Amblyomma americanum ticks utilizes countervailing pro and anti-inflammatory proteins to evade host defense
Authors:
Mariam Bakshi aff001; Tae Kwon Kim aff001; Lindsay Porter aff001; Waithaka Mwangi aff001; Albert Mulenga aff001
Authors place of work:
Department of Veterinary Pathobiology, College of Veterinary Medicine, TAMU, College Station, Texas, United States of America
aff001; Department of Diagnostic Medicine/Pathobiology, College of Veterinary Medicine, Kansas State University, Manhattan, Kansas, United States of America
aff002
Published in the journal:
Amblyomma americanum ticks utilizes countervailing pro and anti-inflammatory proteins to evade host defense. PLoS Pathog 15(11): e32767. doi:10.1371/journal.ppat.1008128
Category:
Research Article
doi:
https://doi.org/10.1371/journal.ppat.1008128
Summary
Feeding and transmission of tick-borne disease (TBD) agents by ticks are facilitated by tick saliva proteins (TSP). Thus, defining functional roles of TSPs in tick evasion is expected to reveal potential targets in tick-antigen based vaccines to prevent TBD infections. This study describes two types of Amblyomma americanum TSPs: those that are similar to LPS activate macrophage (MΦ) to express pro-inflammation (PI) markers and another set that suppresses PI marker expression by activated MΦ. We show that similar to LPS, three recombinant (r) A. americanum insulin-like growth factor binding-related proteins (rAamIGFBP-rP1, rAamIGFBP-rP6S, and rAamIGFBP-rP6L), hereafter designated as PI-rTSPs, stimulated both PBMC -derived MΦ and mice RAW 267.4 MΦ to express PI co-stimulatory markers, CD40, CD80, and CD86 and cytokines, TNFα, IL-1, and IL-6. In contrast, two A. americanum tick saliva serine protease inhibitors (serpins), AAS27 and AAS41, hereafter designated as anti-inflammatory (AI) rTSPs, on their own did not affect MΦ function or suppress expression of PI markers, but enhanced expression of AI cytokines (IL-10 and TGFβ) in MΦ that were pre-activated by LPS or PI-rTSPs. Mice paw edema test demonstrated that in vitro validated PI- and AI-rTSPs are functional in vivo since injection of HEK293-expressed PI-rTSPs (individually or as a cocktail) induced edema comparable to carrageenan-induced edema and was characterized by upregulation of CD40, CD80, CD86, TNF-α, IL-1, IL-6, and chemokines: CXCL1, CCL2, CCL3, CCL5, and CCL11, whereas the AI-rTSPs (individually and cocktail) were suppressive. We propose that the tick may utilize countervailing PI and AI TSPs to regulate evasion of host immune defenses whereby TSPs such as rAamIGFBP-rPs activate host immune cells and proteins such as AAS27 and AAS41 suppress the activated immune cells.
Keywords:
Cytokines – inflammation – immune cells – chemokines – Secretion – Saliva – Ticks
Introduction
Ticks are among the most important ecto-parasites with global public and veterinary health impact. In terms of diversity of transmitted disease pathogens, ticks far outpace any known vector arthropod, and are considered second to mosquitoes in terms of impact of the transmitted disease pathogens. In the livestock industry, losses due to ticks and tick-borne diseases (TBD) are estimated to be worth millions of US dollars annually [1]. Globally, the impact of TBD in public health has been on the rise, with the food-for-thought article on “One Health” listing several TBDs among sources of human health concerns needing One Health solutions [2]. Similarly, of the 23 human vector-borne diseases (VBD) that were listed by the World Health Organization, seven are TBD agents: Crimean-Congo hemorrhagic fever, Lyme disease, relapsing fever (borreliosis), rickettsial diseases (spotted fever and Q fever), tick-borne encephalitis, and tularemia (http://www.who.int/mediacentre/factsheets/fs387/en/). In the United States, the Centers for Disease Control (CDC) listed 16 human TBD agents (http://www.cdc.gov/ticks/diseases), six of which were transmitted by Ixodes scapularis and four by Amblyomma americanum ticks. Additionally, six human TBD agents were listed on the 2018 National Notifiable human VBD in the USA and its territories. In fact, from 2004 to 2016, the six human TBDs accounted for nearly 77% of human VBDs in the USA and its territories [3].
In the absence of effective vaccines against major TBD agents, controlling ticks using acaricides remains the only method to protect animals and humans against TBD infections [4]. Serious limitations such as environmental contamination and ticks developing resistance that threaten acaricide-based tick control have justified the need to develop alternative tick control methods [5–8]. Immunization of animals against tick feeding has been validated as an alternative method [9]. The approach is attractive because it is environmentally friendly and is postulated to be effective against both susceptible and acaricide-resistant tick populations. The limiting step is the availability of effective vaccine antigens. Except for a few instances when human TBD infections occurred after exposure to contaminated materials [10–16], transmission of both animal and human TBD agents occur during tick feeding. Thus, a deeper understanding of how the tick accomplishes feeding is a rational approach through which vaccine targets can be identified [17–21].
Host inflammatory response is the first line of defense against the tick feeding style of disrupting host tissue and sucking up blood. Macrophages (MΦ), which have been confirmed to infiltrate the tick feeding site [22–25] are among key effector cells of the inflammatory response. Importantly, MΦ act as a bridge between innate and adaptive immunity [26, 27]. From this perspective, it is logical that parasites including ticks might target MΦ to evade host immune defenses. A limited number of studies have documented immuno-modulatory effects against MΦ functions by mostly yet undefined tick salivary factors. Salivary gland protein extracts (SGE) of fully fed Rhipicephalus microplus suppressed expression of pro-inflammatory (PI) co-stimulatory markers CD86 and CD69, but not CD40 and CD80 by LPS-activated MΦ (92). The same authors found that R. microplus SGE suppressed secretion of PI cytokines by LPS activated MΦ [28]. Likewise, SGE of D. variabilis inhibited secretion of PI cytokines by LPS-activated MΦ [29]. In this same study, D. variabilis tick saliva proteins stimulated MΦ to secrete copious amounts of prostaglandin 2, which in turn stimulated fibroblast migration. In a related study, D. variabilis tick saliva was shown to increase both basal and platelet-derived growth factor stimulated migration of MΦ [30]. In another study, Amblyomma variegatum tick saliva proteins were shown to suppress expression of MHC-II, CD40, CD80, IL-12-p40, and TNF-α, but increased IL-10 expression by MΦ [31]. Similar immuno-modulatory effects against MΦ functions were also reported in Rhipicephalus sanguineus [32]. These studies clearly indicated that ticks target MΦ functions in their quest to evade host immune defenses and facilitate feeding and transmission of TBD agents.
At the time of drafting this manuscript few defined tick proteins that modulated MΦ functions were reported including a pro-inflammatory MΦ migration inhibitory factor has been described in ticks including A. americanum [33–36], but function was not validated. In another study, Ixodes scapularis cystatin was shown to affect MΦ function in response to Anaplasma phagocytophilum infection [37]. Here, we report that similar to LPS, A. americanum insulin-like growth factor binding protein-related proteins (AamIGFBP-rP1, AamIGFBP-rP6L, and AamIGFBP-rP6S) [38, 39] stimulated MΦ to express PI markers. Interestingly, we also show that A. americanum serine protease (AAS) inhibitors (serpin)-27 and 41 [40], blocked LPS and AamIGFBP-rPs activated MΦ to express PI markers. We have described our findings with reference to understanding molecular mechanisms that regulate tick feeding.
Results
Amblyomma americanum insulin-like growth factors (rAamIGFBP-rP1, rAamIGFBP-rP6S, and rAamIGFBP-rP6L) induced pro-inflammatory response in macrophages (MΦ)
Flow cytometric analyses was used to demonstrate that similar to LPS, [39] HEK293-expressed rAamIGFBP-rP1, rAamIGFBP-rP6S, and rAamIGFBP-rP6L (Fig 1) stimulated mice RAW 267 MΦ to significantly express PI co-stimulatory markers, CD40, CD80, and CD86 (Fig 2).
Low (0.1 μg/ml) and medium (1 μg/mL) of doses of rAamIGFBP-rP1 induced significant expression of CD40 and CD80 (Fig 2A and 2B) but not CD86 (Fig 2C). For AamIGFBP-rP6L, all three doses induced high expression of CD40 (Fig 2D), CD80 by the low and high dose (Fig 2E), and CD86 by high dose (Fig 2F). Similarly, all doses of rAamIGFBP-rP6S induced significant expression of CD40 (Fig 2G), while significant expression of both CD80 and CD86 were observed at the high dose (Fig 2H and 2I).
We further analyzed the effects on MΦ expression of PI cytokines (Fig 3). Furthermore, ELISA results determined the expression of PI cytokines showed that rAamIGFBP-rP1- and rAamIGFBP-rP6L- treated MΦ induced expression of TNF-α and IL-6 (Fig 3). The effects of rAamIGFBP-rP1 and AamIGFBP-rP6L displayed a dichotomous effect on TNFα expression: whereas transcription was not affected (Fig 3A and 3C), it was secreted at significant levels in high dose rAamIGFBP-rP1 (Fig 3B) and low dose rAamIGFBP-rP6L (Fig 3D). In rAamIGFBP-rP6S treated MΦ, the effect was opposite: the high dose induced significant TNF-α transcript but had no effect on its secretion (Fig 3F). In the case of IL-6, both rAamIGFBP-rP1 and AamIGFBP-rP6L apparently induced transcription and secretion (Fig 3G, 3H, 3I and 3J), while rAamIGFBP-rP6S had not effect (Fig 3K and 3L).
We next tested the synergistic effect of the three PI-rTSPs as a cocktail (Fig 4). It is interesting to note that secretion levels of TNF-α, IL-1, and IL-6, were statistically similar to levels that were induced by LPS activated of MΦ (Fig 4A, 4B and 4C). Treatment of MΦ with the PI-rTSP cocktail might have over activated the cells in that AI cytokines, IL-10 (Fig 4D) and TGFβ (Fig 4E) were also significantly induced.
Next, we tested the effects of PI-rTSPs cocktail on MΦ morphology (Fig 4F). Confocal microscopy revealed that PI-rTSPs activated MΦ had the morphology that was similar to LPS activated MΦ as indicated by stretched spindle-like shaped cells compared to smooth and round cells in the media only control (Fig 4F). Altogether, results from the in vitro study confirmed that the PI-rTSPs stimulated MΦ to express PI markers.
AAS27 and AAS41 suppressed expression of pro-inflammatory, but enhanced anti-inflammatory markers by LPS- and PI-rTSPs-activated MΦ
Preliminary findings suggested that rAAS27 and rAAS41 on their own did not affect MΦ function but might have affected functions of activated cells. Flow cytometric analyses showed that the rAAS27 and rAAS41 cocktail rTSPs (0.1, 1 and 10μg/mL) respectively suppressed the expression of CD40, CD80, and CD86 by 43–48%, 16–28%, and 9–13% by MΦ that were pre-activated with LPS (Fig 5A1-9). Likewise, though moderately and not significant, AI-rTSP respectively suppressed expression of CD40, CD80, and CD86 by ~7–10%, ~2–3%, and 2–15% by PI-rTSP activated MΦ (Fig 5B1-9).
We next analyzed cytokine secretion and ELISA revealed that both rAAS27 and rAAS41 suppressed cytokine expression by LPS-activated MΦ (Fig 6).Low (0.1 μg/ml) and medium dose (1 μg/ml) of rAAS27 and rAAS41 significantly suppressed TNF-α secretion by 30–37% and 52–57% respectively (Fig 6A and 6B). Likewise, the medium (1 μg/ml) dose of rAAS27 suppressed secretion of IL-1 (Fig 6C) and IL-6 (Fig 6E) by 24.85% and 18% respectively (Fig 6E). Similarly, middle and high dose of rAAS41 significantly reduced secretion of IL-1 by up to ~29.32% (Fig 6D) and IL-6 by up to 21.63% (Fig 6F).
We next investigated the effects of the AI-rTSP cocktail on expression of cytokines by MΦ that were first activated by LPS or PI-rTSPs (Fig 7). Except for TNFα, which was apparently suppressed, but not significantly (Fig 7A), there was no effect on IL-1, IL-6, and IL-10 expression by LPS-activated MΦ (Fig 7B, 7C and 7D). In Fig 7E, the AI-rTSP cocktail moderately but not significantly enhanced secretion of TGFβ in LPS activated MΦ. With exception of TNF-α, which was significantly suppressed by the highest dose (Fig 7F), expression of IL-1, IL-6, IL-10, and TGFβ were enhanced when PI-rTSP activated MΦ were treated with the AI-rTSP cocktail (Fig 7G, 7H, 7I and 7J).
PI-rTSPs and AI-rTSPs are functional in vivo
Paw edema induction confirmed that cell culture validated PI-rTSP and AI-rTSP were functional in vivo (Fig 8). The high dose (25 μg) of the PI-rTSP cocktail progressively induced edema through 24 h (Fig 8A). Four statistically significant edema points were observed at 20 min (p≤0.05), 240 min (p≤0.05), 480 min (p≤0.05), and at 1440 min (p≤0.01) in PI-rTSPs and AI-rTSPs treatments. In contrast, co-injecting high dose of AI-rTSP cocktail (25 μg) significantly suppressed PI-rTSP-induced edema at 120 (p≤0.05), 240, 480, and 1440 mins, respectively. Injection of individual rAamIGFBP-rP6L (25 μg) caused edema that peaked at 480 min and 1440 min (p≤0.05), while rAamIGFBP-rP6S induced edema that peaked at 20 min, 40 min, 240 min, and 1440 min (p≤0.05)] (Fig 8B). On the other hand, rAamIGFBP-rP1 did not cause detectable edema (Fig 8B).
To rule out the effect of too much protein being injected, we repeated the assay with 10 μg of the low dose cocktail. Consistent with the high dose, injection of 10 μg of the PI-rTSP cocktail induced significant edema that was observed at 20 (p≤0.001) min and at 60 min (p≤0.05) (Fig 8C). Likewise, when co-administered with low dose (10 μg) AI-rTSP cocktail, edema was significantly reduced at 20 (p≤0.001), 40 (p≤0.05), 60 (p≤0.05) and 120 min (Fig 8C). In animals that were injected with individual PI-rTSPs (10 μg), rAamIGFBP-rP6S induced edema that was observed between 20–130 min, while rAamIGFBP-rP6L induced edema that was observed at 130 min (Fig 8D), but not rAamIGFBP-rP1.
PI-rTSP and AI-rTSP differentially regulated inflammatory markers in mice paws
Effects of PI-rTSPs and AI-rTSPs on inflammation marker expression were investigated by qPCR (Figs 9–11). Consistent with cell culture data (Fig 2), PI co-stimulatory markers, CD40, CD80, and CD86 were up regulated in mice that were injected with low dose individual PI-rTSPs (10 μg) and processed at 120 min post injection (Fig 9A, 9B and 9C). Expression of CD40 was significantly enhanced in mice that were injected with low dose rAamIGFBP-rP1 and rAamIGFBP-rP6L, but not rAamIGFBP-rP6S (Fig 9A). Likewise, CD80 was significantly induced by low dose rAamIGFBP-rP1 but not rAamIGFBP-r6L and rAamIGFBP-rP6S (Fig 9B). For CD86, induction was apparent but it was not significant (Fig 9C). In mice that were injected with high dose individual PI-rTSP (25 μg) and processed at 24 h post injection, all three co-stimulatory markers were induced (but not significantly) in rAamIGFBP-rP1-injected animals, but not rAamIGFBP-r6L and rAamIGFBP-rP6S (Fig 9D, 9E and 9F). In contrast, injecting high dose of the PI-rTSP cocktail significantly induced expression of CD40, CD80, and CD86 above normal saline control, while co-injecting with the high dose of AI rTSP cocktail suppressed transcription of CD40 and CD86 by 70% and by 50% for CD80 (Fig 9G, 9H and 9I).
Fig 10 summarizes expression of PI and AI cytokines in PI-rTSP induced edema. TNF-α, IL-1, and IL-6 were significantly expressed in low dose individual (Fig 10A, 10B and 10C) and PI-rTSP cocktail (Fig 10E, 10F and 10G) treatment. In contrast, except for IL-1, which was slightly enhanced (Fig 10J), expression of TNF-α and IL-6 was below negative control in animals that were injected with high dose (25 μg) of the individual PI-rTSP (Fig 10I and 10K). Except for TNF-α which was significantly up regulated above normal saline (Fig 10M), other transcripts were apparently up regulated but not significantly (Fig 10N, 10O and 10P).
Co-injecting with the low dose of AI-rTSP had mixed effects on expression of the four cytokines (Fig 10E–10H). In low dose-treated mice, co-injecting AI-rTSP suppressed TNFα by ~35% and IL-6 by 62% (Fig 10E and 10G), but not IL-1 (Fig 10F). Likewise, co-injecting with high dose AI-rTSP reduced expression of TNFα by 74% (Fig 10M), while IL-1 and IL-6 were apparently enhanced but not significantly (Fig 10N and 10O). Also notable, the TGFβ transcript was induced in animals that were injected with low dose of the individual PI-rTSPs (Fig 10D) as well as the high dose of the PI-rTSP cocktail (Fig 10P), but not the low dose cocktail (Fig 10H) and high dose individual PI-rTSP (Fig 10L).
The effects of PI-rTSPs and AI-rTSPs on chemokine transcription mirrored cytokine expression. Notably, chemokine transcription was significantly upregulated in mice that were injected with low dose, individual (11A, B, C, D, E) or cocktail (Fig 11F, 11G, 11H and 11I) PI-rTSP with exception of CCL5, for which there was no amplification. Except for CCL5 (Fig 11M), which was upregulated in high dose of the individual PI-rTSPs, other chemokines tested were expressed below normal saline injected controls (Fig 11J, 11K, 11L and 11N). In animals that were injected with high dose of the PI-rTSP cocktail, all chemokines were up regulated (Fig 11O, 11P, 11Q, 11R and 11S). Also, notable, co-injecting with the high dose AI-rTSP cocktail suppressed expression of CXCL1, CCL2, CCL3, and CCL11 by ~50%, 53%, 65%, and 72% respectively (Fig 11O, 11P, 11Q and 11S) and CCL5 which was enhanced (Fig 11R).
Discussion
Hard ticks successfully feed and transmit tick borne disease (TBD) agents by secreting numerous tick saliva proteins (TSPs) to thwart the host’s immune defenses, which would otherwise reject the tick. Thus, discovery of tick immuno-modulatory TSPs is highly sought after as these might serve as targets in tick-antigen based vaccines to prevent TBD infections. This study provides evidence to suggest that A. americanum ticks might utilize countervailing functions of PI proteins to regulate the evasion of host immune defenses. Our in vitro and in vivo data in this study has demonstrate that AamIGFBP-rP-1, AamIGFBP-rP6S, and AamIGFBP-rP6L (38, 39) activated MΦ to express PI markers, whereas A. americanum AAS27 and AAS41 suppressed expression of PI markers by activated MΦ. This study builds on our previous studies that showed that AamIGFBP-rP-1, AamIGFBP-rP6S, and AamIGFBP-rP6L were up regulated when ticks were stimulated to start feeding [38, 41], were immunogenic and injected into the host within 24–48 h after attachment [42], and if disrupted by RNAi silencing prevented successful tick feeding [43]. Likewise, the observed AI effects of rAAS27 and rAAS41 in this study is in agreement with our recent studies that showed that AAS27 might inhibit inflammation by targeting trypsin and plasmin and AAS41 by targeting chymase and chymotrypsin [44].
Although not yet determined at the tick feeding site, activated MΦ at an inflamed site occur in a spectrum that is bordered by classically activated PI (M1) and alternately activated (M2) anti-inflammation phenotypes [45]. Broadly, the M1 phenotype is induced at the front end of an immune reaction, and the M2 at the tail end of an immune response to resolve the inflammatory response. M1 MΦ express multiple factors that drive inflammation including co-stimulatory markers, CD40, CD80, and CD86, cytokines such as TNF-α, IL-1β, IL-6, and IL-12, oxygen intermediates and reactive nitrogen species such as nitric oxide (NO) [46–50]. On the other hand, M2 MΦ express factors that lead to resolution of inflammation to protect against self-injury (50). On this basis, we speculate that PI-rTSPs in this study might activate skin resident MΦ to the M1 phenotype to drive local inflammation, while AI-rTSPs, which enhanced expression of anti-inflammation markers might play roles in resolution or moderation of TSP-induced inflammation. The observation that both rAAS27 and rAAS41 reduced the expression of PI markers by both LPS- and PI-rTSPs-activated MΦ was not surprising in that several studies have previously reported tick immuno-suppressive effects against skin immune cells in tick saliva [51–55]. However, the findings that rAAS27 and rAAS41 did not apparently affect non-activated MΦ, but selectively affected functions of MΦ that were spontaneously activated or pre-activated by LPS and PI-rTSP was intriguing. From the perspective of tick feeding physiology and tick transmission of TBD agents, data in this study raise interesting future research questions. For instance, it would be interesting to further explore the effect of rAAS27 and rAAS41 reversing MΦ that were pre-activated by PI-rTSP on the outcome of an immune response to TBD agents. A notable observation in our flow cytometry data was that, AI-rTSPs were much more effective against LPS-activated MΦ than PI-rTSP. Interestingly, TBD agents such as B. afzelii, B. burgdorferi [56, 57], E. chaffeensis [58], A. phagocytophilum [59] and, Powassan virus [60] can activate MΦ to express high levels of PI cytokines. However, this does not seem to limit colonization of the host by transmitted TBD agents. Also, interestingly, clinical outcomes of TBD infections are more pronounced when TBD agents are co-inoculated with tick saliva proteins [31]. Given the finding that rAAS27 and rAAS41 reversed activated MΦ, it is possible that AI-TSPs described here could prevent MΦ from killing transmitted TBD agents, which ultimately could aid pathogen transmission. Several studies have reported that tick saliva/SGE of different tick species including A. variegatum, I. scapularis, R. microplus, R. appendiculatus, R. sanguineous, and D. variabilis suppressed expression of PI markers by MΦ that were first activated by LPS or were exposed to pathogens [29, 61–64]. Given our observations that AAS27 and AAS41 suppressed expression of pro-inflammation markers by LPS-activated MΦ, it is potentially possible that the immunosuppressive effects observed in tick saliva/SGE of different tick species could be mediated by AAS27 and AAS41 homologs.
Skin inflammation in response to tick bites in humans and rodents were characterized by high expression of multiple PI cytokines and chemokines [65–67]. On this basis, we suspect that high expression of PI cytokines and chemokines in PI-rTSP-induced edema suggests that these proteins could play roles in mediating tick and host interactions. An inflammatory response is characterized by infiltration of multiple innate immune cells including mast cells, MΦ, and neutrophils [41, 68–70]. Although we did not conduct immuno-histochemical staining and cellular imaging of inflamed paws to enumerate immune cells, the observed high expression of cytokines and chemokines, which are expressed by various immune cells possibly suggest an influx of immune cells into PI-rTSP injected paws. Specifically, the observation of high expression of PI co-stimulatory markers, CD40, CD80, and CD86, which are mostly produced by the M1 MΦ phenotype [71], could suggest the presence of these cells in injected paws. Chemokines that were investigated in this study were selected for their roles in attracting immune cells to the site of inflammation [72, 73]. Therefore, the observed high expression of chemokines suggested that the edema formation was a result of various cellular migration at the inflamed site.
The findings in this study are not unique as pro-inflammation tick proteins including a tick histamine release factor and an 84 kDa tick serine protease, were previously reported [74, 75]. Given the expectation that in order to complete feeding, ticks must evade the host’s innate immune defense response against tick feeding that also include inflammation, our findings in this study may be considered counterintuitive. However, from the perspective of tick feeding physiology, inflammation can be beneficial to tick feeding as it might lead to increased blood flow into the feeding site benefiting the tick in acquiring the blood meal. Additionally, the increased flow of inflammatory cell monocytes into the inflamed tick feeding site might result in enhanced transmission of A. americanum transmitted TBD agents such as Bourbon virus, Heartland virus, and E. chaffeensis that have tropisms for inflammatory cells including MΦ [76, 77].
It is also important to note that treating MΦ with high dose (10 μg) of PI-rTSP cocktail also induced expression of an anti-inflammation cytokines, IL-10, which conforms to the M2 MΦ phenotype. We are of the view that, the higher concentration of PI-rTSP over-stimulated MΦ to the extent the correct anti-inflammation response was triggered. Similarly, we also observed that, with exception of TNFα, other cytokines, IL-1, IL-6, IL-10, and TGFβ were enhanced in MΦ that were first treated with PI-rTSP for 24 h followed by AI-rTSP for another 24 h. Whether or not, these findings occur physiologically remains to be investigated. Like most functional analysis studies of recombinant tick saliva proteins, the limitation is that the amount of native TSPs that are injected into the host during tick feeding is unknown, and thus future studies to define functional roles of native proteins are required.
In conclusion, we have proposed that A. americanum tick might utilize countervailing functions of pro- and anti- inflammatory proteins to regulate evasion of host defenses. Our proposal is that the tick first secrets PI-TSPs that stimulate MΦ into the pro-host defense phenotype and then secretes AI-TSPs to de-activate the activated immune cells including MΦ. This proposal assumes that proteins in this study were sequentially secreted during tick feeding. The findings in this study warrants further investigations into functional roles of proteins in this study in transmission of TBD agents, and their utility as anti-tick vaccine antigens.
Materials and methods
Ethical statement
Healthy, pathogen-free BALB/c mice were purchased from Charles River laboratories (Wilmington, MA). Animal experiments were done according to the animal use protocol (#2015–0079) approved by Texas A&M University Institutional Animal Care and Use Committee (IACUC) that meets all federal requirements in Animal Welfare Act (AWA), the Public Health Service Policy (PHS), and the Humane Care and use of laboratory animals.
Expression of A. americanum tick saliva insulin-like growth factor binding proteins-related proteins (AamIGFBP-rP) in Human Embryonic Kidney (HEK)
Preliminary assays revealed that insect-cell expressed recombinant (r) AamIGFBP-rP1,—AamIGFBP-rP6L, and AamIGFBP-rP6S (with endotoxins removed) activated both immortalized and PBMC derived macrophages (MΦ) to express PI markers. To rule out the possibility of endotoxin involvement in the observed results, rAamIGFBP-rP1, rAamIGFBP-rP6L, rAamIGFBP-rP6S rTSPs were re-expressed in Human Embryonic Kidney (HEK 293) mammalian cells using the pcDNA 3.3 expression plasmid (Thermo-Scientific). Modified pcDNA 3.3 with added CD5 secretion signal to allow secretion of the recombinant protein into spent media was kindly provided by Dr. Mwangi (Kansas State University, Kansas, USA). Mature protein encoding open reading frames was sub-cloned into the modified pcDNA3.3 plasmid using primers listed in Table 1. The reverse primer included the flag tag sequence (DYKDDDDK) which was used for detection and affinity purification of the recombinant protein. Recombinant plasmids were transformed into E.coli DH5α cells and subsequently purified using plasmid miniprep kit (Omega) followed by quantification and transfection. HEK-293A adherent cells were used in pilot expression, and the HEK-293 Freestyle (HEK-293F) cell line (Thermo-Scientific) was used for large-scale rTSP production in suspension cultures [78].
Adherent 293A cells were grown to a monolayer of up to ~60–70% confluence in T-75 flasks containing 10 mL of Dulbecco’s modified Eagle’s medium (DMEM) (Lonza) supplemented with glutamine and heat-inactivated fetal bovine serum (10%) at 37°C with 5% carbon dioxide (CO2) and 85–90% humidity. For transfection, 1 μg of plasmid DNA and 2.4 μL of the transfection reagent, polyethyleneamine (PEI) diluted in 180 μL of Opti-MEM (Thermo-Scientific) medium was incubated for 20 min at room temperature (RT). Following the incubation, 180 μL of the plasmid DNA-PEI mixture was added to each plate containing the cells, mixed gently by rocking the plate, and incubated for ~48 h at 37°C in the humidified incubator with 5% CO2 [79].
Expression was validated by immuno-staining of HEK cells using the monoclonal antibody to FLAG (5 μg/mL) (Sigma-Aldrich). Fast red was used to (4-Chloro-2-methylbenzenediazonium salt, Naphthol, Sigma-Aldrich) stain the cells, which were visualized using inverted microscope. Spent media was subjected to routine ELISA using the HRP (Horse-radish peroxidase) conjugated antibody to FLAG-Tag (Sigma-Aldrich) to verify secretion of the recombinant product into culture media.
For large-scale expression, HEK-293F suspension cultures were grown to mid-logarithmic phase with shaking at 125 rpm in 8% CO2 and 85% relative humidity. The cells were then seeded at 30 × 106 viable cells in 293 Freestyle media (Thermo-Scientific), allowed to incubate for 2 h. Recombinant plasmids (30 μg each) were incubated in 1 mL Opti-MEM media (Thermo-Scientific) separately. Following incubation, 293fectin transfection reagent (Thermo-Scientific) and recombinant plasmids were combined and incubated for an additional 30 min and then added to 30 mL cell culture containing 30 million HEK-293F cells. The cell suspension was harvested after 72 h and recombinant proteins were purified using FLAG M2 affinity gel purification (Sigma). Bound recombinant proteins were eluted in 1 mL fractions under acidic conditions using 0.1M Glycine buffer (pH 3.5) and immediately neutralized with 25 μL 1M Tris-HCl (pH 8.0). Purification was confirmed using routine SDS-PAGE and Coomassie blue or silver staining. Subsequently, relevant fractions were combined, concentrated and dialyzed against Tris-NaCl buffer (50 mM Tris, 150mM NaCl, pH 7.4) using the 10 kDa molecular cut off membrane spin filters (Pall Life Sciences). Expression recombinant AAS27 and AAS41 is reported elsewhere [44].
Macrophage cell activation assays
This was done using bovine PBMC differentiated and immortalized RAW 267 MΦ (ATCC). In the preliminary assay, PBMCs were isolated from bovine peripheral blood using Ficoll-Paque solution (Sigma-Aldrich). Monocytes from the PBMCs were isolated by Magnetic sorting method using primary mouse anti-bovine CD14 (Washington State University) antibody and a secondary antibody, anti-mouse IgG microbeads (Miltenyi Biotec). The cells were labelled with the anti-CD14 antibody and then loaded onto a MACS column, for CD14 labelled monocytes. The monocytes were counted and allowed to differentiate into macrophages for 6–8 days. Cell morphology was visually confirmed using an inverted microscope (Nikon). Following differentiation, the assay was set up using individual concentrations of 10 μg /mL, 1 μg/mL and 0.1 μg/mL of insect cell expressed rAamIGFBP-rP1, rAamIGFBP-rP6L, rAamIGFBP-rP6S [39] and yeast expressed A. americanum serpin (AAS) 27 and 41 (44). Following 24 h, the cells were collected and stained for CD40, CD80, and CD86 expression and then analyzed by flow cytometry (described below). Lipopolysaccharide (LPS), a bacterial cell wall component was used as positive controls and media alone served as a negative control. All assays were performed in triplicates for each time.
Subsequent to the preliminary assay, RAW 264.7 MΦ (ATCC) were used in the assay. Routinely, cells were grown in Dulbecco’s Modified Eagle’s Medium (DMEM) (Lonza) supplemented with 4 mM L-glutamine, 4500 mg/L glucose, 1 mM sodium pyruvate, sodium bicarbonate, non-essential amino acid solution (Thermo-Scientific) and 10% fetal bovine serum (FBS) (Thermo-Scientific). Routinely, MΦ were seeded in 12 or 24 well plates overnight and cultured at 37°C with 5% CO2, 85–90% humidity overnight to approximately 80% confluency. For pro-inflammation activation assays, 106 MΦ were incubated with 0.10, 1.0, and 10 μg/mL of affinity purified HEK cell expressed rAamIGFBP-rP1, rAamIGFBP-rP6L, and rAamIGFBP-rP6S.
In preliminary analysis, we had observed that pro-inflammation markers were expressed at below background in MΦ that were treated with various dosages of rAAS27 and rAAS41. To investigate this, we conducted two assays. In the first assay, expression of pro-inflammation makers was determined in MΦ that were co-cultured with various dosages (0.1, 1.0, 10 μg/mL of the mixture of rAAS27 or rAAS41 and LPS or rAmIGFPB-rPs. In the second assay, MΦ were first activated with LPS (100 ng) or various dosages (0.1, 1.0, 10 μg/mL) of rAamIGFBP-rP1, rAamIGFBP-rP6L and rAamIGFBP-rP6S for 24 h before replacing spent culture media with fresh media supplemented with various dosages (0.1, 1.0, 10 μg/mL) of individual or cocktail mix of rAAS27 and rAAS41. At 24 and 48 h post incubation, spent cultures were processed for assays described below.
Cell surface marker staining and flow cytometry
Treated and non-treated MΦ, were detached, and re-suspended in staining medium (DMEM with sodium azide). Immuno-labeling of bovine (preliminary analysis) and murine cell surface markers was performed by incubating cells with 15 μg/mL fluorescein isothiocyanate (FITC) conjugated antibodies to CD40 (Abcam), CD86 and CD80 (Thermo-Scientific) and isotype matched control mAbs IgG2a and IgG2b (Abcam) for 30 min on ice. After incubation, cells were washed three times with DMEM media containing 0.01% sodium azide and re-suspended in 400 μL 1X PBS (pH-7.4) containing 1 μg/mL propidium iodide, for excluding dead cells, and analyzed by flow cytometry with parameters set to 10,000 events, filter setting 530/30 nm wavelength (FACS Caliber) using acquisition software BD CellQuest (BD Biosciences) and the analysis program FlowJo 9.8.5 (TreeStar) at digital imaging core facility (College of Veterinary Medicine, Texas A&M University, College Station, TX).
Nitric oxide and Cytokine detection in the spent media
Nitric oxide metabolites released in the cell culture supernatant as nitrate or nitrite was detected by Total Nitric Oxide detection kit (Thermo-Scientific) according to the manufacturer’s protocol. Photometric measurement of the absorbance due to this azo chromophore determined the NO2- (nitrite) concentration at 540 nm wavelength using an ELISA plate reader (BioTek Instruments).
Cytokine ELISA of TNFα, IL-1, IL-6, IL-10, IL-12, and TGFβ was done using specific antibodies (Ready-SET-Go!, eBioscience, Thermo-Scientific). Optical densities were measured using an ELISA plate reader at 450 nm wavelength (BioTek Instruments, Inc).
MΦ phenotype staining
RAW 264.7 MΦ were seeded on Nunc Lab-Tek Chamber Slide (Thermo-Scientific) in the presence of the cocktail (10 μg/mL) of rAamIGFBP-rP1, rAamIGFBP-rP6L, and rAamIGFBP-rP6S, or positive control (100 ng LPS), or negative control (media with buffer) for 24 h. The cells were then fixed with ice cold methanol, blocked with 1% BSA, 22.52 mg/ml glycine in PBST (PBS+0.1% Tween 20) for 30 min and immuno-stained with the antibody to Actin (Abcam). The following day, the cells were washed in 1 X PBS and incubated with secondary antibody conjugated with Alexa Fluor 488 (Abcam) for 1 h in the dark. The cells were washed, treated with mounting media containing DAPI (Thermo-Scientific) for nuclei staining and cell staining was analyzed by confocal microscopy. Images were acquired with Ziess LSM 780 confocal microscope and merged using Zen 2012 SP1 (black edition) software in the Imaging facility (College of Veterinary Medicine, Texas A&M University, College Station, TX).
Paw edema assay
Retired female breeder BALB/c mice (Envigo) were maintained for one week to acclimatize prior to experiment. The carrageenan-induced hind paw inflammation model was used to investigate the PI and AI role of rTSPs [80]. Prior to each injection, the basal footpad volume was recorded using a plythesmometer (Harvard Apparatus). Four experiments were conducted using three mice per group. In the first experiment, effects of a high dose cocktail of rAamIGFBP-rP1, rAamIGFBP-rP6L, and rAamIGFBP-rP6S was assessed. To make the high dose cocktail, approximately 40 μg each of endotoxin free mammalian cells expressed rAamIGFBP-rP1, rAamIGFBP-rP6L and rAamIGFBP-rP6S were combined, and concentrated to reduce volume using Jumbosep centrifugal spin filter devices (Pall Life Sciences). Similarly, 40 μg each of endotoxin free rAAS27 and rAAS41 were combined and concentrated as above. The first group of mice received 25 μg of the rAamIGFBP-rP1, rAamIGFBP-rP6S and rAamIGFBP-rP6L cocktail (PI-rTSP group). The second group of mice received 25 μg cocktail of rAAS27 and rAAS41 cocktail (AI-rTSP group), third group received 25 μg of the AI-rTSP and PI-rTSP cocktail. In the second experiment, the effects of high dose (40 μg per mouse) of rAamIGFBP-rP1, rAamIGFBP-rP6L and rAamIGFBP-rP6S individually were assessed.
In the third and fourth experiments, mice were injected with low doses of cocktail of individual proteins. To make the low dose cocktail, 10 μg each of rAamIGFBP-rP1, rAamIGFBP-rP6L and rAamIGFBP-rP6S with or without 10 μg of rAAS27 and rAAS41 cocktail were prepared. In the third experiment, the first group of mice received the 10 μg the PI-rTSP cocktail, the second received the 10 μg of the AI-rTSP cocktail, the third group received 10 μg of AI-rTSP and PI-rTSP cocktail, the fourth group received 10 μg of rAAS27 or rAAS46 individually. In the fourth experiment, each group of mice received 10 μg of AamIGFBP-rP1, AamIGFBP-rP6L and AamIGFBP-rP6S. For all experiments, algae derived inflammation agonist, carrageenan (2% w/v in 0.9% saline) was used as positive control and normal saline (9 g/L NaCl) or 150mM 50mM Tris NaCl buffer (pH 7.4) as negative control (Table 2).
As index of edema formation, the first and second experiment inflammation was measured at times 0 (before injection), 20, 40, 60, 120, 240, 360, 720, and 1440 min’ post injection. For the third and fourth experiments, paw edema was measured at 0, (before injection), 20, 40, 60, and 120 or 130 min’ post injection. After measurements, the mice were euthanized (3L/minute, CO2) and injected and non-injected paws were placed in cryotubes and snap frozen in liquid nitrogen. The paws were collected at the level of calcaneus bone for cytokine, chemokine, and myeloperoxidase assays.
Quantitative RT-PCR
Total RNA was routinely extracted using the TRIzol reagent according to instructions (Thermo-Scientific). From MΦ, cells were lysed directly into 1 mL TRIzol. For paws, tissues were minced in 1 mL TRIzol solution using sterile soft tissue scissors followed by sonication using the tissue dismembranator (VWR). Total RNA from paws were subjected to mRNA isolation using OligodT magnetic beads (Thermo-Scientific) and bound mRNA was eluted using elution buffer (10mM Tris-HCl, pH 7.5). The NanoDrop (BioTek Instruments, Inc) was used to determine quantity and quality of total RNA for cDNA synthesis.
Template cDNA was synthesized from 500 ng total RNA and 25 ng mRNA using the Verso cDNA synthesis kit (Thermo-Scientific). The Verso cDNA synthesis kit contains an enhancer reagent, which prevents genomic (g) DNA carryover into the synthesized cDNA. The reverse transcription cDNA synthesis step included incubation at 42°C from 30 min and 95°C for 2 min in the thermocycler (Bio-Rad). After cDNA synthesis, the working stock for each sample was diluted 1:10 with DEPC treated water.
The qPCR (Quantitative polymerase chain reaction) was performed in triplicates in a 50 μl final reaction mix containing 3 μl each specific primers (300 nM each, Table 3), 5 μl 1:10 diluted template cDNA, and 25 μl 2X SYBR (Thermo-Scientific) green PCR master mix [(Applied Biosystems 7300 Real Time PCR System (Thermo-Scientific) and Bio-Rad qPCR machine (Bio-Rad)]. Settings were: 50°C for 2 min for one cycle followed by 95°C for 10 min, 95°C for 40 cycles at 15 seconds’ interval and 60ºC for 1 minute. Cognate mRNA expression levels were determined using the comparative delta Δ Ct method [81]. The GAPDH (Glyceraldehyde 3-phosphate dehydrogenase) gene was used as an internal reference gene. Amplifications from non-treated controls were used as calibrator for in vitro experiments and normal saline injected controls for in vivo experiments. For each biological replicate, we did qPCR in three technical triplicates.
Statistical analysis
Data acquisition for flow cytometry was performed by using BD Cell Quest (BD Bioscience). The data analysis program used was FlowJo 9.8.5 (TreeStar). The cells with >80–90% viability was selected by gating on the flow cytometer. The results from each experiment were normalized to negative control and One-way ANOVA followed by Dunnett’s Post hoc test was used to determine the statistical differences between the controls and treatments. The data are represented as means ± standard error (SE) and p values of ≤0.05 were considered to represent statistically significant differences using Prism 8.0 (GraphPad Software Inc).
Zdroje
1. Jongejan F, Uilenberg G. The global importance of ticks. Parasitology. 2004 Oct;129(S1):S3–14. doi: 10.1017/s0031182004005967 15938502
2. Dantas-Torres F, Chomel BB, Otranto D. Ticks and tick-borne diseases: a One Health perspective. Trends in parasitology. 2012 Oct 1;28(10):437–46. doi: 10.1016/j.pt.2012.07.003 22902521
3. Rosenberg R, Lindsey NP, Fischer M, Gregory CJ, Hinckley AF, Mead PS, Paz-Bailey G, Waterman SH, Drexler NA, Kersh GJ, Hooks H. Vital signs: trends in reported vector borne disease cases—United States and Territories, 2004–2016. Morbidity and Mortality Weekly Report. 2018 May 4;67(17):496. doi: 10.15585/mmwr.mm6717e1 29723166
4. George JE. Present and future technologies for tick control. Annals of the New York Academy of Sciences. 2000 Dec;916(1):583–8. doi: 10.1111/j.1749-6632.2000.tb05340.x 11193677
5. Andreotti R, Guerrero FD, Soares MA, Barros JC, Miller RJ, Léon AP. Acaricide resistance of Rhipicephalus (Boophilus) microplus in state of Mato Grosso do Sul, Brazil. Revista Brasileira de Parasitologia Veterinária. 2011 Jun;20(2):127–33. doi: 10.1590/s1984-29612011000200007 21722487
6. Graf JF, Gogolewski R, Leach-Bing N, Sabatini GA, Molento MB, Bordin EL, Arantes GJ. Tick control: an industry point of view. Parasitology. 2004 Oct;129(S1):S427–42. doi: 10.1017/s0031182004006079 15938522
7. Li AY, Davey RB, Miller RJ, George JE. Resistance to coumaphos and diazinon in Boophilus microplus (Acari: Ixodidae) and evidence for the involvement of an oxidative detoxification mechanism. Journal of Medical Entomology. 2003 Jul 1;40(4):482–90. doi: 10.1603/0022-2585-40.4.482 14680115
8. Guerrero FD, Li AY, Hernandez R. Molecular diagnosis of pyrethroid resistance in Mexican strains of Boophilus microplus (Acari: Ixodidae). Journal of Medical entomology. 2002 Sep 1;39(5):770–6. doi: 10.1603/0022-2585-39.5.770 12349861
9. Willadsen P, Bird P, Cobon GS, Hungerford J. Commercialization of a recombinant vaccine against Boophilus microplus. Parasitology. 1995;110 Suppl:S43–50. doi: 10.1017/s0031182000001487 7784128
10. Valle MR, Mèndez L, Valdez M, Redondo M, Espinosa CM, Vargas M, Cruz RL, Barrios HP, Seoane G, Ramirez ES, Boue O. Integrated control of Boophilus microplus ticks in Cuba based on vaccination with the anti-tick vaccine Gavac. Experimental & applied acarology. 2004 Nov 1;34(3–4):375–82. doi: 10.1007/s10493-004-1389-6 15651533
11. Brossard M. The use of vaccines and genetically resistant animals in tick control. Revue scientifique et technique-Office international des épizooties. 1998 Apr 1;17:188–93. doi: 10.20506/rst.17.1.1086 9638810
12. de la Fuente J, Almazán C, Canales M, de la Lastra JM, Kocan KM, Willadsen P. A ten-year review of commercial vaccine performance for control of tick infestations on cattle. Animal Health Research Reviews. 2007 Jun;8(1):23–8. doi: 10.1017/S1466252307001193 17692140
13. De la Fuente J, Kocan KM, Blouin EF. Tick vaccines and the transmission of tick-borne pathogens. Veterinary research communications. 2007 Aug 1;31(1):85–90. doi: 10.3389/fcimb.2013.00030 23847771
14. de la Fuente J, Moreno-Cid JA, Canales M, Villar M, de la Lastra JM, Kocan KM, Galindo RC, Almazán C, Blouin EF. Targeting arthropod subolesin/akirin for the development of a universal vaccine for control of vector infestations and pathogen transmission. Veterinary parasitology. 2011 Sep 8;181(1):17–22 doi: 10.1016/j.vetpar.2011.04.018 21561715
15. Marcelino I, De Almeida AM, Ventosa M, Pruneau L, Meyer DF, Martinez D, Lefrançois T, Vachiéry N, Coelho AV. Tick-borne diseases in cattle: applications of proteomics to develop new generation vaccines. Journal of proteomics. 2012 Jul 19;75(14):4232–50. doi: 10.1016/j.jprot.2012.03.026 22480908
16. Zhang XC, Zhang LX, Li WH, Wang SW, Sun YL, Wang YY, Guan ZZ, Liu XJ, Yang YS, Zhang SG, Yu HL. Ehrlichiosis and zoonotic anaplasmosis in suburban areas of Beijing, China. Vector-Borne and Zoonotic Diseases. 2012 Nov 1;12(11):932–7. doi: 10.1089/vbz.2012.0961 23025695
17. Radulović ŽM, Kim TK, Porter LM, Sze SH, Lewis L, Mulenga A. A 24–48 h fed Amblyomma americanum tick saliva immuno-proteome. BMC genomics. 2014 Dec;15(1):518. doi: 10.1186/1471-2164-15-518 24962723
18. Mulenga A, Sugimoto C, Onuma M. Issues in tick vaccine development: identification and characterization of potential candidate vaccine antigens. Microbes and Infection. 2000 Sep 1;2(11):1353–61. doi: 10.1016/s1286-4579(00)01289-2 11018452
19. Mulenga A, Sugino M, Nakajima M, Sugimoto C, Onuma M. Tick-Encoded serine proteinase inhibitors (serpins); potential target antigens for tick vaccine development. Journal of Veterinary Medical Science. 2001;63(10):1063–9. doi: 10.1292/jvms.63.1063 11714020
20. Kotál J, Langhansová H, Lieskovská J, Andersen JF, Francischetti IM, Chavakis T, Kopecký J, Pedra JH, Kotsyfakis M, Chmelař J. Modulation of host immunity by tick saliva. Journal of proteomics. 2015 Oct 14;128:58–68. doi: 10.1016/j.jprot.2015.07.005 26189360
21. Šimo L, Kazimirova M, Richardson J, Bonnet SI. The essential role of tick salivary glands and saliva in tick feeding and pathogen transmission. Frontiers in cellular and infection microbiology. 2017 Jun 22;7:281. doi: 10.3389/fcimb.2017.00281 28690983
22. Hermance ME, Santos RI, Kelly BC, Valbuena G, Thangamani S. Immune cell targets of infection at the tick-skin interface during Powassan virus transmission. PLoS One. 2016 May 20;11(5):e0155889. doi: 10.1371/journal.pone.0155889 27203436
23. Anderson JM, Moore IN, Nagata BM, Ribeiro J, Valenzuela JG, Sonenshine DE. Ticks, Ixodes scapularis, feed repeatedly on white-footed mice despite strong inflammatory response: an expanding paradigm for understanding tick–host interactions. Frontiers in immunology. 2017 Dec 18;8:1784. doi: 10.3389/fimmu.2017.01784 29326693
24. Langhansova H, Bopp T, Schmitt E, Kopecký J. Tick saliva increases production of three chemokines including monocyte chemoattractant protein‐1, a histamine‐releasing cytokine. Parasite immunology. 2015 Feb;37(2):92–6. doi: 10.1111/pim.12168 25545116
25. Lima e Silva MF, Szabo MP, Bechara GH. Microscopic Features of Tick‐Bite Lesions in Anteaters and Armadillos: Emas National Park and the Pantanal Region of Brazil. Annals of the New York Academy of Sciences. 2004 Oct;1026(1):235–41. doi: 10.1196/annals.1307.036 15604499
26. Arango Duque G, Descoteaux A. Macrophage cytokines: involvement in immunity and infectious diseases. Front Immunol 2014 Oct 7;5:491. doi: 10.3389/fimmu.2014.00491 25339958
27. Zhou D, Huang C, Lin Z, Zhan S, Kong L, Fang C, Li J. Macrophage polarization and function with emphasis on the evolving roles of coordinated regulation of cellular signaling pathways. Cellular signaling. 2014 Feb 1;26(2):192–7. doi: 10.1016/j.cellsig.2013.11.004 24219909
28. Brake DK, Wikel SK, Tidwell JP, de León AA. Rhipicephalus microplus salivary gland molecules induce differential CD86 expression in murine macrophages. Parasites & vectors. 2010 Dec;3(1):103. doi: 10.1186/1756-3305-3-103 21054882
29. Poole NM, Mamidanna G, Smith RA, Coons LB, Cole JA. Prostaglandin E 2 in tick saliva regulates macrophage cell migration and cytokine profile. Parasites & vectors. 2013 Dec;6(1):261. doi: 10.1186/1756-3305-6-261 24025197
30. Kramer CD, Poole NM, Coons LB, Cole JA. Tick saliva regulates migration, phagocytosis, and gene expression in the macrophage-like cell line, IC-21. Experimental parasitology. 2011 Mar 1;127(3):665–71. doi: 10.1016/j.exppara.2010.11.012 21145320
31. Rodrigues V, Fernandez B, Vercoutere A, Chamayou L, Andersen A, Vigy O, Demettre E, Seveno M, Aprelon R, Giraud-Girard K, Stachurski F. Immunomodulatory effects of Amblyomma variegatum saliva on bovine cells: characterization of cellular responses and identification of molecular determinants. Frontiers in cellular and infection microbiology. 2018 Jan 4;7:521. doi: 10.3389/fcimb.2017.00521 29354598
32. de Abreu MR, Pereira MC, Simioni PU, Nodari EF, Paiatto LN, Camargo-Mathias MI. Immunomodulatory and morphophysiological effects of Rhipicephalus sanguineus sl (Acari: Ixodidae) salivary gland extracts. Veterinary immunology and immunopathology. 2019 Jan 1;207:36–45. doi: 10.1016/j.vetimm.2018.11.017 30593349
33. Wasala NB, Jaworski DC. Dermacentor variabilis: characterization and modeling of macrophage migration inhibitory factor with phylogenetic comparisons to other ticks, insects and parasitic nematodes. Experimental parasitology. 2012 Mar 1;130(3):232–8. doi: 10.1016/j.exppara.2011.12.010 22306068
34. Wasala NB, Bowen CJ, Jaworski DC. Expression and regulation of macrophage migration inhibitory factor (MIF) in feeding American dog ticks, Dermacentor variabilis. Experimental and applied acarology. 2012 Jun 1;57(2):179–87. doi: 10.1007/s10493-012-9550-0 22476444
35. Jaworski DC, Jasinskas A, Metz CN, Bucala R, Barbour AG. Identification and characterization of a homologue of the pro‐inflammatory cytokine Macrophage Migration Inhibitory Factor in the tick, Amblyomma americanum. Insect molecular biology. 2001 Aug;10(4):323–31. doi: 10.1046/j.0962-1075.2001.00271.x 11520355
36. Jaworski DC, Bowen CJ, Wasala NB. Amblyomma americanum (L): tick macrophage migration inhibitory factor peptide immunization lengthens lone star tick feeding intervals in vivo. Experimental parasitology. 2009 Apr 1;121(4):384–7. doi: 10.1016/j.exppara.2008.12.003 19111543
37. Wang X, Shaw DK, Sakhon OS, Snyder GA, Sundberg EJ, Santambrogio L, Sutterwala FS, Dumler JS, Shirey KA, Perkins DJ, Richard K. The tick protein Sialostatin L2 binds to Annexin A2 and inhibits NLRC4-mediated inflammasome activation. Infection and immunity. 2016 Jun 1;84(6):1796–805. doi: 10.1128/IAI.01526-15 27045038
38. Mulenga A, Blandon M, Khumthong R. The molecular basis of the Amblyomma americanum tick attachment phase. Experimental and Applied Acarology. 2007 Apr 1;41(4):267–87. doi: 10.1007/s10493-007-9064-3 17406795
39. Radulović ŽM, Porter LM, Kim TK, Bakshi M, Mulenga A. Amblyomma americanum tick saliva insulin‐like growth factor binding protein‐related protein 1 binds insulin but not insulin‐like growth factors. Insect molecular biology. 2015 Oct;24(5):539–50. doi: 10.1111/imb.12180 26108887
40. Porter LM, Radulović ŽM, Mulenga A. A repertoire of protease inhibitor families in Amblyomma americanum and other tick species: inter-species comparative analyses. Parasites & vectors. 2017 Dec;10(1):152. doi: 10.1186/s13071-017-2080-1 28330502
41. Tirloni L, Kim TK, Pinto AF, Yates JR III, da Silva Vaz I Jr, Mulenga A. Tick-host range adaptation: changes in protein profiles in unfed adult Ixodes scapularis and Amblyomma americanum saliva stimulated to feed on different hosts. Frontiers in cellular and infection microbiology. 2017 Dec 19;7:517. doi: 10.3389/fcimb.2017.00517 29312895
42. Radulović ŽM, Kim TK, Porter LM, Sze SH, Lewis L, Mulenga A. A 24–48 h fed Amblyomma americanum tick saliva immuno-proteome. BMC genomics. 2014 Dec;15(1):518. 24962723
43. Mulenga A, Khumthong R. Silencing of three Amblyomma americanum (L.) insulin-like growth factor binding protein-related proteins prevents ticks from feeding to repletion. Journal of Experimental Biology. 2010 Apr 1;213(7):1153–61. doi: 10.1242/jeb.035204 20228352
44. Tirloni L, Kim TK, Berger M, Termignoni C, da Silva Vaz I Jr, Mulenga A. Amblyomma americanum serpin 27 (AAS27) is a tick salivary anti-inflammatory protein secreted into the host during feeding. PLoS neglected tropical diseases. 2019 Aug 26;13(8):e0007660. doi: 10.1371/journal.pntd.0007660 31449524
45. Cavaillon JM. Cytokines and macrophages. Biomedicine & pharmacotherapy. 1994 Jan 1;48(10):445–53. doi: 10.1016/0753-3322(94)90005-1 7858154
46. Wynn TA, Chawla A, Pollard JW. Macrophage biology in development, homeostasis and disease. Nature. 2013 Apr;496(7446):445. doi: 10.1038/nature12034 23619691
47. Lanier LL, O, Somoza C, Phillips JH, Linsley PS, Okumura K, Ito D, Azuma M. CD80 (B7) and CD86 (B70) provide similar costimulatory signals for T cell proliferation, cytokine production, and generation of CTL. The Journal of Immunology. 1995 Jan 1;154(1):97–105. 7527824
48. Fleischer J, Soeth E, Reiling N, Grage‐Griebenow E, FLAD HD, Ernst M. Differential expression and function of CD80 (B7‐1) and CD86 (B7‐2) on human peripheral blood monocytes. Immunology. 1996 Dec;89(4):592–8. doi: 10.1046/j.1365-2567.1996.d01-785.x 9014827
49. MacMicking J, Xie QW, Nathan C. Nitric oxide and macrophage function. Annual review of immunology. 1997 Apr;15(1):323–50. doi: 10.1146/annurev.immunol.15.1.323 9143691
50. Mills C. M1 and M2 macrophages: oracles of health and disease. Critical Reviews in Immunology. 2012;32(6). doi: 10.1615/critrevimmunol.v32.i6.10 23428224
51. Kotsyfakis M, Sa-Nunes A, Francischetti IM, Mather TN, Andersen JF, Ribeiro JM. Anti-inflammatory and immunosuppressive activity of sialostatin L, a salivary cystatin from the tick Ixodes scapularis. J Biol Chem 2006 Sep 8;281(36):26298–26307. doi: 10.1074/jbc.M513010200 16772304
52. Oliveira CJ, Cavassani KA, Moré DD, Garlet GP, Aliberti JC, Silva JS, Ferreira BR. Tick saliva inhibits the chemotactic function of MIP-1α and selectively impairs chemotaxis of immature dendritic cells by down-regulating cell-surface CCR5. International journal for parasitology. 2008 May 1;38(6):705–16. doi: 10.1016/j.ijpara.2007.10.006 18023445
53. Guo X, Booth CJ, Paley MA, Wang X, DePonte K, Fikrig E, et al. Inhibition of neutrophil function by two tick salivary proteins. Infect Immun 2009 Jun;77(6):2320–2329. doi: 10.1128/IAI.01507-08 19332533
54. Langhansova H, Bopp T, Schmitt E, Kopecký J. Tick saliva increases production of three chemokines including monocyte chemoattractant protein‐1, a histamine‐releasing cytokine. Parasite immunology. 2015 Feb;37(2):92–6. doi: 10.1111/pim.12168 25545116
55. Chmelar J, Calvo E, Pedra JH, Francischetti IM, Kotsyfakis M. Tick salivary secretion as a source of antihemostatics. Journal of proteomics. 2012 Jul 16;75(13):3842–54. doi: 10.1016/j.jprot.2012.04.026 22564820
56. Strle K, Drouin EE, Shen S, Khoury JE, McHugh G, Ruzic-Sabljic E, Strle F, Steere AC. Borrelia burgdorferi stimulates macrophages to secrete higher levels of cytokines and chemokines than Borrelia afzelii or Borrelia garinii. The Journal of infectious diseases. 2009 Dec 15;200(12):1936–43. doi: 10.1086/648091 19909078
57. Jones KL, Muellegger RR, Means TK, Lee M, Glickstein LJ, Damle N, Sikand VK, Luster AD, Steere AC. Higher mRNA levels of chemokines and cytokines associated with macrophage activation in erythema migrans skin lesions in patients from the United States than in patients from Austria with Lyme borreliosis. Clinical infectious diseases. 2008 Jan 1;46(1):85–92. doi: 10.1086/524022 18171218
58. Miura K, Matsuo J, Rahman MA, Kumagai Y, Li X, Rikihisa Y. Ehrlichia chaffeensis induces monocyte inflammatory responses through MyD88, ERK, and NF-κB but not through TRIF, interleukin-1 receptor 1 (IL-1R1)/IL-18R1, or Toll-like receptors. Infection and immunity. 2011 Dec 1;79(12):4947–56. doi: 10.1128/IAI.05640-11 21930764
59. Chen G, Severo MS, Sohail M, Sakhon OS, Wikel SK, Kotsyfakis M, Pedra JH. Ixodes scapularis saliva mitigates inflammatory cytokine secretion during Anaplasma phagocytophilum stimulation of immune cells. Parasites & vectors. 2012 Dec;5(1):229. doi: 10.1186/1756-3305-5-229 23050849
60. Hermance ME, Thangamani S. Proinflammatory cytokines and chemokines at the skin interface during Powassan virus transmission. The Journal of investigative dermatology. 2014 Aug;134(8):2280. doi: 10.1038/jid.2014.150 24658509
61. Nuttall PA. Tick saliva and its role in pathogen transmission. Wiener klinische Wochenschrift. 2019 May 6:1–2. doi: 10.1007/s00508-019-1500-y 31062185
62. Schoeler GB, Manweiler SA, Wikel SK. Ixodes scapularis: effects of repeated infestations with pathogen-free nymphs on macrophage and T lymphocyte cytokine responses of BALB/c and C3H/HeN mice. Experimental parasitology. 1999 Aug 1;92(4):239–48. doi: 10.1006/expr.1999.4426 10425152
63. Gwakisa P, Yoshihara K, To TL, Gotoh H, Amano F, Momotani E. Salivary gland extract of Rhipicephalus appendiculatus ticks inhibits in vitro transcription and secretion of cytokines and production of nitric oxide by LPS-stimulated JA-4 cells. Veterinary Parasitology. 2001 Jul 31;99(1):53–61. doi: 10.1016/s0304-4017(01)00445-9 11445155
64. Ferreira BR, Silva JS. Saliva of Rhipicephalus sanguineus tick impairs T cell proliferation and IFN-γ-induced macrophage microbicidal activity. Veterinary immunology and immunopathology. 1998 Jul 31;64(3):279–93. doi: 10.1016/s0165-2427(98)00135-4 9730222
65. Krause PJ, Grant-Kels JM, Tahan SR, Dardick KR, Alarcon-Chaidez F, Bouchard K, Visini C, Deriso C, Foppa IM, Wikel S. Dermatologic changes induced by repeated Ixodes scapularis bites and implications for prevention of tick-borne infection. Vector-Borne and Zoonotic Diseases. 2009 Dec 1;9(6):603–10. doi: 10.1089/vbz.2008.0091 19196014
66. Glatz M, Means T, Haas J, Steere AC, Müllegger RR. Characterization of the early local immune response to Ixodes ricinus tick bites in human skin. Experimental dermatology. 2017 Mar;26(3):263–9. doi: 10.1111/exd.13207 27623398
67. Heinze DM, Carmical JR, Aronson JF, Thangamani S. Early immunologic events at the tick-host interface. PloS one. 2012 Oct 15;7(10):e47301. doi: 10.1371/journal.pone.0047301 23077588
68. Butterfield TA, Best TM, Merrick MA. The dual roles of neutrophils and macrophages in inflammation: a critical balance between tissue damage and repair. Journal of athletic training. 2006 Oct;41(4):457. 17273473
69. Fujiwara N, Kobayashi K. Macrophages in inflammation. Current Drug Targets-Inflammation & Allergy. 2005 Jun 1;4(3):281–6. doi: 10.2174/1568010054022024 16101534
70. Freire MO, Van Dyke TE. Natural resolution of inflammation. Periodontology 2000. 2013 Oct;63(1):149–64. doi: 10.1111/prd.12034 23931059
71. Woldai S. The role of CD80 and CD86 in macrophage activation and its regulation following LPS stimulation (Doctoral dissertation, Université d'Ottawa/University of Ottawa).
72. Moser B, Willimann K. Chemokines: role in inflammation and immune surveillance. Annals of the rheumatic diseases. 2004 Nov 1;63(suppl 2):ii84–9. doi: 10.1136/ard.2004.028316 15479880
73. Zlotnik A, Yoshie O. Chemokines: a new classification system and their role in immunity. Immunity. 2000 Feb 1;12(2):121–7. doi: 10.1016/s1074-7613(00)80165-x 10714678
74. Mulenga A, Macaluso KR, Simser JA, Azad AF. The American dog tick, Dermacentor variabilis, encodes a functional histamine release factor homolog. Insect biochemistry and molecular biology. 2003 Sep 1;33(9):911–9. doi: 10.1016/s0965-1748(03)00097-3 12915182
75. Mulenga A, Azad AF. The molecular and biological analysis of ixodid ticks histamine release factors. Experimental & applied acarology. 2005 Dec 1;37(3–4):215–29. doi: 10.1007/s10493-005-3261-8 16323052
76. Lani R, Moghaddam E, Haghani A, Chang LY, AbuBakar S, Zandi K. Tick-borne viruses: a review from the perspective of therapeutic approaches. Ticks and tick-borne diseases. 2014 Sep 1;5(5):457–65. doi: 10.1016/j.ttbdis.2014.04.001 24907187
77. Westover JB, Rigas JD, Van Wettere AJ, Li R, Hickerson BT, Jung KH, Miao J, Reynolds ES, Conrad BL, Nielson S, Furuta Y. Heartland virus infection in hamsters deficient in type I interferon signaling: Protracted disease course ameliorated by favipiravir. Virology. 2017 Nov 1;511:175–83. doi: 10.1016/j.virol.2017.08.004 28865344
78. Portolano N, Watson PJ, Fairall L, Millard CJ, Milano CP, Song Y, et al. Recombinant protein expression for structural biology in HEK 293F suspension cells: a novel and accessible approach. J Vis Exp 2014 Oct 16;(92):e51897. (92):e51897. doi: 10.3791/51897 25349981
79. Longo PA, Kavran JM, Kim MS, Leahy DJ. Transient mammalian cell transfection with polyethylenimine (PEI). InMethods in enzymology 2013 Jan 1 (Vol. 529, pp. 227–240). Academic Press. doi: 10.1016/B978-0-12-418687-3.00018-5 24011049
80. Winter CA, Risley EA, Nuss GW. Carrageenan-induced edema in hind paw of the rat as an assay for anti-inflammatory drugs. Proceedings of the society for experimental biology and medicine. 1962 Dec;111(3):544–7. doi: 10.3181/00379727-111-27849 14001233
81. Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2− ΔΔCT method. methods. 2001 Dec 1;25(4):402–8. doi: 10.1006/meth.2001.1262 11846609
82. Dann SM, Spehlmann ME, Hammond DC, Iimura M, Hase K, Choi LJ, Hanson E, Eckmann L. IL-6-dependent mucosal protection prevents establishment of a microbial niche for attaching/effacing lesion-forming enteric bacterial pathogens. The Journal of Immunology. 2008 May 15;180(10):6816–26. doi: 10.4049/jimmunol.180.10.6816 18453602
83. Mazur PK, Herner A, Mello SS, Wirth M, Hausmann S, Sánchez-Rivera FJ, Lofgren SM, Kuschma T, Hahn SA, Vangala D, Trajkovic-Arsic M. Combined inhibition of BET family proteins and histone deacetylases as a potential epigenetics-based therapy for pancreatic ductal adenocarcinoma. Nature medicine. 2015 Oct;21(10):1163. doi: 10.1038/nm.3952 26390243
84. Guma M, Ronacher L, Liu‐Bryan R, Takai S, Karin M, Corr M. Caspase 1–independent activation of interleukin‐1β in neutrophil‐predominant inflammation. Arthritis & Rheumatism: Official Journal of the American College of Rheumatology. 2009 Dec;60(12):3642–50. doi: 10.1002/art.24959 19950258
85. Vicente‐Suarez I, Takahashi Y, Cheng F, Horna P, Wang HW, Wang HG, Sotomayor EM. Identification of a novel negative role of flagellin in regulating IL‐10 production. European journal of immunology. 2007 Nov;37(11):3164–75. doi: 10.1002/eji.200737306 17948265
86. Morgado P, Sudarshana DM, Gov L, Harker KS, Lam T, Casali P, et al. Type II Toxoplasma gondii induction of CD40 on infected macrophages enhances interleukin-12 responses. Infect Immun 2014 Oct;82(10):4047–4055. doi: 10.1128/IAI.01615-14 25024369
87. Li JG, Du YM, Yan ZD, Yan J, Zhuansun YX, Chen R, Zhang W, Feng SL, Ran PX. CD80 and CD86 knockdown in dendritic cells regulates Th1/Th2 cytokine production in asthmatic mice. Experimental and therapeutic medicine. 2016 Mar 1;11(3):878–84. doi: 10.3892/etm.2016.2989 26998006
88. Saluzzo S, Gorki AD, Rana BM, Martins R, Scanlon S, Starkl P, Lakovits K, Hladik A, Korosec A, Sharif O, Warszawska JM. First-breath-induced type 2 pathways shape the lung immune environment. Cell reports. 2017 Feb 21;18(8):1893–905. doi: 10.1016/j.celrep.2017.01.071 28228256
89. Bando Y, Hagiwara Y, Suzuki Y, Yoshida K, Aburakawa Y, Kimura T, Murakami C, Ono M, Tanaka T, Jiang YP, Mitrovi B. Kallikrein 6 secreted by oligodendrocytes regulates the progression of experimental autoimmune encephalomyelitis. Glia. 2018 Feb;66(2):359–78. doi: 10.1002/glia.23249 29086442
90. Chang CT, Lin H, Ho TY, Li CC, Lo HY, Wu SL, Huang YF, Liang JA, Hsiang CY. Comprehensive assessment of host responses to ionizing radiation by nuclear factor-κB bioluminescence imaging-guided transcriptomic analysis. PloS one. 2011 Aug 24;6(8):e23682. doi: 10.1371/journal.pone.0023682 21887294
91. Davis MJ, Tsang TM, Qiu Y, Dayrit JK, Freij JB, Huffnagle GB, Olszewski MA. Macrophage M1/M2 polarization dynamically adapts to changes in cytokine microenvironments in Cryptococcus neoformans infection. MBio. 2013 Jul 1;4(3):e00264–13. doi: 10.1128/mBio.00264-13 23781069
Štítky
Hygiena a epidemiologie Infekční lékařství LaboratořČlánek vyšel v časopise
PLOS Pathogens
2019 Číslo 11
- Jak souvisí postcovidový syndrom s poškozením mozku?
- Měli bychom postcovidový syndrom léčit antidepresivy?
- Farmakovigilanční studie perorálních antivirotik indikovaných v léčbě COVID-19
- 10 bodů k očkování proti COVID-19: stanovisko České společnosti alergologie a klinické imunologie ČLS JEP
Nejčtenější v tomto čísle
- Candida albicans triggers NADPH oxidase-independent neutrophil extracellular traps through dectin-2
- Mycobacterium abscessus virulence traits unraveled by transcriptomic profiling in amoeba and macrophages
- Trickle infection and immunity to Trichuris muris
- Porphyromonas gingivalis induces penetration of lipopolysaccharide and peptidoglycan through the gingival epithelium via degradation of junctional adhesion molecule 1