible for sleeping sickness in sub-saharan Africa. The parasite cycle involves more than nine developmental stages that can be clearly distinguished by their general morphology, their metabolism and the relative positioning of their DNA-containing organelles. During their development, trypanosomes remain exclusively extracellular and encounter changing environments with different physico-chemical properties (nutritional availability, viscosity, temperature, etc.). It has been proposed that trypanosomes use their flagellum as a sensing organelle, in agreement with the established role of structurally-related cilia in metazoa and ciliates. Recognition of environmental triggers is presumed to be at the initiation of differentiation events, leading to the parasite stage that is the best suited to the new environment. These changes are achieved by the modification of gene expression programmes, mostly underlying post-transcriptional control of mRNA transcripts. We first demonstrate that the RNA-binding proteins ALBA3/4 are involved in specific differentiation processes during the parasite development in the fly. They are cytosolic and expressed throughout the parasite cycle with the exception of the stages found in the tsetse fly proventriculus, as shown by both immunofluorescence and live cell analysis upon endogenous tagging with YFP. Knock-down of both proteins in the developmental stage preceding these forms leads to striking modifications: cell elongation, cell cycle arrest and relocalization of the nucleus in a posterior position, all typical of processes acting in parasites found in the proventriculus region. When ALBA3 is over-expressed from an exogenous copy during infection, it interferes with the relocalization of the nucleus in proventricular parasites. This is not observed for ALBA4 over-expression that does not visibly impede differentiation. Both ALBA3/4 proteins react to starvation conditions by accumulating in cytoplasmic stress granules together with DHH1, a recognized RNA-binding protein. ALBA3/4 proteins also partially colocalize with granules formed by polyA+ RNA in these conditions. We propose that ALBA are involved in trypanosome differentiation processes where they control a subset of developmentally regulated transcripts. These processes involving ALBA3/4 are likely to result from the specific activation of sensing pathways. In the second part of the thesis, we identify novel flagellar proteins that could act in sensing mechanisms. Several protein candidates were selected from a proteomic analysis of intact flagella performed in the host laboratory. This work validates their flagellar localization with high success (85% of the proteins examined) and defines multiple different patterns of protein distribution in the flagellum. Two proteins are analyzed during development, one of them showing down-regulation in proventricular stages. The functional analysis of one novel flagellar membrane protein reveals its rapid dynamics within the flagellum but does not yield a visible phenotype in culture. This is coherent with sensory function that might not be needed in stable culture conditions, but could be required in natural conditions during development. In conclusion, this work adds new pieces to the puzzle of identifying molecular switches involved in developmental mRNA control and environmental sensing in trypanosome stages in the tsetse fly.
Die Schlafkrankheit hat ihren Schrecken seit den Zeiten Robert Kochs und Paul Ehrlichs nicht verloren. Die zielgerichtete Entwicklung neuer Medikamente ist für die Menschen in den Endemiegebieten damals wie heute von elementarer Bedeutung. Die Naphtylisochinolin-Alkaloide stellen eine neue chemische Substanzklasse dar, die gute Kandidaten für die Entwicklung neuer Medikamente enthält. Mit GBAP 94 im speziellen liegt eine Substanz vor, die gute Startvorrausetzungen hierfür mitbringt. Diese sind eine sehr gute Wirksamkeit gegen Trypanosomen, gepaart mit einer hohen Selektivität durch einen sehr wahrscheinlich relativ spezifisch anti-trypanosomalen Wirkmechanismus. Die verwendeten Naphtylisochinolin-Alkaloide GBAP 94 und GBAP 146 wurden nach unterschiedlichen Gesichtspunkten ausgewählt. GBAP 94 wurde aufgrund seiner guten antitrypanosomalen Wirkung und seiner hohen Selektivität für Trypanosomen ausgewählt. Die IC50 liegt mit 0,383 µmol/l im Vergleich zu den aktuell verwendeten Medikamenten sehr niedrig. Die Selektivitätsindices (IC50 Trypanosoma brucei brucei / IC50 Makrophagen J774.1) mit 85,6 und (IC50 Try-panosoma brucei brucei / IC50 Leishmania major) mit 15,1 liegen in einem sehr günstigen Bereich. GBAP 146 wurde hauptsächlich wegen seiner guten Fluoreszenz-Eigenschaften ausgewählt. Die antitrypanosomale Aktivität ist mit einer IC50 von 0,289 µmol/l zwar sehr gut, eine große Selektivität ist aber nicht gegeben. Die beiden Alkaloide waren aufgrund ihrer Eigenfluoreszenz gut fluoreszenz-mikroskopisch in den Parasiten zu detektieren. Nach 10 min war in den ersten Trypanosomen die Anreicherung der Wirkstoffe erkennbar. Nach 30 min war bei fast allen Parasiten eine Färbung erkennbar. Die Wirkstoffe reicherten sich zunächst in mehreren kleinen Vakuolen an. Bei längeren Inkubationszeiten zeigte sich eine fast homogene Verteilung innerhalb des kompletten Parasiten. Durch-gängig ausgespart blieb eine vakuolische Struktur. Diese entwickelte oder vergrößerte sich im Verlauf der Inkubationszeit im vorderen Drittel des Parasiten, etwa im Bereich des Kinetoplasten. Diese Vakuole konnte auch lichtmikroskopisch in der Giemsa-Färbung nachgewiesen werden. Der Anteil der veränderten Trypanosomen lag bei diesen Untersuchungen nach 1 h bei 25,4%, stieg bis zum Zeitpunkt 2 h auf 46,6% und stabilisierte sich nach 4 h bei 44,8%. Die vakuolische Struktur führte durch ihre Vergrößerung zur zunehmenden Verplumpung der Trypanosomen bis zu einer kugelförmigen Zellform mit geisselartig-wirkender Flagelle. Aufgrund der veränderten Form wurden die Zellorganellen verdrängt. Dies konnte durch die Fluoreszenzmarkierung des Mitochondriums mit Rodamine B Hexylester und der sauren Kompartimente, besonders des Lysosoms, mit LysoTracker® gezeigt werden. Die Vakuolisierung von Trypanosomen im Zusammenhang mit Apoptose ist bekannt. Die neu entstehende Vakuole konnte weder mit LysoTracker® green, noch mit dem endosomalen Farbstoff FM 4-64 angefärbt werden. Damit können eine lysosomale und eine endosomale Herkunft der Vakuole ausgeschlossen werden. Eine genaue Klärung der Genese der Vakuole steht noch aus. In den Untersuchungen mit Annexin V und Propidium-Jodid im FACS® konnte gezeigt werden, dass die Wirkung der NIQs sehr wahrscheinlich Apoptose induziert. Annexin V ist auch bei Trypanosomen als Marker für Apoptose etabliert. Zudem zeigte sich ein Anstieg der Anzahl apoptotischer Trypanosomen mit Periode von 6 h – 8 h. Diese Dauer entspricht ungefähr der Dauer des trypanosomalen Zellzyklus. Ein Eingriff der NIQs in den Zellzyklus ist somit sehr wahrscheinlich. Eine Hemmung von Teilen des Zellzyklus ist als Auslöser für Apoptose bekannt. Über die genaue Zielstruktur der NIQs kann allerdings nur spekuliert werden. Die apotose-induzierende Wirkung anderer Alkaloide auf Trypanosomen ist inzwischen nachgewiesen. Ein weiteres Indiz ist, dass die Ergebnisse von Ponte-Sucre mit den NIQs bei Leishmanien ebenfalls in Richtung Apoptose weisen.
While gene expression is a fundamental and tightly controlled cellular process that is regulated at multiple steps, the exact contribution of each step remains unknown in any organism. The absence of transcription initiation regulation for RNA polymerase II in the protozoan parasite Trypanosoma brucei greatly simplifies the task of elucidating the contribution of translation to global gene expression. Therefore, we have sequenced ribosome-protected mRNA fragments in T. brucei, permitting the genome-wide analysis of RNA translation and translational efficiency. We find that the latter varies greatly between life cycle stages of the parasite and ∼100-fold between genes, thus contributing to gene expression to a similar extent as RNA stability. The ability to map ribosome positions at sub-codon resolution revealed extensive translation from upstream open reading frames located within 5' UTRs and enabled the identification of hundreds of previously un-annotated putative coding sequences (CDSs). Evaluation of existing proteomics and genome-wide RNAi data confirmed the translation of previously un-annotated CDSs and suggested an important role for >200 of those CDSs in parasite survival, especially in the form that is infective to mammals. Overall our data show that translational control plays a prevalent and important role in different parasite life cycle stages of T. brucei.
In the mammalian host, the Trypanosoma brucei cell surface is covered with a densely packed protein coat of a single protein, the variant surface glycoprotein (VSG). The VSG is believed to shield invariant surface proteins from host antibodies but there is limited information on how far antibodies can penetrate into the VSG monolayer. Here, the VSG surface coat was probed to determine whether it acts as a barrier to binding of antibodies to the membrane proximal VSG C-terminal domain. The binding of C-terminal domain antibodies to VSG221 or VSG118 was compared with antibodies recognising the cognate whole VSGs. The C-terminal VSG domain was inaccessible to antibodies on live cells but not on fixed cells. This provides further evidence that the VSG coat acts as a barrier and protects the cell from antibodies that would otherwise bind to some of the other externally disposed proteins.
Base J, β-D-glucosyl-hydroxymethyluracil, is a chromatin modification of thymine in the nuclear DNA of flagellated protozoa of the order Kinetoplastida. In Trypanosoma brucei, J is enriched, along with histone H3 variant (H3.V), at sites involved in RNA Polymerase (RNAP) II termination and telomeric sites involved in regulating variant surface glycoprotein gene (VSG) transcription by RNAP I. Reduction of J in T. brucei indicated a role of J in the regulation of RNAP II termination, where the loss of J at specific sites within polycistronic gene clusters led to read-through transcription and increased expression of downstream genes. We now demonstrate that the loss of H3.V leads to similar defects in RNAP II termination within gene clusters and increased expression of downstream genes. Gene derepression is intensified upon the subsequent loss of J in the H3.V knockout. mRNA-seq indicates gene derepression includes VSG genes within the silent RNAP I transcribed telomeric gene clusters, suggesting an important role for H3.V in telomeric gene repression and antigenic variation. Furthermore, the loss of H3.V at regions of overlapping transcription at the end of convergent gene clusters leads to increased nascent RNA and siRNA production. Our results suggest base J and H3.V can act independently as well as synergistically to regulate transcription termination and expression of coding and non-coding RNAs in T. brucei, depending on chromatin context (and transcribing polymerase). As such these studies provide the first direct evidence for histone H3.V negatively influencing transcription elongation to promote termination.
Many arthropods such as mosquitoes, ticks, bugs, and flies are vectors for the transmission of pathogenic parasites, bacteria, and viruses. Among these, the unicellular parasite Trypanosoma brucei (T. brucei) causes human and animal African trypanosomiases and is transmitted to the vertebrate host by the tsetse fly. In the fly, the parasite goes through a complex developmental cycle in the alimentary tract and salivary glands ending with the cellular differentiation into the metacyclic life cycle stage. An infection in the mammalian host begins when the fly takes a bloodmeal, thereby depositing the metacyclic form into the dermal skin layer. Within the dermis, the cell cycle-arrested metacyclic forms are activated, re-enter the cell cycle, and differentiate into proliferative trypanosomes, prior to dissemination throughout the host.
Although T. brucei has been studied for decades, very little is known about the early events in the skin prior to systemic dissemination. The precise timing and the mechanisms controlling differentiation of the parasite in the skin continue to be elusive, as does the characterization of the proliferative skin-residing trypanosomes. Understanding the first steps of an infection is crucial for developing novel strategies to prevent disease establishment and its progression.
A major shortcoming in the study of human African trypanosomiasis is the lack of suitable infection models that authentically mimic disease progression. In addition, the production of infectious metacyclic parasites requires tsetse flies, which are challenging to keep. Thus, although animal models - typically murine - have produced many insights into the pathogenicity of trypanosomes in the mammalian host, they were usually infected by needle injection into the peritoneal cavity or tail vein, bypassing the skin as the first entry point. Furthermore, animal models are not always predictive for the infection outcome in human patients. In addition, the relatively small number of metacyclic parasites deposited by the tsetse flies makes them difficult to trace, isolate, and study in animal hosts.
The focus of this thesis was to develop and validate a reconstructed human skin equivalent as an infection model to study the development of naturally-transmitted metacyclic parasites of T. brucei in mammalian skin. The first part of this work describes the development and characterization of a primary human skin equivalent with improved mechanical properties. To achieve this, a computer-assisted compression system was designed and established. This system allowed the improvement of the mechanical stability of twelve collagen-based dermal equivalents in parallel through plastic compression, as evaluated by rheology. The improved dermal equivalents provided the basis for the generation of the skin equivalents and reduced their contraction and weight loss during tissue formation, achieving a high degree of standardization and reproducibility. The skin equivalents were characterized using immunohistochemical and histological techniques and recapitulated key anatomical, cellular, and functional aspects of native human skin. Furthermore, their cellular heterogeneity was examined using single-cell RNA sequencing - an approach which led to the identification of a remarkable repertoire of extracellular matrix-associated genes expressed by different cell subpopulations in the artificial skin. In addition, experimental conditions were established to allow tsetse flies to naturally infect the skin equivalents with trypanosomes.
In the second part of the project, the development of the trypanosomes in the artificial skin was investigated in detail. This included the establishment of methods to successfully isolate skin-dwelling trypanosomes to determine their protein synthesis rate, cell cycle and metabolic status, morphology, and transcriptome. Microscopy techniques to study trypanosome motility and migration in the skin were also optimized. Upon deposition in the artificial skin by feeding tsetse, the metacyclic parasites were rapidly activated and established a proliferative population within one day. This process was accompanied by: (I) reactivation of protein synthesis; (II) re-entry into the cell cycle; (III) change in morphology; (IV) increased motility. Furthermore, these observations were linked to potentially underlying developmental mechanisms by applying single-cell parasite RNA sequencing at five different timepoints post-infection.
After the initial proliferative phase, the tsetse-transmitted trypanosomes appeared to enter a reversible quiescence program in the skin. These quiescent skin-residing trypanosomes were characterized by very slow replication, a strongly reduced metabolism, and a transcriptome markedly different from that of the deposited metacyclic forms and the early proliferative trypanosomes. By mimicking the migration from the skin to the bloodstream, the quiescent phenotype could be reversed and the parasites returned to an active proliferating state. Given that previous work has identified the skin as an anatomical reservoir for T. brucei during disease, it is reasonable to assume that the quiescence program is an authentic facet of the parasite's behavior in an infected host.
In summary, this work demonstrates that primary human skin equivalents offer a new and promising way to study vector-borne parasites under close-to-natural conditions as an alternative to animal experimentation. By choosing the natural transmission route - the bite of an infected tsetse fly - the early events of trypanosome infection have been detailed with unprecedented resolution. In addition, the evidence here for a quiescent, skin-residing trypanosome population may explain the persistence of T. brucei in the skin of aparasitemic and asymptomatic individuals. This could play an important role in maintaining an infection over long time periods.